Gear-constraint-type helmet with transformable jaw-guard structure

专利摘要:
Provided is a helmet with a transformable jaw-guard structure, which comprises a helmet shell main body (1), a jaw guard (2) and a fork handle (2a) arranged on the jaw guard (2). A linkage mechanism is composed of a bottom support (3), the fork handle (2a), an inner gear (4), an outer gear (5) and a transmission member (7), wherein both the inner gear (4) and the outer gear (5) rotate in a fixed axis and form a meshing restraint pair; and the inner gear (4) and the fork handle (2a) fit with each other in a sliding manner to form a sliding restraint pair; and the transmission member (7) transfers motion of the outer gear (5) to the fork handle (2a) and drives the jaw guard (2) to produce extend-retract displacement relative to the helmet main body (1), so that the jaw guard (2) performs a turning motion and is combined with a reciprocating action, thereby realizing the conversion of the jaw guard (2) between a full helmet position and a half helmet position.
公开号:ES2878249A2
申请号:ES202190042
申请日:2019-10-25
公开日:2021-11-18
发明作者:Haotian Liao
申请人:JIANGMEN PENGCHENG HELMETS Ltd；
IPC主号:

专利说明:

[0002] HELMET WITH TRANSFORMABLE CHAIN STRUCTURE WITH RESTRICTION
[0004] TECHNICAL FIELD
[0005] The present disclosure belongs to the technical field of human body safety protection devices and relates to a helmet for protecting the head of a human body, particularly, to a helmet with a chin guard or chin guard structure, and more particularly , to a helmet that allows the position and posture of a chin rest to be changed between a full helmet structure and a semi-helmet structure according to the requirements of the application.
[0007] BACKGROUND
[0008] It is well known that users of various motor vehicles, racing cars, racing boats, balance cars, aircraft, and even bicycles must wear helmets to protect their heads during the actuation process. Additionally, for people working in many special situations such as spray shops, fire fighting, disaster relief, counter terrorism and riot control, as well as harsh environments such as mine exploration, coal mining and tunnels, they also have to wear helmets to protect their heads from various unexpected injuries. At present, there are mainly two types of helmets, namely, a full-helmet type and a semi-helmet type, in which full-helmet type helmets are equipped with chin guards that surround the wearer's chin, while full-face helmets semi-helmet type do not have chin rests. Full-face helmets can better protect the wearer's head thanks to their chin rests; while semi-helmet type helmets provide greater wearing comfort since the user's mouth, nose and other organs are not restricted by the chin guard.
[0009] For conventional full-face helmets, the chin guard and the shell body are integrated, that is, the chin guard is fixed relative to the shell body. Undoubtedly, conventional full-face helmets of this integrated structure are firm and reliable and thus provide sufficient safety to users. However, on the other hand, the full-shell type helmets of the integrated structure have the following disadvantages. First of all, from the point of view of use, when the user needs to perform activities such as drinking water, making a call or resting, the user must remove the helmet to complete the corresponding action, and there is no doubt that the helmets of the type full hull of the integrated structure are inflexible and inconvenient. Second, from the production point of view, the full-shell type helmets of the integrated structure have the structural characteristics of large cavity and small opening, such that the mold is very complex and the production efficiency is low. . This is the reason why full-shell type helmets of the integrated structure have a high manufacturing cost.
[0011] It is obvious that conventional helmets with an integrated full helmet structure cannot satisfy the requirements of safety, comfort, low cost and the like. In view of this, the development of a helmet that combines the advantages of the safety of the full-helmet structure and the comfort of the semi-helmet structure has naturally become the current goal of helmet researchers and manufacturers. In this context, the present patent applicant has proposed "helmet with transformable jaw protection structure based on gear restraint" in Chinese Patent Application CN105901820A, which is characterized in that fixed inner gears of a type of Spur gear are arranged on two sides of a helmet shell, two rotating outer gears of a spur gear type are correspondingly clamped on two branches of the chin guard, and corresponding arc-shaped restraining grooves are formed on the fastened support bases to the helmet shell. The gears Rotating outer gears and fixed inner gears are constrained by the restriction slots such that the rotating outer gears and fixed inner gears mesh with each other to form kinematic torque. Accordingly, the position and posture of the chin rest are restricted by a predetermined process, and the chin rest travels in a planned trajectory between a full helmet frame position and a semi-helmet frame position and can be operated inversely between the two. positions. In other words, the chin rest can be raised from the full helmet frame position to the semi-helmet frame position as required, and vice versa. Additionally, since the chin guard and the shell body are not integrated, the mold for manufacturing the helmet is simplified, so that the manufacturing cost can be reduced and the production efficiency can be improved. It is obvious that the gear restraint transformable chin guard structure scheme provided in this patent application can better satisfy the requirements of safety, comfort, low cost and the like, thus promoting the advancement of helmet technology.
[0013] However, although the helmet with a transformable chin guard structure proposed in Chinese Patent Application CN105901820A has obvious advantages, long arc-shaped restriction grooves of a through nature are needed to maintain the meshing relationship between the rotating outer gears and the gears. Fixed inner gears and rotating outer gears oscillate at a large turning angle together with the chin guard, thus causing various disadvantages. Specifically: 1) There is a hidden danger in the reliability of the helmet due to the long arc-shaped restriction grooves, because the chin guard cannot fully cover the restriction grooves, that is, it is difficult for the branch body The chin guard effectively covers the long arc-shaped restriction grooves of a through nature, when the chin guard forms a bare-face helmet during a chin guard posture transformation process, particularly in a certain intermediate position between the full helmet structure and the semi-hull structure (the hull in this case has a shape of a "hull with structure of quasi-semi-helmet ", which is convenient for the user to carry out activities such as drinking water, conversation and temporary ventilation and is especially suitable for tunnel operations). As a result, an opportunity is created for foreign objects to enter in the meshing kinematic torque made up of the rotating outer gears and the fixed inner gears, and once this occurs, the gear restrained torque easily gets stuck. In other words, there are some hidden dangers in the reliability of the hull when is in use. 2) The existence of long arc-shaped restriction grooves of a through nature results in a great noise from the helmet, also because the chin guard is required to constitute the open-face helmet in a state in which the chin guard is in an intermediate position between the full-hull structure and the half-hull structure during a mental posture transformation process Therefore, the chin guard cannot completely cover the rider restraining grooves, such that the jingle, due to external air flow through the outer surface of the helmet, can be easily transmitted from the grooves of the rider. restriction of a passing nature to the inside of the helmet. . Since these restriction grooves are only arranged near the two ears of the wearer, the sound insulation effect or the comfort of the helmet is poor. 3) The arrangement and mode of operation of the outer gears rotating like a planet make the safety of the helmet weakened to some extent because the outer gears move with the chin guard to exhibit planetary spinning behavior when the chin guard is changed in a structural position of the chin guard. It is not difficult to find that a large space area is swept, and it is obviously impossible to place set screws or other fastening structures in the gap of space area through which the outer gears rotate. In this case, the support bases with the long arc-shaped restraining grooves formed therein are forcibly designed as thin carcass members with a large extension. It is well known that the members of this structure are relatively small in intrinsic stiffness, which means that the helmet shell has a relatively low stiffness, that is, the safety of the helmet is weakened.
[0014] In conclusion, the helmet with gear restriction-based transformable jaw protection structure can be transformed between full helmet position and semi-helmet position, but the helmet has the disadvantages of low reliability, comfort and safety. In short, there is still scope for a further improvement on existing helmets with a transformable chin guard structure.
[0016] DESCRIPTION OF THE INVENTION
[0017] In view of the above problems in existing helmets with a transformable jaw guard structure based on gear restraint, the embodiments of the present disclosure provide a helmet with a transformable chin guard structure with gear restraint. Compared with the existing gear restraint transformable chin guard structure technology, in this helmet, by improving the structure arrangement and drive mode of a gear restraint mechanism, accurate position conversion can be ensured and the posture of the chin guard between a full helmet structure and a semi-helmet structure, and the reliability, comfort and safety of the helmet can be further improved effectively.
[0019] The object of carrying out the disclosure is achieved in this way. A helmet with a gear restraint transformable chin guard structure, comprising: a shell body; a chin guard; and two support bases, wherein the two support bases are arranged on two sides of the carcass body, respectively, and the two support bases are fixed to the carcass body or integrated with the carcass body; wherein the chin guard is provided with two branches which are arranged on two sides of the carcass body, respectively; wherein for each of the two support bases, an internal gear constrained by the support base and / or the carcass body and an external gear constrained by the support base and / or the carcass body are provided; wherein the internal gear can rotate about an internal gear shaft, and the external gear can rotate around an external gear shaft; wherein the internal gear comprises a body or accessory having a through slot, and a drive member is provided running through the through slot; wherein the support base, branch, internal gear, external gear, and drive member on one side of the casing body constitute an associated mechanism; wherein in the associated mechanism, the branch is disposed outside the through slot of the internal gear, the external gear and internal gear are meshed together to constitute kinematic torque, and the internal gear is in sliding fit with the branch to constitute a sliding kinematic pair; wherein the drive member is in engagement restraint with the external gear at one end of the drive member, such that the drive member can be driven by the external gear or the external gear can be driven by the drive member; the actuation member is in engagement restraint with the branch at the other end of the actuation member, such that the branch can be actuated by the actuation member or the actuation member can be actuated by the branch; and, wherein an actuation and operation logic executed by the chin guard, internal gear, external gear, and actuation member in the associated mechanism comprises at least one of three situations a), b) and c):
[0021] a) the chin guard begins with an initial rotating action; then the chin guard actuates the internal gear to rotate through the branch; after which, the inner gear drives the outer gear by the gear between the inner gear and the outer gear; and then, the outer gear drives the branch to move by the drive member, and the branch is caused to slide displacement relative to the inner gear by a restriction between the inner gear and the branch of the slidable kinematic torque, of such that the position and posture of the chin rest are correspondingly changed during a chin rest rotation process;
[0022] b) the internal gear begins with an initial turning action; then, the internal gear drives the chin guard to perform a corresponding rotational movement by means of the sliding kinematic torque constituted by the internal gear and the branch; meanwhile, the inner gear drives the outer gear to rotate by the gear between the inner gear and the outer gear, and the outer gear drives the branch to move by the drive member and the branch is forced to make a displacement slidable with respect to the internal gear by a restriction between the branch and the internal gear of the slidable kinematic torque, such that the position and posture of the chin guard are correspondingly changed during a chin guard rotation process; Y
[0023] c) the external gear begins with an initial turning action; then, the outer gear drives the inner gear to rotate by the meshing relationship between the outer gear and the inner gear; after which, the internal gear drives the chin guard to perform a corresponding rotational movement by means of the sliding kinematic torque constituted by the internal gear and the branch; and meanwhile, the outer gear drives the branch to move by the drive member and the branch is caused to slide displacement relative to the internal gear by a restriction between the branch and the inner gear of the sliding kinematic pair, of such that the position and posture of the chin rest are correspondingly changed during a chin rest rotation process.
[0025] In one embodiment, in the associated mechanism, the kinematic torque constituted by the internal gear and the external gear is a flat gear drive mechanism.
[0027] In one embodiment, in the associated mechanism, the internal gear and the external gear They are cylindrical gears; and, when the inner gear and the outer gear are meshed with each other, a pitch radius R of the inner gear and a pitch radius r of the outer gear satisfy a relationship: R / r = 2.
[0029] In one embodiment, in the associated mechanism, the drive member comprises a surface of revolution structure having an axis of revolution, the axis of revolution can always rotate about an external gear axis synchronously together with the external gear, and the Axis of revolution is arranged parallel to the outer gear axis and intersects a pitch circle of the outer gear.
[0031] In one embodiment, the surface structure of revolution of the drive member is a cylindrical surface structure or a circular conical surface structure.
[0033] In one embodiment, the coupling restriction between the drive member and the outer gear is that the drive member is attached to the outer gear or integrated with the outer gear, and the drive member is in rotary fit with the branch; or the coupling restriction between the drive member and the outer gear is that the drive member is in rotary fit with the outer gear, and the drive member is attached to the branch or integrated with the branch; or the coupling restriction between the drive member and the outer gear is that the drive member is in rotary fit with the outer gear, and the drive member is also in rotary fit with the branch.
[0035] In one embodiment, a first anti-disengagement member capable of preventing axial play of the internal gear is provided on the support base, the casing body and / or the external gear; a second anti-disengagement member capable of preventing axial play of the external gear is arranged on the internal gear, the support base and / or the casing body; and a A third anti-disengagement member capable of preventing axial loosening of the chin guard branch is arranged on the internal gear.
[0037] In one embodiment, at least one of the gear teeth of the outer gear is designed as an abnormal gear tooth having a thickness greater than the average thickness of all effective gear teeth on the outer gear, and the drive member alone It is connected to the abnormal gear tooth.
[0039] In one embodiment, the internal gear through slot is a flat straight through slot that is arranged to point or pass through an internal gear shaft; the sliding kinematic torque constituted by the sliding fit of the internal gear with the branch is a linear sliding kinematic torque, and the linear sliding kinematic torque is arranged to point or pass through the internal gear shaft; and, the straight through slot and the linear sliding kinematic pair are superimposed on each other or parallel to each other.
[0041] In one embodiment, when the chin guard is in a full-hull structure position, the axis of revolution of the surface of revolution structure of the drive member in at least one associated mechanism overlaps the internal gear axis, and the elements Linear constraints included in the sliding kinematic torque in the associated mechanism are perpendicular to a plane constituted by the internal gear shaft and the external gear shaft.
[0043] In one embodiment, a central angle covered by all the teeth of gears effective in the internal gear is greater than or equal to 180 degrees.
[0045] In one embodiment, a first clamping structure is arranged on the support base and / or the carcass body; at least a second clamping structure is arranged on the body of the internal gear or an extension of the internal gear; an actuation spring to press and actuate the first clamping structure close to the second clamping structure it is further arranged on the support base and / or the carcass body; the first clamping structure and the second clamping structure are male and female clamping structures coupled to each other; And, when the first clamping structure and the second clamping structure are clamped together, the effect of clamping and holding the chin rest in the current position and posture of the chin rest can be achieved.
[0047] In one embodiment, the first clamp structure has a convex tooth configuration; the second clamping structure has a groove configuration; At least one second clamping structure is provided, wherein a second clamping structure is clamped with the first clamping structure when the chin guard is in a full helmet frame position and another second clamping structure is clamp fitted with the first holding frame when the chin guard is in a semi-helmet frame position.
[0049] In one embodiment, another second clamp structure is clamped with the first clamp structure when the chin rest is in an open face frame position.
[0051] In one embodiment, the carcass body comprises a reinforcing spring arranged in the support base and / or the carcass body; when the chin guard is in the full helmet frame position, the reinforcement spring is compressed and stores energy; When the chin guard rotates from the full helmet frame position to a shell body dome, the bracing spring releases the elastic force to help open the chin guard; and, when the chin guard is located between the full helmet frame position and the open face frame position, the reinforcing spring stops acting on the chin guard.
[0052] In one embodiment, in at least one associated mechanism, a ratio of a number of teeth equivalent to the full circumference of the internal gear ZR of the mesh elements comprised in the internal gear with respect to an equivalent number of teeth of the full circumference of the gear external Zr of the mesh elements comprised in the external gear satisfies a relationship: ZR / Zr = 2.
[0054] In one embodiment, the external gear in at least one associated mechanism comprises a web plate that is disposed on the external gear.
[0056] In one embodiment, in at least one associated mechanism, the internal gear comprises a through slot constituted in the internal gear, the through slot participates in the slidable restraint behavior of the internal gear and the branch, and the slidable restraint behavior constitutes a part. or the totality of the sliding kinematic pair constituted by the internal gear and the branch.
[0058] In one embodiment, the helmet further comprising a visor, wherein the visor comprises two legs arranged on two sides of the shell body, respectively, and capable of oscillating about a fixed axis relative to the shell body; A load bearing rail side is arranged on at least one of the legs, and the leg with the load bearing rail side is arranged between the bearing base and the carcass body; a through opening is constituted by an inner support plate in the support base facing the casing body, and a trigger pin extending out of the opening and which can come into contact with the load bearing rail side of the leg is arranged in the external gear; and, when the visor is fully fastened, the arrangement of the trigger pin and the load bearing rail side satisfies several conditions: when the chin guard is opened from the full helmet frame position, the trigger pin can come into contact with the load bearing rail side on the leg and thus make the visor rotate; and when the chin guard returns to the helmet frame position full from the semi-hull frame position, during the first two-thirds of the return trip of the chin rest, the trigger pin may come into contact with the load bearing rail side on the leg and therefore make the visor rotate.
[0060] In one embodiment, the first toothed locking teeth are provided on the legs of the visor, and the second locking teeth corresponding to the first locking teeth are provided on the support base and / or the carcass body; a locking spring is arranged on the support base and / or on the casing body; the first locking teeth move synchronously with the visor, and the second locking teeth can move or oscillate relative to the carcass body; when the visor is fastened, the second locking teeth can move close to the first locking teeth under the action of the locking spring, such that the visor is loosely locked; and, when the visor is opened by an external force, the first locking teeth may forcibly actuate the second locking teeth to compress the locking spring to move to give way to the first locking teeth and unlocking the first locking teeth.
[0062] In the helmet with a gear restraint transformable chin rest structure in accordance with the embodiments of the present disclosure, by adopting the arrangement mode of forming an associated mechanism by the chin rest, internal gear, external gear and actuating member , the internal gear and the external gear can rotate about a fixed axis and meshed with each other to form a kinematic torque, and a restraint torque in sliding fit with the chin guard branch is constituted as the internal gear, such that the branch, the internal gear and the external gear can be driven to be rotatable. Meanwhile, the branch is driven to reciprocate with respect to the internal gear by the drive member connected to the external gear and the chin guard branch, such that the position and posture of the chin guard can be changed with precision along with the action of opening or closing the chin guard. Accordingly, the transformation of the chin guard between the full-helmet frame position and the semi-helmet frame position is performed, and the uniqueness and reversibility of the geometric movement path of the chin guard can be maintained. Based on the mode of arrangement and the mode of operation of the associated mechanism, during the chin rest posture transformation process, the chin rest branch body can be rotated synchronously with the internal gear, to basically or even completely cover the through groove of internal gear. Therefore, external foreign objects can be prevented from entering the restraining torque, and the reliability of the helmet when in use is guaranteed. Furthermore, the path of external noise entering the interior of the helmet can be blocked and the comfort of the helmet when in use is improved. Meanwhile, since the operating space occupied by the external gear rotating around a fixed axis is relatively small, a more flexible arrangement option is provided for the fixing structure of the support bases, the rigidity of the support of the support bases and can further improve the overall safety of the helmet.
[0064] BRIEF DESCRIPTION OF THE DRAWINGS
[0065] Figure 1 is an axonometric view of a helmet with a gear restraint transformable chin guard structure in accordance with one embodiment of the present disclosure;
[0067] Figure 2 is a side view when the helmet with the gear restraint transformable chin guard structure of Figure 1 is in a state of a full helmet frame;
[0069] Figure 3 is a side view when the helmet with the gear restraint transformable chin guard structure of Figure 1 is in a state of semi-helmet structure;
[0071] Figure 4 is an exploded view showing the assembly of the helmet with the structure of transformable chin guard with gear restraint of Figure 1;
[0073] Figure 5 is a schematic diagram showing the status of a process of changing a chin rest from a full helmet structure position to a semi-helmet structure position in the helmet with the transformable chin rest structure with gear restriction of according to one embodiment of the present disclosure;
[0075] Figure 6 is a schematic diagram showing the state of a process of returning the chin rest from the semi-helmet structure position to the full helmet structure position in the helmet with the transformable chin rest structure with gear restriction of according to one embodiment of the present disclosure;
[0077] Figure 7 is an axonometric diagram of an embodiment of an inner support plate of a support base in the helmet with the gear restraint transformable chin guard structure in accordance with one embodiment of the present disclosure;
[0079] Figure 8 is a radial diagram of the inner support plate of Figure 7 when viewed in a direction from the shell body inside the helmet to the outside of the helmet along the internal gear axis;
[0081] Figure 9 is a radial diagram of the inner support plate of Figure 7 when viewed in a direction from the outside of the helmet to the shell body of the helmet along the internal gear axis;
[0083] Figure 10 is an axonometric diagram of an embodiment of an outer support plate of a support base in the helmet with the transformable chin guard structure with gear restraint;
[0084] Figure 11 is a radial diagram of the outer support plate of Figure 10 when viewed in a direction from the shell body inside the helmet to the outside of the helmet along the internal gear axis;
[0086] Figure 12 is a radial diagram of the outer support plate of Figure 10 when viewed in a direction from the outside of the helmet to the shell body of the helmet along the internal gear axis;
[0088] Figure 13 is an axonometric view of the internal gear of the helmet with the transformable chin guard structure with gear restraint in accordance with one embodiment of the present disclosure;
[0090] Figure 14 is an axonometric view of the internal gear of Figure 13 when viewed in another direction;
[0092] Figure 15 is a radial diagram of the internal gear of Figure 13 when viewed in a direction from the outside of the helmet to the shell body of the helmet along the internal gear axis;
[0094] Figure 16 is a radial diagram of the internal gear of Figure 13 when viewed in a direction from the shell body inside the helmet towards the outside of the helmet along the internal gear axis;
[0096] Figure 17 is an axonometric view of the outer gear of the helmet with the gear restraint transformable chin guard structure in accordance with one embodiment of the present disclosure;
[0098] Figure 18 is an axonometric view of the external gear of Figure 17 when viewed in other address;
[0100] Figure 19 is a radial diagram of the external gear of Figure 17 when viewed in a direction from the outside of the helmet to the shell body of the helmet along the external gear axis;
[0102] Figure 20 is a radial diagram of the external gear of Figure 17 when viewed in a direction from the shell body inside the helmet to the outside of the helmet along the external gear axis;
[0104] Figure 21 is an axonometric diagram of one embodiment of the chin guard and its ramifications;
[0106] Figure 22 is a side view of the chin guard and its branches in Figure 21;
[0108] Figure 23 is a side view of the chin guard and its branches in Figures 21 and 22 when fitted with a snap cover;
[0110] Figure 24 is an axonometric diagram of one embodiment of the chin guard ramifications of the chin guard;
[0112] Figure 25 is a radial diagram of the snap cover of Figure 24 when viewed in a direction from the shell body inside the helmet to the outside of the helmet;
[0114] Figure 26 is a sectional view of one embodiment of the assembly of the internal gear, the external gear, the chin rest branches and the chin rest branch snap cover;
[0115] Figure 27 is a schematic diagram showing the meshing between the inner gear and the outer gear when a ratio of a pitch radius R of the inner gear to a pitch radius r of the outer gear is designed as 2: 1 in the helmet with the transformable chin guard structure with gear restraint in accordance with one embodiment of the present disclosure;
[0117] Figure 28 is a schematic diagram showing the state changes of the inner gear and the outer gear in accordance with one embodiment of the present disclosure, in which the ratio of the pitch radius R of the inner gear to the pitch radius r of the outer gear is designed as 2: 1, a through groove of the inner gear is straight and the through groove rotates to a certain position from an initial position perpendicular to a plane constituted by the inner gear shaft and the outer gear shaft;
[0119] Figure 29 is a schematic diagram showing a geometric relationship in the embodiment shown in Figure 28;
[0121] Figure 30 is a schematic diagram when a ratio of a number of teeth equivalent to the full circumference of the internal gear ZR converted from the mesh elements of the internal gear to a number of teeth equivalent to the full circumference of the external gear Zr converted from the elements gear included in the external gear satisfies a ratio ZR / Zr = 2, according to one embodiment of the present disclosure;
[0123] Figure 31 is a schematic diagram showing the changes of state of a relative positional relationship between the corresponding straight through slot, the restraining slide rails in a linear slideable kinematic pair, and a drive member together with the rotational movement of the chin rest in the helmet with the transformable chin rest structure with gear restriction according to an embodiment of the present disclosure, when the ratio of the pitch radius R of the inner gear to the pitch radius r of the outer gear is R / r = 2: 1 or the ratio of the number of full circumference equivalent teeth of the inner gear ZR to the number of full circumference equivalent teeth of external gear Zr is ZR / Zr = 2;
[0125] Figure 32 is a schematic diagram showing clamp fit states between a first clamp structure and a second clamp structure on the helmet with the gear restraint transformable chin guard structure in accordance with one embodiment of the present disclosure, when the chin guard is in a full helmet structure position state, a bare face structure position state and a semi-helmet structure position state, respectively;
[0127] Figure 33 shows a side view and an axonometric view of the internal gear linkage, a trigger pin, the legs of a visor and a load bearing rail side on the helmet with the transformable chin guard structure with gear restraint of In accordance with one embodiment of the present disclosure, when the chin guard is moved from the full-helmet frame position to the semi-helmet frame position and the initially located visor in a fully buckled position is opened;
[0129] Figure 34 shows a side view and an axonometric view of the internal gear linkage, trigger pin, visor legs and load bearing rail side on the helmet with the transformable chin guard structure with gear restraint of According to one embodiment of the present disclosure, when the chin guard is returned from the semi-helmet frame position to the full helmet frame position and the initially located visor in the fully fastened position is opened;
[0131] Figure 35 is a schematic diagram showing the changes of state of the helmet with the transformable chin guard structure with gear restraint in accordance with a embodiment of the present disclosure, when the chin guard is moved from the full helmet frame position to the semi-helmet frame position and the initially located visor in the fully fastened position is unlocked; Y
[0133] Figure 36 is a schematic diagram showing the state changes of the helmet with the transformable chin rest structure with gear restriction in accordance with one embodiment of the present disclosure, when the chin rest is returned from the semi-helmet structure position to the full helmet frame position and the visor initially located in the fully fastened position is unlocked.
[0135] DETAILED DESCRIPTION OF THE EMBODIMENTS OF THE INVENTION
[0136] The present disclosure will be described in more detail below by specific embodiments with reference to Figures 1-36.
[0138] A helmet with a gear restraint transformable chin rest structure is provided, including a shell body 1, a chin rest 2 and two support bases 3. The two support bases 3 are arranged on two sides of the shell body 1, respectively. The two support bases 3 are fixed to the casing body 1 (as shown in Figures 1 and 4), or they are integrated with the casing body 1 (not shown). Here, in the embodiments of the present disclosure, the connection between the two support bases 3 and the casing body 1 includes, but is not limited to four situations: 1) the two support bases 3 are independent parts and are fixed to the casing body 1 (as shown in Figures 1-4); 2) the two support bases 3 are fully integrated with the casing body 1 (not shown); 3) a portion of each of the two support bases 3 is integrated with the carcass body 1, while the resting portion of each of the two support bases 3 is constructed as an independent member (not shown); and 4) one of the two support bases 3 is fixed on the housing body 1, while the other of the two support bases 3 is integrated with the housing body 1 (notshown). Additionally, that "the two support bases 3 are arranged on two sides of the casing body 1, respectively" in the embodiments of the present disclosure, means that the two support bases 3 are arranged on two sides of a plane of symmetry P of the shell body 1, in which the plane of symmetry P passes through the mouth, nose and head of the user and separates the eyes, ears of the user and the like on two sides of the user when the user normally wears the helmet , that is, the plane of symmetry P is actually an imaginary plane dividing the carcass body 1 in half (as shown in Figure 1). In other words, the plane of symmetry P in the embodiments of the present disclosure can be considered as a plane of bilateral symmetry of the carcass body 1. The plane of symmetry P passing through the carcass body 1 will have an intersection line S with a contoured outer surface of the casing body 1 (see Figures 1 and 4). In the embodiments of the present disclosure, an optimal arrangement of the support bases 3 is that each of the two support bases 3 is arranged on one of the two sides of the casing body 1 near or close to the ear of the user of the helmet (as shown in Figures 1-4). In the embodiments of the present disclosure, the chin guard 2 has two branches 2a (see Figures 4 and 21), the two branches are arranged on two sides of the carcass body 1 (as shown in Figure 4), that is, the two branches 2a are arranged on two sides of the plane of symmetry P of the carcass body 1. Preferably, a portion of the body of each of the two branches 2a is arranged or extended to one of the two sides of the carcass body 1 near or close to the ear of the helmet wearer (as shown in Figures 1-4). Here, each of the two branches 2a can be the body of the chin rest 2 or an extension of the body of the chin rest 2. In particular, the branches 2a can also be independent parts attached or attached to the body of the chin rest 2 (including an extension or lengthening of the body of the chin guard 2). In other words, in the embodiments of the present disclosure, the body of each of the two branches 2a includes not only a portion of the body of the chin guard 2 but also other parts attached to the body of the chin guard 2. As shown in Figures Figures 4 and 23, each of the two branches 2aIt consists of a chin guard body extension 2 and a snap cover 2b attached to the extension. Thus, according to embodiments of the present disclosure, when each of the two branches 2a includes a clasp cover 2b, the branch 2a may also be indicated by 2a (2b) in the drawings. It should be noted that, in the embodiments of the present disclosure, each of the two support bases 3 can be a part assembled or combined by several parts (as shown in Figure 4), or it can be a part composed of a single member (not shown), wherein the support base 3 being combined by several parts is optimal in that this support base 3 can be manufactured, assembled and maintained more flexibly. In the case shown in Figure 4, each of the two support bases 3 is a component combined by several parts. In the case shown in Figure 4, each of the two support bases 3 comprises an inner support plate 3a and an outer support plate 3b. Additionally, in some drawings of embodiments of the present disclosure, for example, in Figure 32, the inner support plate 3a may be indicated by a support base 3 (3a), and the outer support plate 3b may be indicated by a support base 3 (3b). Additionally, it should also be noted that, in the embodiments of the present disclosure, the carcass body 1 is a general term. The carcass body 1 can be the carcass body 1 itself, or it can include various other parts attached and attached to the carcass body 1 as well as the carcass body 1 itself. These parts include various functional parts or decorative parts such as a window. of air, a seal cover, a pendant, a sealing element, a clamp and an energy absorbing element. The embodiments of the present disclosure are characterized in that: for each of the two support bases 3, an internal gear 4 restricted by the support base 3 or / and the casing body 1 and an external gear 5 restricted by the base support 3 or / and casing body 1 are provided correspondingly (see Figures 4, 13-20). The internal gear 4 can rotate around the internal gear shaft O1 of the internal gear 4, and the external gear 5 can rotate around an external gear shaft O2 of the external gear 5 (see Figures 28 and 29). Here, in the embodiments of the present disclosure, the internal gear 4 and the gearexternal gear 5 are meshed with each other, internal gear 4 is an internal toothed gear, and external gear 5 is an external toothed gear. Therefore, in the embodiments of the present disclosure, the meshing of the internal gear 4 with the external gear 5 belongs to the gear transmission of an internal gear property. It is worth mentioning that the internal gear 4 and the external gear 5 in the embodiments of the present disclosure can be cylindrical gears (as shown in Figures 4, 14, 16-19, 27 and 28) or non-cylindrical gears (not shown). It is preferable that the inner gear 4 and the outer gear 5 are cylindrical gears. When the inner gear 4 and the outer gear 5 are cylindrical gears, the inner gear shaft O1 is a shaft passing through a center of a reference circle of the inner gear 4, and the outer gear shaft O2 is a shaft passing through a center of a reference circle of outer gear 5. Here, the center of the reference circle of inner gear 4 coincides with the center of a pitch circle of inner gear 4, and the center of the reference circle of the outer gear 5 coincides with the center of a pitch circle of the outer gear 5. In the embodiments of the present disclosure, particularly in a preferred arrangement situation, the inner gear shaft O1 and the outer gear shaft O2 are parallel between yes and perpendicular to the plane of symmetry P of the casing body 1. It should be noted that, in the embodiments of the present disclosure, the fixed axis rotation of the internal gear 4 and the external gear 5 it can be generated under the restriction of the support base 3 or / and the carcass body 1, or it can be generated under the restriction of the support base 3 or / and the carcass body 1 in combination with other restrictions. For example, in the case shown in Figure 4, the external gear 5 can rotate in the restriction of the support base 3 or / and the casing body 1 as well as in the restriction of the gear ratio between the internal gear 4 and the outer gear 5. The inner gear 4 and the outer gear 5 are not only surrounded and constrained by edges 3c on the support base 3, but also limited by the meshing action between these two gears (see Figures 4 and 32) . Therefore, in Fig. 4, the inner gear 4 and the outer gear 5 perform fixed axis turning behaviors under the joint constraint of multiple parts. In fact,Since the support base 3 in the embodiment shown in Figure 4 has an edge 3c that surrounds the inner gear 4 and an edge 3c that surrounds the outer gear 5, these edges 3c surround and restrict the restricted objects by more than 180 degrees , the internal gear 4 and the external gear 5 can be restricted to realize fixed axis turning behaviors only depending on the restriction of these edges 3c, and the fixed axis turning of the gears can be more stable and reliable under the restriction of the edges 3c in combination with the meshing action of these two gears. However, if the constrained object (i.e., internal gear 4 or outer gear 5) is surrounded by edge 3c by no more than 180 degrees (not shown), it is obvious that the reliable fixed axis rotation of the constrained object additionally requires the mesh restriction of the internal gear 4 and the external gear 5 or the restriction of other members. Here, the edges 3c can be part of the body of the support base 3 (as shown in Figures 4, 7 and 9, the edges 3c form part of the body of the inner support plate 3a of the support base 3) , or they can be independent elements fixed on the support base 3 (not shown). Additionally, there may be one or more edges 3c to restrain a certain meshing, and the shape of the edge 3c can be set according to the specific structural arrangement. For example, in the cases shown in Figures 4, 7 and 9, the edge 3c to restrict the internal gear 4 is a closed circular edge in the form of a ring that may have some notches, while the edge 3c to restrict the external gear 5 is a semi-closed open circular arc shaped edge that may also have some notches. Indeed, in the embodiments of the present disclosure, in addition to the ring-shaped or arc-shaped configuration, the edge 3c may have other configurations such as convex bolt, convex key, column, or convex lug, or it may be in a continuous configuration or a discontinuous configuration. For example, if three contact points distributed in the form of an acute triangle (that is, the triangle formed by the three points when used as a vertex is an acute triangle) are used as constraint members, the effect of the axis rotation behavior Fixed achieved by restraining using all three contact points is equivalent to the effect of the fixed axis turning behavior achieved by restraining using a ring-shaped edgethat surrounds the restrained object by more than 180 degrees. It should be noted that, in addition to the fact that the internal gear 4 and the external gear 5 may be limited by the structure and construction of the edges 3c, in the embodiments of the present disclosure, the rotational behavior of the internal gear 4 and the external gear 5 can be limited by a shaft / hole structure or a shaft / sleeve structure which can be constituted, for example, in the support base 3, and the internal gear 4 and the external gear 5 can be forced to rotate by the structure shaft / hole or the shaft / sleeve structure (the hole or sleeve can be of a full structure or it can be an incomplete structure with notches). Meanwhile, a shaft structure in rotary fit with the bore or sleeve is constituted in the inner gear 4 or / and in the outer gear 5 (not shown). In this way, a fixed axis restriction can be realized on the internal gear 4 or the corresponding external gear 5, and the internal gear 4 and the external gear 5 can rotate even depending only on these limitations. Of course, the shaft arranged in the internal gear 4 must have an axis coincident with the internal gear shaft O1 and must be coaxial with the hole or sleeve constituted in the support base 3 that is coupled with this shaft, and the shaft arranged in the external gear 5 it must have a shaft coincident with the external gear shaft O2 and it must be coaxial with the hole or sleeve constituted in the support base 3 that is coupled with this shaft. Similarly, it is also possible that a shaft structure is constituted on the support base 3 and a hole or sleeve structure is correspondingly constituted on the internal gear 4 or / and on the external gear 5 to be coupled with the frame. shaft (not shown). This will not be repeated here due to the similar principle. In the embodiments of the present disclosure, the mesh of the internal gear 4 with the external gear 5 means that the internal gear 4 and the external gear 5 are meshed with each other by a toothed structure or configuration and perform the delivery and transmission of movement and power. based on the gear. The effective gear teeth of the internal gear 4 or the outer gear 5 may be distributed over an entire circumference, that is, the effective gear teeth are distributed at 360 degrees (for example, in the casesshown in Figures 4, 17, 19, 27 and 28, the external gear 5 belongs to this situation); or, the effective gear teeth may not be distributed over the entire circumference, that is, the effective gear teeth are distributed in a reference circle that has an arc length of less than 360 degrees (for example, in the cases shown in Figures 4, 14, 16, 27 and 28, the internal gear 4 belongs to this situation). The so-called effective gear teeth refer to the gear teeth that are actually involved in meshing (including teeth and tooth bushes, hereafter). Additionally, the effective gear teeth of the inner gear 4 and the outer gear 5 in embodiments of the present disclosure can be measured or evaluated by modulus. However, the size of the tooth shape may not be measured or evaluated by modulus. When the effective gear teeth of the internal gear 4 and the external gear 5 are measured by module or the size of the tooth shape is evaluated by module (for example, when two gear gears are evolving gears), for matched and meshed gears (including teeth and tooth bushes), the modules of the two gears are preferably the same. However, in a case where the abnormal teeth / tooth bushings or modified teeth / tooth bushings are meshed, the modules of the two gears may not be the same. It should be noted that, even for the same gear, the modulus of all the effective gear teeth of this gear is not necessarily required to be the same. For example, according to the embodiments of the present disclosure, abnormal gear teeth or individual abnormal tooth bushes or some are allowed on all effective gear teeth of internal gear 4 (see abnormal tooth bushing 8b and teeth of modified gears 8c in Figures 14, 16, 27 and 28), and abnormal gear teeth or individual or some abnormal tooth bushings are allowed on all effective gear teeth of external gear 5 (see abnormal gear tooth 8a in Figures 17-18, 27 and 28). Alternatively, if viewed or measured from the reference circle, the inner gear 4 and the outer gear 5 are allowed to have different tooth thicknesses or different tooth bushing widths. TheFigures 27 and 28 show a case in which there are abnormal tooth bushings 8b in the internal gear 4 while there are abnormal gear teeth 8a in the external gear 5, in which the abnormal tooth bushings 8b in the internal gear 4 are present in the form of tooth bushes, and the abnormal gear teeth 8a in the outer gear 5 are present in the form of teeth; and, the abnormal gear teeth 8a in the outer gear 5 and the abnormal tooth bushings 8b in the inner gear 4 are intermeshed restraining objects. Additionally, in the case shown in Figures 27 and 28, there are tooth-shaped modified gear teeth 8c in the internal gear 4. It is not difficult to find that the abnormal gear teeth 8a and the mentioned modified gear teeth 8c above are different from each other in shape and size and also different from other normal effective gear teeth in shape. In other words, if the shape and size of the abnormal gear teeth 8a and the modified gear teeth 8c can be measured per module, the modules for both will be different from each other, and the modules for both will also be different from the modules for other normal effective gear teeth. It should also be noted that, in the embodiments of the present disclosure, there is a particular case where individual or several gearless meshing behaviors may occur in the process of meshing between the internal gear 4 and the external gear 5, that is, some Gearless member engagement forms having transitional properties, such as column / groove engagement, key / groove engagement, or cam / undercut engagement, are allowed to be provided in certain gaps, segments, or normal engagement processes of the internal gear 4 with external gear 5. The size of these gearless members may or may not be evaluated by modulus. In other words, for gearless meshing, the size of the meshing structure can be measured in ways other than modulus. It should be noted that the abnormal gear tooth 8a, the abnormal tooth bushing 8b, and the modified gear tooth 8c in embodiments of the present disclosure may be conventional gear shapes that are measured by modulus in tooth bushing shape or size, or they may be gear members withoutgears that are not measured by modulus in tooth bushing shape or size. It should also be noted that, in embodiments of the present disclosure, although gearless member engagement is possible, the gearless member engagement is simply an auxiliary transition gear, and the posture transformation mechanism to guide and restrict the chinrest 2 to change in the telescopic positional displacement and the oscillation angular posture is still restricted and is mainly realized by the gear meshing, such that the properties and behaviors of the gear-constrained transformable chinrest structure in the realizations of this disclosure is not substantially modified. In particular, it should be noted that, in the embodiments of the present disclosure, for the internal gear 4 and the external gear 5 meshed together, the shape of the effective gear teeth includes shapes of various gear configurations in the prior art, for example , shapes obtained by various creation methods, such as a generation method or a profiling method, as well as shapes obtained by various manufacturing methods, such as mold making, wire cutting, spark making or three-dimensional shaping. The shapes of the gear teeth include, but are not limited to, the evolving tooth shape, cycloidal tooth shape, hyperbolic tooth shape, or the like, among which the enveloping tooth shape is most preferable (the gears shown in Figures 4, 14, 16, 17-18, 27 and 28 have evolving gear teeth). This is because evolve gears have a low manufacturing cost and are easy to assemble and clean. Additionally, the evolving gear teeth can be used for spur gears or bevel gears. In embodiments of the present disclosure, a through slot 6 is formed in the internal gear body 4 or in an internal gear fitting 4. The through slot 6 may be formed in the internal gear body 4 (as shown in the Figures 4 and 13-16), or it may be constituted in an accessory fixed to the internal gear 4 (not shown). The accessory is another part attached to the internal gear 4. It should be noted that, in the embodiments of the present disclosure, the through groove 6 has a through penetration property. That is, whenthrough slot 6 is viewed in an axial direction of internal gear shaft O1, through slot 6 can be found to have a through shape that can be seen through (see Figures 4, 13-16, 27, 28 and 30 ). Here, the through groove 6 may have various shapes (that is, the shape seen in the axial direction of the internal gear shaft O1), wherein the through groove 6 is in the shape of a strip, particularly, in the shape of a straight strip is more preferable (as shown in Figures 4, 13-16, 27, 28 and 30). This is because the through slot 6 in the form of a straight strip has the simplest structure and occupies a small space, in such a way that it is convenient to hide, hide, occlude and cover the through slot 6. Additionally, in the embodiments of In the present disclosure, a drive member 7 is further provided which runs through the through slot 6 (see Figures 4 and 31). The drive member 7 may be disposed between the outer gear 5 and the branch 2a, and may run through the body of the inner gear 4 or the fixture of the inner gear 4 to join with the outer gear 5 and the branch 2a, respectively. In embodiments of the present disclosure, the support base 3, the branch 2a, the internal gear 4, the external gear 5, and the drive member 7 on one side of the casing body 1 form an associated mechanism. That is, there is a structural assembly relationship, a path restriction relationship, a position lock relationship, a kinematic coordination relationship, an energy transfer relationship, or the like between the parts that make up the associated mechanism. Additionally, it should be noted that, in embodiments of the present disclosure, the actuating member 7 includes or has at least two ends, that is, the actuating member 7 has at least two ends that can be fitted with external parts. It should also be noted that, in the embodiments of the present disclosure, the actuating member 7 may be in the form of a single part or a combination of two or more parts. When the actuating member 7 is a combination of parts, the parts may be in a combined form of immobile adjustment, or a combined form of movable adjustment, in particular, they may also be a combined form of relative rotation. Additionally, in embodiments of the present disclosure, the actuating member 7 hastwo situations in particular: 1) the drive member 7 is attached to the external gear 5 (including a situation in which the drive member 7 and the outer gear 5 are integrated; as shown in Figures 4 and 17-19); and, 2) the drive member 7 is attached to branch 2a (including a situation where the drive member 7 and branch 2a are integrated, not shown). As described above, in embodiments of the present disclosure, branch 2a may be an integral part, ie, a single body structure. Additionally, branch 2a may be a multi-part assembled component, ie a body structure with a combined configuration (as shown in Figures 4 and 23). In Figures 4 and 23, branch 2a actually includes the body of the chin guard 2 (including a body extension), a snap cover 2b attached to the body, and other parts. Therefore, the situation where the actuating member 7 is attached to the branch 2a includes a situation where the actuating member 7 is directly attached to the body of the branch 2a (i.e., attached to the body of the chin guard 2 or the chin guard extension 2, not shown) and a situation in which the actuating member 7 is attached to a constituent part of the branch 2a (not shown). In embodiments of the present disclosure, in the associated mechanism, the branch 2a is disposed outside the through slot 6 in the internal gear 4, the external gear 5 and the internal gear 4 are meshed with each other to constitute a kinematic pair, and internal gear 4 is in sliding fit with branch 2a to constitute a sliding kinematic torque. One end of the drive member 7 is connected to the external gear 5, such that the drive member 7 can be driven by the external gear 5 or the external gear 5 can be driven by the drive member 7; and, the other end of the drive member 7 is connected to the branch 2a, such that the branch 2a can be driven by the drive member 7 or the drive member 7 can be driven by the branch 2a. Here, in the embodiments of the present disclosure, the kinematic torque constituted by the external gear 5 and the internal gear 4 belongs to a pair with gear restriction,and the kinematic pair constituted by the internal gear 4 and the branch 2a belongs to a sliding kinematic pair (the sliding kinematic pair can be grooved rails, guide rails or other types of sliding pairs). For convenience of description, in embodiments of the present disclosure, the internal gear elements 4 that make up the sliding kinematic torque may be collectively referred to as the first slide rails A (see Figures 4, 13-16 and 31), and the elements of the branch 2a constituting the sliding kinematic pair may be collectively referred to as second sliding rails B (see Figures 4, 21, 22 and 31). The first sliding rails A and the second sliding rails B are adjusted in sliding to constitute the sliding kinematic torques (see Figure 26), in such a way that the purpose of restricting the internal gear 4 and the branch 2a to perform a relative slip. It should be noted that, in embodiments of the present disclosure, the sliding kinematic pair actually includes several grooved rail-type sliding kinematic pairs and several guide rail-type sliding kinematic pairs in the prior art, and there may be one or more rails. grooved on the grooved rail-type sliding kinematic pair or one or more guide rails on the guide rail-type sliding kinematic pair. Particularly, in embodiments of the present disclosure, the first slide rails A and the second slide rails B may be paired in one-to-one correspondence to constitute slidable kinematic pairs (i.e., only a second slide rail B is in slidable fit. with a first slide rail A, and only a first slide rail A is in sliding fit with a second slide rail B), or cannot be matched one-to-one to constitute slideable kinematic pairs (i.e. each of the first slide rails A may be in sliding fit with a plurality of second slide rails B, or each of the second slide rails B may be in slide fit with a plurality of first slide rails A). It should be noted that, in the embodiments of the present disclosure, the first slide rails A and the second slide rails B can be interchanged, that is, the firstSlide rails A and second slide rails B can be interchanged in terms of structural and functional characteristics. The restraint effects achieved by the kinematic restraint and the trajectory restraint to the chin rest by the first slide rails A and the second slide rails B before and after the interchange are comparative or equivalent. Taking the structural feature as an example, if the original first slide rail A appears in the form of a groove structure, the original second slide rail B appears in the form of a convex rail structure, and the first slide rail A and the second rail slide rail B are paired with each other, the first slide rail A and the second slide rail B can be interchanged in structure, that is, the groove structure of the original first slide rail A is changed to a convex rail structure, and the second slide rail B of the convex rail structure originally paired with the first slide rail A is changed to a groove structure, such that the slideable kinematic pairs constituted by the first slide rail A and the second slide rail B before and after the exchange are equivalent. It should also be noted that, in the embodiments of the present disclosure, the description "branch 2a is arranged outside of through slot 6 in internal gear 4" means that if chin guard 2 is observed when placed in the position of frame structure full helmet or in the semi-helmet frame position, and if the chin guard 2 travels from the outside to the inside of the helmet (or towards the shell body 1) along the internal gear axis O1, the chin guard 2 is first encounters branch body 2a, then reaches through groove 6 in internal gear 4 and finally reaches casing body 1, i.e. branch 2a is located at an outer end further away from casing body 1 than through slot 6. In embodiments of the present disclosure, an advantage that is achieved by arranging branch 2a outside of through slot 6 is that favorable conditions can be provided for the ra through groove 6 is covered by branch 2a. In embodiments of the present disclosure, a drive logic and operation executed by the chin guard 2, theinternal gear 4, external gear 5, and drive member 7 on associated mechanism (i.e., internal gear 4, outer gear 5, and drive member 7 on associated mechanism and chin guard 2, four parts in total ) includes at least one of the three situations a), b) and c): a) The chin rest begins with an initial rotation action; then, the chin guard 2 drives the internal gear 4 through the branch 2a, in such a way that the internal gear 4 rotates around an internal gear shaft O1 of the internal gear 4; after which, the inner gear 4 drives the outer gear 5 by meshing therebetween, so that the outer gear 5 rotates about an outer gear shaft O2 of the outer gear 5; and then, the outer gear 5 drives the branch 2b by the drive member 7, so that the branch 2a moves and is driven to perform slidable displacement relative to the internal gear 4 under joint restriction of the slidable kinematic torque; and finally, the position and posture of the chin rest 2 are correspondingly changed during a rotation process of the chin rest 2; b) The internal gear 4 begins with an initial rotating action around the internal gear shaft O1; then, the internal gear 4 drives the chin guard 2 to perform a corresponding rotational movement by means of the sliding kinematic torque constituted by the internal gear 4 and the branch 2a (here, a rotational force of the internal gear 4 will act on the sliding kinematic torque in moment shape and branch 2a is driven to rotate at the moment, to cause chin guard 2 to make a corresponding rotational movement); meanwhile, the inner gear 4 drives the outer gear 5 by meshing therebetween, so that the outer gear 5 rotates around an outer gear shaft O2 of the outer gear 5; the outer gear 5 drives the branch 2a by the drive member 7, so that the branch 2a moves and is driven to perform a slidable displacement relative to the internal gear 4 under the joint restriction of the slidable kinematic torque; and finally, the position and posture of the chin rest 2 are correspondingly changed during a rotation process of the chin rest 2. c) The external gear 5 starts with an initial rotating action around the axis ofexternal gear O2; then, the outer gear 5 drives the inner gear 4 to rotate about an inner gear shaft O1 of the inner gear 4 by meshing between them; after which, on the one hand, the internal gear 4 drives the chin guard 2 to perform a corresponding rotational movement by means of the sliding kinematic torque constituted by the internal gear 4 and the branch 2a (here, the internal gear 4 applies a moment to the rotationally slidable kinematic torque, and the branch 2a is driven at the moment of turning to drive the chin guard 2 to make a corresponding rotational movement); on the other hand, the external gear 5 drives the branch 2a by the drive member 7, so that the branch 2a moves and is driven to perform a slidable displacement with respect to the internal gear 4 under the joint restriction of the slidable kinematic torque; and finally, the position and posture of the chin rest 2 are correspondingly changed during a rotation process of the chin rest 2. Here, the "rotation action" described in the embodiments of the present disclosure means that the chin rest 2 is rotated by a angle relative to the carcass body 1 during a movement of the chin guard 2, particularly including but not limited to the process of moving the chin guard 2 from the full helmet frame position to the semi-helmet frame position and the process of movement from the semi-hull structure position to the full-hull structure position, the same hereinafter. Additionally, the so-called "initial" described in the embodiments of the present disclosure means the mechanical or kinematic behavior of the first activated part (or the part that is first actuated by an external force) between the three parts, that is, the chin guard 2, internal gear 4 and external gear 5, the same hereinafter. Additionally, in embodiments of the present disclosure, the actuation and operation logic executed by chin guard 2, internal gear 4, external gear 5, and actuation member 7 in the associated mechanism can be any of the three situations. a), b) and c), or a combination of two of the three situations a), b) and c), or all three situations a), b) and c). In particular, Any of one, two or all three situations a), b) and c) can be combined with other types of drive and operation logic. Among the logics ofactuation and operation in the above situations, the actuation and operation logic in situation a) is most preferable in the embodiments of the present disclosure, because the actuation and operation logic in situation a) is the simplest actuation mode (In this case, the helmet user can precisely control the position and posture of the chin guard 2 by pulling the chin guard by hand). The process of performing manual actuation and operation in the embodiments of the present disclosure will be detailed below taking situation a) as an example. Firstly, the helmet user unlocks the chin guard 2 manually in the full helmet frame position or the semi-helmet frame position or a certain intermediate frame position (ie open face frame position). Second, the wearer of the helmet manually opens or buckles the chin guard 2 to cause the chin guard 2 to generate an initial rotating action. Then the chin guard 2 drives the internal gear 4 to rotate around the internal gear shaft O1 through branch 2a. Next, the internal gear 4 drives the external gear 5 to rotate about the external gear shaft O2 by meshing therebetween. Subsequently, the outer gear 5 drives the branch 2a to move by the drive member 7, and the branch 2a can perform slidable displacement relative to the inner gear 4 under joint restriction of the slidable kinematic torque. Therefore, the branch 2a performs an extension / retraction movement while rotating around the internal gear shaft O1. Finally, the position and posture of the chin rest 2 are correspondingly changed during a rotation process of the chin rest 2. From the rotation process of the chin rest 2 illustrated in this embodiment, it is not difficult to find that the chin rest 2 can be extended. / retract in time during the chin guard 2 opening process by simply rotating the chin guard 2. The secret is the principle of gear meshing and the derivation of the reciprocating movement by the drive member 7. Therefore, the complicated operation of rotating , simultaneously pulling and pressing the chin guard 2 in conventional helmets with a transformable chin guard structure (see Chinese Patent Application ZL201010538198.0 and Spanish Patent ApplicationES2329494T3) can be greatly simplified. It should be noted that, in the embodiments of the present disclosure, the slidable displacement of branch 2a with respect to internal gear 4 is reciprocating telescopic. That is, in the embodiments of the present disclosure, the rotational movement of the chin guard 2 and the branch 2a thereof is accompanied by the reciprocating movement with respect to the internal gear 4 (it is equivalent to the chin guard 2 performing a reciprocating movement relative to the housing body 1). In the embodiments of the present disclosure, for this feature alone, the position and posture of the chin rest 2 can be changed in time during the rotation process of the chin rest 2. As described above, in the embodiments of the present disclosure , the sliding kinematic pair constituted by the internal gear 4 and the branch 2a can be grooved rails, guide rails or other types of sliding pairs. That is, the sliding kinematic torque constituted by the internal gear 4 and the branch 2a can be of various types of sliding pairs in the prior art, particularly, including but not limited to, slide / slide, guide bar / guide sleeve, slide / guide pin, slide / slide rail or the like. In this case, it means that the branch 2a of the chin guard 2 is preferably attached to, abutted against or embedded in the internal gear 4, and a relative movement can be generated between the branch 2a and the internal gear 4. It should also be noted that, In embodiments of the present disclosure, the power to drive the chin guard 2 to perform the initial rotating action, drive the internal gear 4 to perform the initial rotating action, or drive the external gear 5 to perform the initial rotating action can be derived the actuation of a motor, a spring, a human hand or the like. The drive power can be a single drive power or a combination of a plurality of drive powers. It is preferable that the driving force is generated by human hands, because this driving mode is the simplest and most reliable. In this case, the user of the helmet can directly pull the chin guard 2 with their hands to rotate the chin guard 2, or directly pull the internal gear 4 with their hands to rotate the internal gear 4, or directly pull the external gear 5 with the hands to turn theexternal gear 5. Also, in addition to directly pulling the parts related to the hands, the helmet user can indirectly actuate the chin guard 2, the internal gear 4 or the external gear 5 to perform the corresponding movement by means of various binding members, such as ropes, tip members, or guide bars (not shown). Particularly, it should be noted that, in the description "the internal gear 4 can rotate around the internal gear axis O1 of the internal gear 4, and the external gear 5 can rotate around the external gear axis O2 of the external gear 5" in the embodiments of the present disclosure, the internal gear shaft O1 and the external gear shaft O2 are not required to be in an absolute fixed shaft state or an absolute straight shaft state, and these shafts may have certain deflection errors and errors. deformation. That is, under various factors such as manufacturing error, assembly error, stress deformation, temperature deformation and vibration deformation, the internal gear shaft O1 and the external gear shaft O2 may have deflection and distortion conditions such as displacement. , flapping, dejection, oscillation and lack of straightness within a certain interval of errors. The range of errors described herein refers to a magnitude of error that leads to a final overall effect that does not affect the normal process of rotation of the chin guard 2. There is no doubt that, in the embodiments of the present disclosure, the occurrence of non-parallel and non-straight O1 internal gear shaft and O2 external gear shaft in a local area due to various factors, including but not limited to the need for modeling, the need to overcome obstacles, and the need to block position is allowed, in which the "modeling need" means that the chin guard 2 is required to obey a general appearance modeling of the helmet; the "need to overcome obstacles" means that the chin guard 2 is required to overcome some limiting points such as the highest point, the furthest point and the widest point; and, the "need for position locking" means that the chin guard 2 is required to be elastically deformed to pass through some clamping members in the full-helmet frame position, the semi-helmet frame position, and the semi-helmet frame position. open-face structure, as well as in the vicinity of these positionsindividuals. All non-parallel and non-straight phenomena of the internal gear shaft O1 and the external gear shaft O2 (including the phenomenon that the internal gear shaft O1 and the external gear shaft O2 are not perpendicular to the plane of symmetry P of the body 1) due to the above reasons, it will be considered to be within the range of errors allowed in the embodiments of the present disclosure, provided that the normal rotation operation of the chin guard 2 is not affected. It should be noted that, in embodiments of the present disclosure, the "open face frame position" refers to any position between the full hull frame position and the semi-hull frame position, in which the helmet is located. in an intermediate state, also called a bare-face state (the helmet may be called a bare-face helmet). The open-face helmet is in a state of "quasi-semi-helmet structure". The chin guard 2 in the open-face frame position can be in different frame position states, such as a slight opening degree, a medium opening degree and a high opening degree (in which the opening degree is relative to the full helmet frame position, and the chin guard 2 in the full helmet frame position can be set to zero opening degree, i.e. not open at all). The slight opening degree refers to a state in which the chin guard 2 is slightly open, and the chin guard 2 slightly open is beneficial for ventilation and dissipating breathing vapor in the helmet. The medium opening degree refers to a state in which the chin guard 2 opens in the vicinity of the user's forehead, and this state is beneficial for the user to perform activities such as communication and temporary rest. The high opening degree refers to a state in which the chin guard 2 is located at or near the dome of the casing body 1, and this state is particularly suitable for the user to drink water, watch or perform other work activities. It should be noted that, in the embodiments of the present disclosure, the chin guard 2 and the branches 2a thereof obviously have an angular speed of rotation with respect to the casing body 1 which is the same as that of the internal gear 4 in the direction of spin and spin speed. However, in this case, the chinrest 2 and the branches 2a of theitself extend or retract with respect to the internal gear 4 during their synchronized rotations with the internal gear 4. It should be noted that the through groove 6 is constituted in the body of the internal gear 4 or in an accessory of the internal gear 4, therefore through slot 6 also rotates synchronously with internal gear 4. In other words, in the embodiments of the present disclosure, chin guard 2 and branches 2a thereof actually rotate synchronously with through slot 6. Additionally, it should be noted that, as described above, in the embodiments of the present disclosure, the branch 2a in the associated mechanism is arranged outside the through slot 6 in the internal gear 4. That is, in the embodiments of the present disclosure, in the outer side of the through slot 6, there is always a branch 2a that rotates synchronously with the through slot 6. This means that, in the embodiments of the present Disclosure, during all the processes of opening or fastening rotation of the chin guard 2, the body of the branch 2a can be better designed to cover the through slot 6 (see Figures 5 and 6). In particular, it should be noted that, in the embodiments of the present disclosure, the chin guard 2 and the body of the branch 2a rotate synchronously with the through slot 6, that is, the branch 2a and the through slot 6 have the same angular velocity with respect to to the casing body 1. Therefore, in the embodiments of the present disclosure, the extension / retraction of the branch 2a with respect to the internal gear 4 is actually carried out along an opening direction of the through slot 6. It should be note that, in embodiments of the present disclosure, branch 2a is disposed outside of through slot 6. In other words, even if branch 2a is designed to have a narrower body structure, through slot 6 is actually can fully cover in a full-time and full-posture form in the embodiments of the present disclosure, which is a significant difference between the technology of e Gear restraint transformable chin rest structure of the embodiments of the present disclosure and existing gear restraint transformable chin rest structure technologies, such as CN105901820A, CN101331994A and WO2009095420A1. To more clearly illustrate theprocess of changing chin guard 2 from the full-shell frame position to the semi-shell frame position In the embodiments of the present disclosure, Figure 5 shows the changes throughout the process: Figure 5 (a) shows a full helmet position state in which the chin guard 2 is located on the full helmet frame; Figure 5 (b) shows a state of the rising position in which the chin guard 2 is in the process of opening; Figure 5 (c) shows a state of forward position in which the chin guard 2 passes through the dome of the carcass body 1 (this state is also an open-face helmet state); Figure 5 (d) shows a state of the dropped position in which the chin guard 2 is retracted towards a rear side of the carcass body 1; and, Figure 5 (e) shows a semi-hull position state in which the chin guard 2 is retracted towards the semi-hull structure. Similarly, to more clearly illustrate the process from returning and recovering the chin guard 2 from the semi-helmet frame position to the full helmet frame position in embodiments of the present disclosure, Figure 6 shows the changes during the whole process: Figure 6 (a) shows a semi-hull position state in which the chin guard 2 is located in the semi-hull structure; Figure 6 (b) shows a rising position state in which the chin rest 2 rises to the rear side of the carcass body 1 during a return process of the chin rest 2; Figure 6 (c) shows a state of the dome advance position in which the chin guard 2 passes through the dome of the carcass body 1; Figure 6 (d) shows a state of the fastening position in which the chin guard 2 is in the last return process; and, Figure 6 (e) shows a full helmet position state in which the chin guard 2 returns to the full helmet structure. It is not difficult to find in Figures 5 and 6 that, in various positions of the structure of the chin guard 2 and during various rotation processes of the chin guard 2, the through slot 6 is completely covered by the narrow body of the branch 2a of chin guard 2 without being exposed. Accordingly, it has been shown that the through slot 6 can be completely covered and not exposed in one way throughout the entire time and throughout the process in the embodiments of the present disclosure. There is no doubt that, in the embodiments of the present disclosure, the internal gear 4 and theexternal gear 4 are rotatable and are meshed with each other to constitute a kinematic torque, the internal gear 4 and branch 2a are adjusted sliding relative to each other to constitute a sliding kinematic torque, and the rotation of the external gear 5 is transferred to branch 2a by the drive member 7 such that the branch 2a extends or retracts relative to the internal gear 4, whereby the position and posture of the chin guard 2 can be precisely changed in conjunction with the process of opening or fastening the chinrest 2, and finally the reliable transformation of chinrest 2 between full-helmet frame position and semi-helmet frame position can be realized. Obviously, in view of the properties of the gear meshing transmission, in the embodiments of the present disclosure, the uniqueness and reversibility of the geometric movement path of the chin guard 2 can be maintained when the position and posture of the chin guard are changed. Chinrest 2. That is, a certain specific position of the chinrest 2 necessarily corresponds to a specific and unique position of the chinrest 2. Furthermore, it does not matter whether the internal gear 4 and the external gear 5 perform positive turns or reverse turns, the posture of chin guard 2 at a particular turning moment must be unique and can be inferred backwards. Furthermore, in the embodiments of the present disclosure, the branch 2a of the chin guard 2 may substantially or even completely cover the through groove 6 in the internal gear 4, such that entry of external foreign matter into the pair of restriction, and the reliability of the helmet when in use is guaranteed; and, the path of external noise entering the interior of the helmet can be blocked, thus improving the comfort of the helmet when in use. Also, since the movement of the external gear 5 is a fixed axis rotation in the embodiments of the present disclosure, that is, the space occupied by the external gear 5 when it is operating is relatively small, a more flexible option is provided for the arrangement of clamping structures on the support base 3 having a relatively low stiffness and strength. For example, the clamping reinforcing ribs and clamping screws or other constructions / structures / parts may be arranged on an outer periphery of the outer gear 5 and on the inner and outer peripheries of the gear.internal 4. These clamping reinforcement measures are not comprehensive enough in existing gear restraint transformable chin structure technologies. Therefore, according to the embodiments of the present disclosure, the supporting rigidity of the supporting base 3 can be improved, therefore, the overall safety of the helmet can be improved. It is worth mentioning that the technical solutions provided by the existing gear restraint transformable chin rest structure technologies, such as CN105901820A, CN101331994A and WO2009095420A1 adopt the structure and mode of operation of moving gears or moving frames oscillating and They rotate with the chin guard 2, so the space swept by these gears or frames is very large, and this structural design has a negative effect on the rigidity and resistance of the helmet. This is another significant difference between the helmet with the gear restraint transformable chin structure of the present disclosure and those of existing technologies.
[0140] In the embodiments of the present disclosure, in the associated mechanism, the kinematic torque constituted by the internal gear 4 and the external gear 5 may belong to a flat gear drive mechanism, characterized in that: the internal gear 4 and the external gear 5 meshed with each other have parallel axes, that is, the inner gear shaft O1 of the inner gear 4 and the outer gear shaft O2 of the outer gear 5 are parallel to each other. It should be noted that, in the embodiments of the present disclosure, particularly, the internal gear shaft O1 around which the internal gear 4 that can rotate is a fixed shaft, and the external gear shaft O2 around which the external gear 5 which can rotate can rotate is also a fixed axis. Therefore, the internal gear 4 having internal tooth properties and the external gear 5 having external tooth properties obviously have the same direction of rotation when meshed with each other (see Figures 28 and 29). Here, the internal gear shaft O1 and the external gear shaft O2 are preferably arranged perpendicular to the plane of symmetry P of the casing body 1. Furthermore, in the associated mechanism, the internal gear 4 and the external gear 5 in embodiments of the present disclosure may be cylindrical gears, including spur gears (as shown in Figures 14, 16, 17-19, 27 and 28) and bevel gears (not shown). Such an arrangement has the advantage that the gear meshing pair constituted by the internal gear 4 and the external gear 5 can be better adapted and adjusted to the appearance design of the helmet in terms of space occupation, due to the fact that the structure of this gear configuration is relatively flat and can easily satisfy the strict requirement of the carcass body 1 regarding thickness, particularly, the thickness in a direction perpendicular to the plane of symmetry P of the carcass body 1. Obviously, the internal gear 4 and the outer gear 5 of the cylindrical gear type have a small size in a direction perpendicular to the plane of symmetry P, and therefore have the advantage of occupying little space. Particularly, in the embodiments of the present disclosure, when the inner gear 4 and the outer gear 5 are meshed with each other, the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 satisfy a ratio: R / r = 2 (see Figures 27-29), in which the pitch radius R of the inner gear 4 is formed on the inner gear 4, the pitch radius r of the outer gear 5 is constituted on the outer gear 5, and the Pitch circle can only be generated when the inner gear 4 and the outer gear 5 are meshed with each other. Obviously, when the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 satisfy the ratio R / r = 2, a rotational speed of the inner gear 4 around the inner gear shaft O1 is only half of the rotational speed of the external gear 5 around the external gear shaft O2, that is, the rotational speed of the external gear 5 is twice the rotational speed of the internal gear 4, that is, an angle of rotation of the gear internal 4 (that is, a central angle rotated with respect to the internal gear axis O1) is only half the angle of rotation of the external gear 5 (that is, a central angle rotated with respect to the external gear axis O2) after that the two gears operate over a period of time in a meshed fashion. When the internal gear 4 and the external gear 5 are arranged in accordance with this mesh restriction relationship in the embodiments of the present disclosure, the helmet obtained will have and must have a rule of regulation and control of the posture of the chin guard 2 having unique behaviors and different advantages (see the following description and evidence). It should be noted that when the inner gear 4 and the outer gear 5 are designed as standard gears, the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 will also be equal to their respective radii of the reference circle. . Here, the inner gear 4 and the outer gear 5 always have a reference circle radius used for design, manufacturing and inspection, but the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 are only It can generate when the internal gear 4 and the external gear 5 are meshed. It should be noted that, when the internal gear 4 or the external gear 5 is provided with an abnormal tooth bushing 8b to mesh with an abnormal gear tooth 8a, the pitch radius of the meshed abnormal gear tooth 8a and the abnormal tooth bushing 8b is preferably designed according to the above rule. For example, in the embodiment of Figures 27 and 28, the pitch radius of the abnormal gear tooth 8a present in the outer gear 5 in the form of a tooth is only half the pitch radius of the abnormal tooth bushing 8b present in the internal gear 4 in the form of a tooth bushing. Particularly, there is a preferred parameter design arrangement in the embodiments of the present disclosure, that is: all effective gear teeth, including abnormal gear teeth and abnormal tooth bushings in internal gear 4, have a radius of uniform pitch R , and all effective gear teeth, including abnormal gear teeth and abnormal tooth bushings in outer gear 5, have a uniform pitch radius r (as shown in Figures 27 and 28), because A simpler structural shape and optimal gear adjustment mode will be achieved when the internal gear 4 and the external gear 5 are designed and arranged according to these parameters. In the embodiments of the present disclosure, when the effective gear teeth of the inner gear 4 and the outer gear 5 are configured according to the principle that the ratio of the pitch radius R of the inner gear 4 to the pitch radius r external gear 5 satisfies the ratio R / r = 2, one of the most important characteristics (see Figures 28 and 29) is that: when the internal gear 4 and the external gear 5 are rotatable and are meshed with each other, the pitch circle of the external gear 5 must pass through internal gear shaft O1 of internal gear 4 (obviously); and, when a point, which coincides with the internal gear axis O1, in the pitch circle of the external gear 5 begins to rotate with the external gear 5, this point must always fall on a certain radius of the synchronously rotating internal gear 4 with the inner gear 4. In other words, if the drive member 7 is arranged in the pitch circle of the outer gear 5, the drive member 7 will always intersect a certain radius of the inner gear 4 rotating synchronously with the gear In this way, the through slot 6 can be designed as a straight line shaped slot and the through slot 6 passes through or is aligned with the internal gear shaft O1, such that the drive member 7 can substantially or even fully reciprocating smoothly in through slot 6 (as shown in Figure 31). Therefore, the through groove 6 can be easily machined and conveniently assembled and cleaned. More importantly, in this way, the body of the branch 2a of the chin guard 2 can more easily cover the through slot 6 such that the through slot 6 is less exposed or not completely exposed to the outside (see Figures 5 and 6). Actually, it is not difficult to show that, the above characteristics must be presented when the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 are formed when the inner gear 4 and the outer gear 5 are meshed with each other. satisfy the relation R / r = 2 (see Figures 28 and 29). 1) It is obvious that when the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 satisfy the ratio R / r = 2, the pitch circle of the outer gear 5 must pass through the gear shaft internal O1. Since the pitch circle of the inner gear 4 must be tangent to the pitch circle of the outer gear 5, a tangent point K must lie in the plane constituted by the inner gear shaft O1 and the outer gear shaft O2 (that is, a point of interest of the internal gear shaft O1, a point of interest of the external gear shaft O2 and the point tangent K must be collinear). 2) It will be shown that, during the meshing movement of the inner gear 4 and the outer gear 5, a certain point M on the pitch circle of the outer gear 5 (point M is always fixed on the outer gear 5 and rotates synchronously with the outer gear 5) will always fall on a certain radius O1N of the inner gear 4 (the radius O1N is always fixed on the inner gear 4 and rotates synchronously with the inner gear 4, that is, an end point N of the radius O1N is always fixed in the pitch circle of the internal gear 4 and rotates synchronously with the internal gear 4), referring to Figures 28 and 29, in which Figure 29 (a) corresponds to Figure 28 (a); Figure 29 (b) corresponds to Figure 28 (b); Figures 28 (a) and 29 (a) show the position state of the internal gear 4 and of the external gear 5 at the beginning of the movement (the initial position status may correspond to the position of the chin guard 2 in the position of the structure of full helmet); and, Figures 28 (b) and 29 (b) show the position status of the inner gear 4 and the outer gear 5 after the gear movement has started and the gear rotation has been performed at a certain angle ( this position state corresponds to any intermediate posture of the chinrest 2 during a rotation process of the chinrest 2). In general, if point M in the initial position shown in Figures 28 (a) and 29 (a) is assumed to be located in a position M1 that coincides with the internal gear axis O1 (this position is also a point of axial interest of the internal gear shaft O1), the radius O1N is located in a position perpendicular to the plane constituted by the internal gear shaft O1 and the external gear shaft O2, the end point N of the radius O1N at this time is located at a position N1 that is perpendicular to O1K, and a current position of the end point N can be indicated by N (N1) in the drawings. It is not difficult to find that a line segment O1N1 is a tangent line of the pitch circle of the outer gear 5, with a tangent point of (M1, O1); and, the axis of revolution O3 of the drive member 7 exactly coincides with the internal gear axis O1. Therefore, the tangent point can also be denoted by (M, M1, O1, O3). After the internal gear 4 and the external gear 5 perform a certain meshing turn, the point M on the external gear 5 is rotated to the position M2, and the point N in internal gear 4 it is rotated correspondingly to position N2. Correspondingly, at this time, the current position of point M can be indicated by M (M2) in the drawings, and the current position of point N can be indicated by N (N2) in the drawings. Since the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 satisfy the ratio R / r = 2, at this time, the center angle of the inner gear 4 rotated through point N satisfies the ratio zN1O1N2 = 3, and the center angle of the outer gear 5 rotated by point M satisfies the relation zM1O2M2 = 2zN1O1N2 = 23. In Figure 29 (b), if point Q is assumed to be an intersection point of radius O1N2 of inner gear 4 and the pitch circle of outer gear 5, a line segment O1Q is a chord in outer gear 5 , and zN1O1Q is a tangent angle of chord in the pitch circle of external gear 5. According to geometric law, the tangent angle of chord zN1O1Q is half a circumferential angle of an included arc of external gear 5, and the The circumferential angle is half the central angle zM1O2Q of the arc of the external gear 5 included by the tangent chord angle zN1O1 Q. Or, in turn, it must be zM1O2Q = 2zN1O1Q = 2zN1O1N2 = 2 £. As described above, when the pitch radius R of the internal gear 4 and the pitch radius r of the outer gear 5 satisfy the relationship R / r = 2, zN1O2N2 = 2 is valid, thus proving that point Q coincides with M2 . In other words, points N2, M2, and M1 must be collinear. Due to the arbitrariness of the assumed angle 3, this means that, together with the meshing movement of the internal gear 4 and the external gear 5, the point M must always fall on the radius O1N that rotates synchronously with the internal gear 4. Just by the arbitrariness of the angle 3, any point of the external gear 5 can be equivalent to the position of the point M2, and must fall on the dynamically rotated radius O1N along with the rotation of the external gear 5. From another perspective, in the embodiments of the present disclosure, if the through groove 6 is designed in the shape of a straight line and designed to be parallel or even coincide with the radius O1N, and the drive member 7 is arranged in the pitch circle of the external gear 5 (corresponding to point M) , then the drive member 7 can basically or even completely perform a smooth linear reciprocating motion in the through groove 6. To be observed more clearly and vividly, Figure 31 shows the process of change of state of the link of the straight groove 6 and the drive member 7 when the ratio of the pitch radius R of the internal gear 4 with with respect to the pitch radius r of the external gear 5 satisfies the relation R / r = 2 (the snap cover 2b is removed in Figure 31), in which Figure 31 (a) shows the full hull position state in that the chin guard 2 is located on the full helmet structure; Figure 31 (b) shows the state of the ascent position in which the chin guard 2 is in the process of opening; Figure 31 (c) shows a state of the dome advance position in which the chin guard 2 passes through the dome of the carcass body 1; Figure 31 (d) shows the state of the fall position in which the chin guard 2 is retracted towards a rear side of the helmet body 1; and, Figure 31 (e) shows the semi-hull position state in which the chin guard 2 is retracted towards the semi-hull structure. It is not difficult to find from the change of state that the through slot 6 always rotates synchronously around the internal gear shaft O1 together with the chin guard 2 and the drive member 7 (at this time, it is equivalent to point M on the external gear 5 in Figure 29) always falls into through slot 6 (at this time, it is equivalent to radius O1N in internal gear 4 in Figure 29) during the turning process. Obviously, if the clasp cover 2b is mounted, an effect equivalent to the effect shown in Figure 5 will be obtained, that is, the body of the branch 2a can completely cover the through slot 6 during the entire rotation process of the chin guard 2 It should be noted that, the gear restraint mechanism has invertibility, so it is not difficult to achieve the effect shown in Figure 6 when the chin guard 2 returns from the semi-hull structure position to the full-hull structure position. . Thus, in embodiments of the present disclosure, the through slot 6 in the internal gear 4 can be designed as a flat straight through slot 6, and is arranged to point to the internal gear shaft O1 of the internal gear 4 (as shown in Figures 4, 13-16, 27, 28, 30 and 31). At this time, the actuating member 7 can always fall into the through slot 6 and smoothly perform a linear reciprocating movement. It should be particularly noted that, in the embodiments of the present disclosure, there is a case where the Inner gear 4 and outer gear 5 may be provided with gear teeth effective within a full 360 degree circumferential range. In this case, when the inner gear 4 and the outer gear 5 are meshed with each other, the pitch radius R of the inner gear 4 and the pitch radius r of the outer gear 5 also satisfy the ratio R / r = 2. In this way, the number of all gear teeth, including abnormal gear teeth 8a and modified gear teeth 8c of outer gear 5, is only half the number of all gear teeth of inner gear 4. By For example, if the number of gear teeth of the inner gear 4 is 28, the number of gear teeth of the corresponding outer gear 5 must be 14. However, it should be noted that in this case there must be redundant gear teeth between the 28 gear teeth of internal gear 4, that is, not all 28 gear teeth of internal gear 4 will participate in meshing with the 14 gear teeth of external gear 5, because it is well known that it is impossible and unnecessary to turn the chin rest 2 of the helmet unidirectionally at 270 degrees relative to the shell body 1. Actually, from a practical point of view, the maximum angle of rotation of the chin guard 2 is preferred. The half-helmet structure of the helmet constituted by the chin guard 2 rotated to this angle has better friendliness and safety, and this arrangement is easily adapted to the modeling of the appearance and particularly conforms to the aerodynamic principle, of such that the resistance to the gas flow is low and the howling of the wind generated when the air flow flows through the outer surface of the helmet can be effectively reduced.
[0142] In embodiments of the present disclosure, in the associated mechanism, the drive member 7 may be designed as a part that includes a surface of revolution structure, wherein the surface of revolution structure includes an axis of revolution O3 that can rotate always around the external gear axis O2 together with the external gear 5. The axis of revolution O3 is arranged to be parallel to the external gear axis O2 and intersects with the pitch circle of the external gear 5 (see Figures 19, 28, 29 , 30 and 31). Here, the structure of the surface of revolution may have various shapes, including various cylindrical surfaces, conical surfaces, spherical surfaces, annular surfaces, abnormal convoluted surfaces, or the like. It should be noted that, the pitch circle of the outer gear 5 is constituted when the gear 5 is meshed with the inner gear 4 (at this time, a pitch circle of the inner gear tangent to the pitch circle of the outer gear is also constituted in the internal gear 4). Obviously, when the outer gear 5 is a standard gear, the pitch circle of the outer gear 5 coincides with the reference circle of the outer gear; and, when the external gear 5 is a non-standard gear, that is, when the external gear 5 is a modified gear having a non-zero coefficient of modification, the pitch circle of the external gear does not coincide with the reference circle of the external gear. Similarly, when the inner gear 4 is a standard gear, the pitch circle of the inner gear 4 coincides with the reference circle of the inner gear 4; and, when the internal gear 4 is a non-standard gear, that is, when the internal gear 4 is a modified gear having a non-zero coefficient of modification, the pitch circle of the internal gear 4 does not coincide with the reference circle of the internal gear 4. In the embodiments of the present disclosure, the drive member 7 is manufactured in a part that includes a surface of revolution structure, a better adjustment mode and a better manufacturability can be realized when the drive member The drive 7 is connected to the external gear 5 and when the drive member 7 is connected to the branch 2a of the chin guard 2. It is well known that the part having a configuration of revolution is easy to machine and assemble and can adopt a mode of conventional shaft-hole fit. Additionally, in embodiments of the present disclosure, the axis of revolution O3 is arranged to intersect the pitch circle of the external gear 5 and be parallel to the external gear axis O2, with an advantage that this arrangement can realize a better spatial arrangement to balance the arrangement of the drive member 7 in the outer gear 5, the inner gear 4 and the through groove 6. Particularly, the drive member 7 can have better stability of movement. As shown above, when the structure of the surface of revolution of the driving member 7 has an axis of revolution O3 and the axis of revolution O3 is arranged in the pitch circle of the external gear 5 and parallel to the external gear axis O2 , the axis of revolution O3 operates by a law that always falls in a certain radius that rotates synchronously with the internal gear 4, in such a way that good conditions are created for the design of the shape and the design of the arrangement of the through groove 6. It should be mentioned that, although the axis of revolution O3 of the drive member 7 is parallel to the external gear axis O2 of the external gear 5 as described above, in the embodiments of the present disclosure, the axis of rotation O3 of the transmission member 7 is absolutely parallel to the external gear axis O2 of the external gear 5, rather, these shafts are allowed to have a non-parallelism error up to ci The third point, that is, the non-parallelism between the axis of revolution O3 and the external gear axis O2 caused by various factors, such as manufacturing error, assembly error, stress strain, temperature strain, and vibration strain are It allows. As long as the final overall effect achieved by the non-parallelism error does not affect the normal rotation of the chin guard 2, the axis of revolution O3 and the external gear axis O2 are considered to be arranged in parallel. Furthermore, in embodiments of the present disclosure, the structure of the surface of revolution of the drive member 7 can be designed as a cylindrical surface (as shown in Figures 4, 17-18, 27, 28, 30 and 31), or it can be designed as a circular conical surface (not shown). In this case, obviously, the driving member 7 has only two ends and only one axis of revolution O3. It is well known that the cylindrical surface and the circular conical surface are conventional multi-part structural shapes, and are convenient to machine and very reliable in fit. It should be noted that the circular conical surface described in embodiments of the present disclosure includes a circular truncated cone. Additionally, if the structure of the surface of revolution of the drive member 7 in the embodiments of the present disclosure is designed as a cylindrical surface, it may be a cylindrical surface having a single diameter, or it may be constituted by stacking a plurality of cylindrical surfaces having different diameters (however, these cylindrical surfaces must be arranged coaxially, that is, the drive member 7 has only one axis of revolution O3). Particularly, in the embodiments of the present disclosure, the structure of the surface of revolution of the actuating member 7 further includes a situation: on the basis of the cylindrical surface or circular conical surface, structures of the surface of revolution in other shapes can be combined, for example, structural details of the auxiliary process such as chamfer, rounded corner and taper that are convenient to manufacture and assemble and avoid stress concentration, provided that all the structural details of the auxiliary process do not damage the structure of the surface of revolution of drive member 7 connected to external gear 5 or branch 2a.
[0144] In embodiments of the present disclosure, the fit and connection between the drive member 7 and the external gear 5 and between the drive member 7 and the branch 2a in the associated mechanism can be accomplished by one of three situations.
[0145] 1) The drive member 7 is clamped or integrated with the external gear 5, and the drive member 7 is in rotary fit with the branch 2a (Figures 4 and 17-19 show an example of the drive member 7 and the gear external 5 being integrated, and the actuating member 7 in this case has an end in rotary fit with a circular hole 2c in the snap cover 2b in Figures 4 and 24-26). Alternatively, 2) the drive member 7 is in rotary fit with the external gear 5, and the drive member 7 is attached or integrated with the branch 2a (not shown). Alternatively, 3) the drive member 7 is in rotary fit with the external gear 5, and the drive member 7 is also in rotary fit with the branch 2a (not shown). Actually, in addition to the above three situations, in the embodiments of the present disclosure, the fit and connection between the drive member 7 and the external gear 5 and between the drive member 7 and the branch 2a can be done by other types of fitting and connection methods. For For example, the drive member 7 may be in rotary fit and slide fit with (ie, rotary slide fit with) the external gear 5 and / or branch 2a (not shown). As a conventional example, the drive member 7 has a cylindrical configuration, and a belt-shaped groove configuration connected to the drive member 7 is arranged in the external gear 5 or branch 2a, such that the drive member 7 it can be in rotary fit with external gear 5 or branch 2a and also in sliding fit with external gear 5 or branch 2a.
[0147] In the embodiments of the present disclosure, to prevent loosening of the internal gear 4 and the external gear 5 during the rotation process of the chin rest 2 and thus ensure the stability and reliability of the chin rest 2 during the posture change process, a first anti-disengagement member 9a capable of preventing axial play of the internal gear 4 can be arranged on the support base 3, the casing body 1 or / and external gear 5, and a second anti-disengagement member 9b capable of preventing the axial play of the external gear 5 can be arranged in the internal gear 4, the support base 3 or / and the casing body 1. Here, the prevention of axial play refers to stopping, blocking, preventing and limiting the displacement Excessive internal gear 4 and external gear 5, to prevent internal gear 4 and external gear 5 from loosening by providing the first anti-disengagement member 9a and the second anti-disengagement member 9b, that is, avoid that the internal gear 4 and the external gear 5 affect the normal rotation process of the chin guard 2 and affect the normal clamping stagnation of the chin guard 2 in the full helmet structure position, the position of semi-hull structure or the open-face structure position. In the embodiments of the present disclosure, the arrangement of the first anti-disengagement member 9a includes various situations, such as the first anti-disengagement member 9a which is arranged in the support base 3, or in the carcass body 1, or in the internal gear 4, or any two or three of the support base 3, the casing body 1 and the internal gear 4. In the In embodiments of the present disclosure, the arrangement of the second anti-disengagement member 9b includes various situations, such as the second anti-disengagement member 9b being arranged on the internal gear 4, or the support base 3, or the carcass body 1, or in any two or three of the internal gear 4, the support base 3 and the casing body 1. In the cases shown in Figures 4 and 10-12, the first anti-disengagement member 9a to prevent axial play of the internal gear 4 is arranged on the outer support plate 3b of the support base 3; while in the embodiments shown in Figures 4 and 13-16, the second anti-disengagement member 9b to prevent axial play of the external gear 5 is arranged in the internal gear 4. Obviously, the arrangement of the first anti-disengagement member 9a and the second anti-disengagement member 9b in the embodiments of the present disclosure is not limited to the cases shown in Figures 4 and 10-16. It should be noted that, in embodiments of the present disclosure, the first anti-disengagement member 9a and the second anti-disengagement member 9b may have a flanged configuration (as shown in Figures 4 and 10-12), a flanged configuration (as shown in Figures 4 and 10-12). clasp (i.e., fastened by a snap hook configuration, not shown), a clamp ring configuration (i.e., fastened by a clamping spring structure, not shown), a set screw configuration (i.e. , fastened by a set screw structure, not shown), a locking pin configuration (i.e., fastened by a locking pin, not shown), a cover plate structure (as shown in Figures 4 and 13-16, the second anti-disengagement member 9b of the cover plate structure in the drawings may be a configuration of the body of the internal gear 4 or a configuration of an extension of the internal gear 4), or even a magnetic attractable member (not shown) or other types of configurations or members. As described above, the first anti-disengagement member 9a may be a part of the configuration of the support base 3 (as shown in Figures 4 and 10-12), or a portion of the configuration of the carcass body. 1 (not shown) or a portion of the external gear configuration 5 (not shown), and the second anti-disengagement member 9b may be a portion of the internal gear configuration 4 (as shown). shown in Figures 4 and 13-16). Additionally, the first anti-disengagement member 9a can be a separate part attached to the support base 3 or the casing body 1 or the external gear 5 (not shown), and the second anti-disengagement member 9b can be a independent part attached to internal gear 4 or support base 3 or casing body 1 (not shown). Similarly, to prevent chin guard 2 from disengaging from carcass body 1, in embodiments of the present disclosure, a third anti-disengagement member 9c capable of preventing axial loosening of branch 2a from chin guard 2 may be provided. on internal gear 4 (as shown in Figures 4, 13, 15 and 31). The third anti-disengagement member 9c can be an integral part of the body (including an extension or elongation of the body) of the internal gear 4 (as shown in Figures 4, 13, 15 and 31), or it can be an independent part attached to internal gear 4 (not shown). Additionally, the third anti-disengagement member 9c can have a flanged configuration (as shown in Figures 4, 13, 15 and 31), or it can have a configuration form such as a clamping groove, a locking screw. clamp, a clamping collar or clamping cover (not shown), or there may be various types of configurations in the prior art. The flanged configuration is preferable therein, because the flanged configuration is easy to manufacture and assemble and, particularly, it may even constitute a portion or all of the sliding kinematic torque between the chin guard 2 and the branch 2a. It should be noted that, in the embodiments of the present disclosure, the flange on the third anti-disengagement member 9c having the flange configuration may have various shapes. For example, in the embodiments shown in Figures 4, 13, 15 and 31, the flange of the third anti-disengagement member 9c having the flange configuration is oriented away from the through slot 6, that is, the flanged configuration is directs out of the through slot 6. Actually, in addition to this, the flange of the third anti-disengagement member 9c having the flange configuration in the embodiments of the present disclosure may be oriented towards the through slot 6 (not shown ). As described above, in embodiments of the present disclosure, the third anti-disengagement member 9c is provides to prevent axial disengagement of branch 2a from chin guard 2 from internal gear 4. Here, "axial disengagement" refers to a situation where branch 2a disengages from internal gear 4 to affect the normal rotation process of the chin guard 2 in the axial direction of the internal gear shaft O1. It should be mentioned that, in the embodiments of the present disclosure, the function of the third anti-disengagement member 9c is to prevent the axial disengagement of the branch 2a of the chin guard 2 from the internal gear 4, without preventing the alternative torque extension / retraction behavior. sliding kinematic constituted by branch 2a and internal gear 4.
[0149] In the embodiments of the present disclosure, to realize a better arrangement of the drive member 7, at least one of the effective gear teeth of the outer gear 5 can be designed as an abnormal gear tooth 8a having a thickness greater than the average thickness. of all the effective gear teeth in the outer gear 5. In other words, from the appearance, the abnormal gear tooth 8a in the outer gear 5 is first of all a gear tooth in an entity shape, that is, the abnormal gear tooth 8a is tooth shaped. Second, the abnormal gear tooth 8a is larger in size than other normal effective gear teeth (as shown in Figures 17 and 19). Of course, it is necessary to form an abnormal tooth bushing 8b in the form of a tooth bushing in the inner gear 4 to mesh with the abnormal gear tooth 8a in the outer gear 5. Obviously, the cavity of the abnormal tooth 8b in the inner gear 4 should correspondingly be wider than other normal gear teeth (as shown in Figures 14 and 16). Here, in the embodiments of the present disclosure, the drive member 7 is engaged only with the abnormal gear tooth 8a in the outer gear 5 (see Figures 27 and 28). The abnormal gear tooth 8a having a relatively large thickness is provided in the outer gear 5 to allow the structure of the surface of revolution of the drive member 7 engaged with the abnormal gear tooth 8a to have a larger diameter, such that the strength and rigidity of the drive member 7 can be better ensured, therefore, the reliability and safety of the helmet can be improved.
[0151] In embodiments of the present disclosure, to allow chin guard 2 to smoothly and reliably complete various posture transformation processes, through slot 6 in internal gear 4 can be designed as a flat straight through slot, i.e., One slot straight through 6, and straight through slot 6 is arranged to point or pass through internal gear shaft O1 (see Figures 15, 16, 27, 28 and 31). Additionally, the sliding kinematic torque constituted by the internal gear 4 and the branch 2a in the sliding fit is designed as a linear sliding kinematic torque, and the linear sliding kinematic torque is arranged to point or pass through the gear axis O1. internal. Furthermore, the straight through slot 6 and the linear sliding kinematic pair are superimposed on each other or parallel to each other. Here, the through slot 6 which is designed as a "flat straight through slot" means that when looking in the axial direction of the internal gear shaft O1, the through slot 6 can be in the shape of a long flat strip and have a slot edge configuration in the form of a straight edge and can be seen through it. Additionally, the "straight through groove 6 which is arranged to point or pass through the internal gear shaft O1" means that, if the body configuration of the through groove 6 projects orthogonally to the plane of symmetry P of the helmet, its projection assembly intersects with a projection point of interest of the internal gear shaft O1; or, if the projection set extends along the line of geometric symmetry of the projection set, the projection set must pass through the projection point of interest of the internal gear axis O1, particularly, the line of symmetry of the The projection assembly passes through the projection point of interest of the internal gear shaft O1 (see Figures 15, 16, 27, 28 and 31). Here, "the sliding kinematic torque constituted by the internal gear 4 and the branch 2a in the sliding fit is designed as a linear sliding kinematic torque" means that the restraining behavior of the kinematic torque has the effect of allowing mutual movement between the internal gear 4 and branch 2a is a linear displacement. Additionally, "the linear sliding kinematic torque is arranged to point or pass through the internal gear shaft O1" means that at least one of the configurations, structures or parts (eg, the body of branch 2a, etc.) ) that form the linear sliding kinematic torque is in a state of pointing or passing through the internal gear shaft O1 (see Figures 5, 6 and 31). Here, "the straight groove 6 and the linear sliding kinematic pair overlap each other or are parallel" means that if the through groove 6 and the sliding kinematic pair are projected orthogonally to the plane of symmetry P of the hull, it can be found that their Projections intersect, particularly, the geometric symmetry line of the projection assembly of the straight through groove 6 and the geometric symmetry line of the projection assembly of the linear sliding kinematic pair are parallel to each other, particularly they overlap each other. In the embodiments of the present disclosure, by coordinating the straight through slot 6 and the linear sliding kinematic torque and arranging that the straight through slot 6 and the linear sliding kinematic torque overlap each other or parallel to each other, they can be achieved at least two advantages. First, the drive member 7 can smoothly reciprocate in the through slot 6 without interference. Second, conditions can be provided for the branch 2a to completely cover the through slot 6. As previously described, at this time, the movement path of the actuating member 7 is linear and reciprocating, and the linear path can always follow the straight groove 6 formed in the internal gear 4 in the radial direction. Therefore, there is no doubt that the drive member 7 can easily perform any movement interference with the through slot 6 (see Figure 31). On the one hand, it should be noted that, the branch 2a of the chin guard 2 has the same angular velocity and the same direction of rotation as the internal gear 4 (that is, the through groove 6). At this time, the through slot 6 can actually be designed as a narrow flat straight slot, which creates the conditions for the body of the branch 2a arranged on the outer side and having a narrow structure to completely cover the through slot 6 in one form at all times and throughout the entire process. In other words, the groove through 6 can be covered in one way all the time and during the whole process even if the body of the branch 2a of the chin guard 2 is narrow, because the body of the branch 2a of the chin guard 2 can be pressed well against the outer surface of the through groove 6 in the internal gear 4 as long as the chin guard 2 is located in the full helmet frame position, the half shell frame position or any intermediate position during a chin guard 2 rotation process.
[0153] In the embodiments of the present disclosure, increasing the degree of rotation of the chin rest 2 in order to adapt and conform to a superior appearance and aerodynamic requirements, such an arrangement can be provided: when the chin rest 2 is in the position of complete hull structure, the axis of revolution O3 of the drive member 7 in at least one associated mechanism overlaps with the internal gear axis O1 (see Figures 5, 6 and 31), and the linear restraining elements included in the pair The sliding kinematics in this associated mechanism are perpendicular to the plane constituted by the internal gear shaft O1 and the external gear shaft O2 (see Figure 31), in which the described "linear constraint elements" are valid on the basis that the structures or members in the internal gear 4 and branch 2a that actually participate in the restraining behavior belong to the linear sliding kinematic pair, that is, "linear constraint elements" include structures and parts of a linear configuration. These structures and members include, but are not limited to, grooves, rails, bars, sides, keys, shafts, holes, sleeves, columns, screws, or the like. In the case shown in Figure 4, a linear sliding kinematic pair is provided consisting of first straight side slide rails A and second straight side slide rails B, and when the chin guard 2 is in the full hull frame position , the linear restraining elements (that is, the second slide rails B and the first slide rails A) in the slideable kinematic pair are perpendicular to the plane constituted by the internal gear axis O1 and the external gear axis O2. Figure 31 (a) shows that the position and posture of the linear sliding kinematic torque in the frame position Full hulls are arranged to be perpendicular to the plane constituted by the internal gear shaft O1 and the external gear shaft O2. Such an arrangement is not only advantageous for the appearance design of the helmet, but also allows the body of the branch 2a to better cover the through groove 6 in the internal gear 4 (see Figures 5 and 6). To more clearly observe the process of influence of the linear sliding rail type sliding kinematic torque on the turning behavior of the chin guard 2, Figure 31 shows the state relationship between the branch 2a with the clasp cover 2b removed, the through slot 6 and actuating member 7: in which Figure 31 (a) shows that the chin guard 2 is located in the full hull structure position, the second slide rails B and the first slide rails A in the linear sliding kinematic torque are perpendicular to the plane constituted by the internal gear axis O1 and the external gear axis O2, the axis of revolution O3 of the drive member 7 coincides with the internal gear axis O1, and the drive member 7 is located at the innermost end of the through slot 6 (the innermost end is a limit point of movement of the actuating member 7 with respect to the through slot 6); Figure 31 (b) shows that the chin guard 2 is in a state of position in which it opens and begins to rise, both the second slide rails B and the first slide rails A in the linear slide kinematic pair rotate synchronously around of the gear of the inner shaft O1 together with the inner gear 4, and the drive member 7 slides into a certain intermediate portion of the through slot 6; Figure 31 (c) shows that the chin guard 2 is located at or near the dome of the carcass body 1 (that is, in an open-face structure position state), Both the second B and first slide rails Slide rails A in the linear slidable kinematic pair continuously rotate synchronously around the gear of the inner shaft O1 together with the inner gear 4, and the drive member 7 slides towards the outermost end of the through slot 6 (the outermost end it is another limit point of movement of the actuating member 7 with respect to the through slot 6); Figure 31 (d) shows that the chin guard 2 is in a state of position in the falling towards the rear side of the casing body 1, both the second slide rails B and the first slide rails A in the linear slide kinematic torque still continuously rotate synchronously around the gear of the inner shaft O1 together with the inner gear 4, and the drive member 7 slides back into a certain intermediate portion of the through slot 6; and, Figure 31 (e) shows that the chin guard 2 is in a state in which it falls towards the rear side of the carcass body 1, that is, reaching the position of the semi-helmet structure (it should be noted that, in this state, the second sliding rails B and the first sliding rails A in the linear sliding kinematic torque may or may not be perpendicular to the plane constituted by the internal gear axis O1 and the external gear axis O2; when the second rails of sliding B and the first sliding rails A in the linear sliding kinematic pair are perpendicular to the plane constituted by the internal gear axis O1 and the external gear axis O2, the axis of revolution O3 of the drive member 7 coincides again with the internal gear shaft O1, and the drive member 7 returns to the innermost end of the through slot 6; and, the chin guard 2 is rotated only 180 degrees with respect to the casing body 1 when l chinrest 2 is rotated from the full helmet frame position to the semi-helmet frame position). It is not difficult to find that such a design in the embodiments of the present disclosure has at least two meanings and the following benefits derived therefrom. First of all, the extension / retraction displacement of the chin rest 2 relative to the carcass body 1 can be maximized, that is, the maximum travel distance of the chin rest 2 can be obtained, so that it is advantageous to improve the ability to crossing of the chin guard 2, such as climbing and crossing the dome of the carcass body 1 or crossing other fixings of the helmet or the like. Second, the degree of rotation of the chin guard 2 relative to the shell body 1 can be maximized, therefore, a more attractive appearance and better aerodynamic performance of the helmet can be obtained, since the axis of revolution O3 Matches internal gear shaft O1 in full-hull frame position. With such an arrangement, in reality, the internal gear shaft O1 of the Inner gear 4 can be raised closer to the dome of the carcass body 1 as much as possible, and the space occupation of the inner gear 4 in the under-ear portion can be obviously reduced. This space occupation is very important for the appearance and comfort of wearing the helmet.
[0155] In embodiments of the present disclosure, to ensure that the chin guard 2 can be transformed efficiently position structure complete hull to the position structure half-shell, a central angle covered by all the teeth of effective gears in the gear internal 4 can be greater than or equal to 180 degrees (see Figure 27). The main purpose of such a design is to ensure that the chin guard 2 has a large enough rotation range to satisfy the transformation requirement between the full-hull structure and the semi-hull structure. In this way, the chin guard 2 can reach a maximum rotation angle of at least 180 degrees, and the helmet with a semi-helmet structure corresponding to the position of the chin guard 2 at this time obviously has a more attractive appearance and better performance. aerodynamic. Additionally, in embodiments of the present disclosure, the central angle a may be less than 360 degrees, that is, the internal gear 4 does not have fully disposed gear teeth on a circumference of the internal gear 4. The advantage of this arrangement is that the internal gear 4 can have more space for the arrangement of other functional members, such as the clamping mechanism, locking mechanisms or rebound mechanisms. For example, in the embodiment shown in Figure 32, a clamping mechanism is provided for clamping the chin guard 2 in a particular position, which is just disposed within a surrounding area of the internal gear 4 having gear teeth not fully arranged in a circumference of the internal gear 4. of course, even if the central angle covered by all the teeth of effective gears in the internal gear 4 is equal to 360 degrees, that is, the internal gear 4 has teeth disposed entirely gears in a circumference of the internal gear 4, it is also possible to arrange a clamping mechanism to clamp the chin guard 2 in a position in particular, a locking mechanism and a rebound mechanism (not shown). Since both the internal gear 4 and the external gear 5 in the embodiments of the present disclosure can rotate about fixed axes, the space occupied by the internal gear 4 and the external gear 5 is not large, such that the functional mechanisms Related can be arranged in areas on the inner side of the inner gear 4 and the outer side of the outer gear 5.
[0157] In the embodiments of the present disclosure, to allow the chin guard 2 to have some stability in the full-shell frame position, the half-shell frame position, or even the open-face frame position, that is, to allow the chin guard 2 is temporarily locked, locked or stopped as required in the above position state, a first clamping structure 10a may be arranged on the support base 3 or / and the carcass body 1, at least one second frame may be arranged clamp 10b on the body of the internal gear 4 or an extension of the internal gear 4, and an actuation spring capable of pressing and actuating the first clamping structure 10a can be placed near the second clamping structure 10b arranged on the base of bracket 3 or / and casing body 1 (as shown in Figure 32). The first clamping structure 10a and the second clamping structure 10b are male and female clamping structures coupled to each other. When the first clamping structure 10a and the second clamping structure 10b are clamped together, they can produce the effect of clamping and holding the chin rest 2 in the current position and posture of the chin rest 2. At this time, a force of Action to hold a posture of the chin guard 2 comes primarily from a pressure force applied by the action spring 11 and a frictional force generated during clamp adjustment (the "posture" described in embodiments of the present disclosure refers to a combination of position and posture, and can be used to describe the position status and angle of the chin rest 2). Here, it is obvious that the second clamping structure 10b can rotate synchronously with the internal gear 4. When the second clamping structure 10b is adjusted by clamp with the first clamping structure 10a, An effect of weakly locking the chin rest 2 can be achieved. That is, without forced intervention, the chin rest 2 can generally remain in the posture when it is loosely locked. At this time, the chin rest 2 is held in the current position mainly by the actuation force of the actuation spring 11 (of course, including the friction force to prevent the chin rest 2 from rocking). However, when the applied external force reaches a certain degree, the chin guard 2 can overcome the restriction of the above clamping structures and continuously force a rotary movement (at this time, the actuation spring 11 is withdrawn to perform unlocking). To simplify the structure, in embodiments of the present disclosure, the first clamping structure 10a can be designed as a convex tooth configuration, and the second clamping structure 10b can be designed as a groove configuration (as shown in Figure 32 ). Additionally, the second support structure 10b may be arranged such that a second support structure 10b is clamped with the first support structure 10a when the chin guard 2 is in the full helmet frame position (as shown). shown in Figure 32 (a)) and another second clamping structure 10b is clamped with the first clamping structure 10a when the chin guard 2 is in the semi-helmet frame position (as shown in Figure 32 ( c)). In this way, the chin guard 2 can be effectively locked in the full-helmet frame position and in the semi-helmet frame position, such that the stability of the chin guard 2 (particularly the stability of the helmet when the user drives vehicles, operates machines and tools or performs other operations) can be improved. It should be particularly noted that, in embodiments of the present disclosure, the second clamping structure 10b may be a tooth bushing of an effective gear tooth of the internal gear 4, that is, a tooth bushing of an effective gear tooth of the internal gear 4 can be used directly as the second clamping structure 10b, or the second clamping structure 10b can be an integral portion of an effective gear tooth of the internal gear 4. In Figure 32, when the chin guard 2 is in the full-hull structure position and in the semi-hull structure position, the second clamping structure 10b in clamp fit with the first clamping structure 10a is a tooth bushing of an effective gear tooth of the internal gear 4. Likewise, in embodiments of the present disclosure, it is also possible to configure a second clamping structure 10b to clamp-fit the first clamping structure 10a when the chin guard 2 is located at or near the dome of the carcass body 1. (as shown in Figure 32 (b)). This arrangement is to further provide an intermediate frame posture between the full-hull frame and the half-hull frame. Corresponding to this frame posture, the chin guard 2 opens towards the helmet dome or near the helmet dome. This frame pose is also a state in frequent use today, that is, a state in which the chin guard 2 is rotated to reveal the face (as shown in Figure 32 (b)). This state is advantageous for the driver to temporarily open the chin guard 2 of the helmet for various activities such as smoking, talking, drinking water or resting. In embodiments of the present disclosure, the position of the chin guard 2 located at or near the dome of the carcass body 1 is referred to as the open-face frame position. In other words, in embodiments of the present disclosure, the helmet with a transformable chin guard structure may have at least three frame states, that is, a helmet with a full helmet frame, a helmet with a semi-helmet frame, and a helmet with an open-face structure, so that the comfort of the helmet can be further improved when in use. Furthermore, to further improve the comfort of the helmet when in use, in the embodiments of the present disclosure, a reinforcing spring (not shown) may be provided on the support base 3 or / and the shell body 1. When chin guard 2 is located in the full helmet frame position, the reinforcement spring is compressed and stores energy; when the chin guard 2 is flipped from the full helmet frame position to the open face frame position, the reinforcing spring releases an elastic force to help open the chin guard 2; and, when the chin guard 2 is in a state between the semi-helmet frame position and the frame position open-faced, the reinforcement spring does not act on the chin guard 2, so that the rotational action of the chin guard 2 during this process is not affected.
[0159] In embodiments of the present disclosure, the following design and arrangement may be provided. In the mesh restriction pair constituted by the internal gear 4 and the external gear 5 in at least one associated mechanism, in addition to the normal gear mesh, In the process of meshing between the internal gear 4 and the external gear 5 behaviors can occur single or multiple gearless meshing. That is, the meshing of some gearless members that have transitional properties, such as column / groove gear or key / groove gear, are allowed to be provided in certain gaps, segments, or processes of the normal internal gear 4 gear. with external gear 5 (not shown). In the embodiments of the present disclosure, all the structures and elements (including the convex configurations and the concave structures) that are arranged in the internal gear 4 or / and the external gear 5 and that actually participate in the meshing behaviors for the transfer. of movement and power transfer between the internal gear 4 and the external gear 5, for example, normally configured effective gear teeth (including abnormal gear teeth 8a having a large shape, abnormal tooth bushings 8b having a width of Larger tooth bushing and some modified gear teeth 8c have a small shape, see Fig. 30) and mesh members without auxiliary gears or the like are collectively called mesh elements. It should be noted that, the meshing of these gearless members is merely auxiliary, and the main mechanisms for guiding and restraining the chinrest 2 to perform an extension / retraction movement and changing an angular oscillation phase of the chinrest 2 are still mainly based on the conventional gear type gear tooth for gear restriction. Therefore, the properties and behaviors of the gear-constrained transformable chin guard structure in the embodiments of the present disclosure are not substantially altered. In this case, assuming that the number of gear elements of internal gear 4 is calculated according to a full circumference of 360 degrees and is indicated as the number of teeth equivalent of full circumference of internal gear ZR and the number of mesh elements of outer gear 5 is calculated (or converted ) according to a complete circumference of 360 degrees and is indicated as the number of teeth equivalent of the total circumference of the external gear Zr, a ratio of the number of teeth equivalent to the complete circumference of the internal gear ZR with respect to the number of equivalent teeth of full circumference of the external gear Zr satisfies a relationship: ZR / Zr = 2, with reference to Figure 30. Figure 30 (a) shows that the mesh elements of the internal gear 4 that actually participate in the mesh are not arranged circumferentially at 360 degrees, and Figure 30 (b) shows that the number of full circumference equivalent teeth of the gear int erno ZR of internal gear 4 is calculated (or converted) according to a complete 360 degree circumference. In Figure 30 (b), the inner gear 4 may be indicated by an inner gear 4 (ZR) and the outer gear 5 may be denoted by an outer gear 5 (Zr), indicating that they are equivalently converted gears. For example, if the total number of all the meshing elements of the external gear 5 actually participating in the meshing is assumed to be 14 and the 14 gear elements are exactly distributed around a complete circumference in 360 degrees, the number of teeth full circumference equivalents of the outer gear Zr is 14. In this case, correspondingly, in theory, only 14 engagement elements of the inner gear 4 are required to perform one-to-one pairing with the engagement elements of the outer gear 5. However Obviously, the internal gear 4 having only 14 meshing elements cannot be fully circumferentially distributed at 360 degrees. In the embodiments of the present disclosure, if the mesh elements of the internal gear 4 are configured in accordance with the principle that the ratio of the number of full-circumference equivalent teeth of the internal gear ZR to the number of full-circumference equivalent teeth of the external gear Zr satisfies the ratio ZR / Zr = 2, the number of full circumference equivalent teeth of the inner gear Zr will be 28. Therefore, the relative position and the space occupation of the inner gear 4 and the outer gear 4 in the casing body 1 can be arranged according to the parameters that the number of full circumference equivalent teeth of the external gear Zr is 14 and the number of teeth equivalent to the full circumference of the internal gear Zr is 28. It should be noted that, in practical applications, in the embodiments of the present disclosure, it is not necessary that the number of meshing elements of the gear internal 4 is set according to the number of full circumference equivalent teeth of internal gear ZR, provided that the number of internal gear 4 engagement elements actually participating in the engagement is not less than the number of gear engagement elements external actually involved in the gear. In the embodiments of the present disclosure, the purpose of such an arrangement is to keep the rotational speed of the inner gear 4 always at half the rotational speed of the outer gear, to ensure that the sliding kinematic torque and the through groove 6 have simple configurations, for example a linear configuration or the like.
[0161] In embodiments of the present disclosure, the following design and arrangement may be provided. A web plate 5a is arranged on the external gear 5 in at least one associated mechanism (as shown in Figures 4 and 17-20). The core plate 5a may be arranged on a face of the toothed end of the external gear 5 or at any intermediate position of the external gear 5 in a thickness direction of the external gear 5, in which it is more preferable that the core plate 5a is arranged in a tooth bushing position on the end face of the tooth. Additionally, the web plate 5a can be arranged on all the gear teeth or on some gear teeth of the outer gear 5, where it is preferable that the web plate 5a is arranged on all the gear teeth. Furthermore, the web plate 5a can be integrated with the external gear 5 (as shown in Figures 4 and 17-19), or it can be a separate member attached to the external gear 5 (not shown). In the realizations Of the present disclosure, by arranging the web plate 5a on the outer gear 5, the rigidity of the outer gear 5 can be improved and the drive member 7 may be arranged on the web plate 5a.
[0163] In embodiments of the present disclosure, the following design and arrangement may be provided. In at least one associated mechanism, the through slot 6 constituted in the internal gear 4 participates in the slidable restraint behavior of the internal gear 4 and the branch 2a, and the slidable restraint behavior constitutes a part or all of the slidable kinematic pair constituted by internal gear 4 and branch 2a. In the embodiments of the present disclosure, with such a design, the design of the helmet (particularly the structural design of the sliding kinematic torque constituted by the branch 2a of the chin guard 2 and the internal gear 4) can be simplified by fully utilizing the features structural elements of the through slot 6. In other words, the two sides of the through slot 6 rails can also be used as first slide rails A of the slideable kinematic pair (as shown in Figures 4 and 13-16), and as long as the second slide rails B coincide with the first slide rails A are correspondingly arranged in branch 2a (as shown in Figures 4, 24 and 25), the first slide rails A can be coupled with the second slide rails B to constitute the sliding kinematic torque (see Figure 26), whereby the relative sliding movement of the gear internal gear 4 and branch 2a can be restrained and realized, and the turning moment between internal gear 4 and branch 2a can be transferred (that is, the rotational movement of branch 2a can be transferred through through slot 6 to drive internal gear 4 to rotate synchronously together with branch 2a, or in turn, the rotational movement of internal gear 4 can be transferred through through slot 6 to drive branch 2a to rotate synchronously together with internal gear 4 ). It should be noted that, in the embodiments of the present disclosure, the description "in at least one associated mechanism, the through slot 6 constituted in the internal gear 4 participates in the sliding restraint behavior of internal gear 4 and branch 2a, and the sliding restraint behavior constitutes a part or all of the behaviors of the sliding kinematic torque constituted by internal gear 4 and branch 2a "includes two situations : 1) in at least one associated mechanism, through slot 6 and branch 2a form a single slidable kinematic pair between internal gear 4 and branch 2a; and 2) in at least one associated mechanism, through slot 6 and the Branch 2a form a portion of the sliding kinematic pair constituted by internal gear 4 and branch 2a. In other words, in addition to the sliding kinematic pair constituted by through groove 6 and branch 2a, there are other types of sliding kinematic pairs between the gear. internal 4 and branch 2a, and all sliding kinematic pairs participate in limiting the behavior extension / retraction and rotation between internal gear 4 and branch 2a. Obviously, in the embodiments of the present disclosure, with the above arrangement, space can be saved and a compact design can be realized; and, the structural reliability of the sliding kinematic torque can be improved and the safety of the helmet can be further improved.
[0165] In embodiments of the present disclosure, the following design and arrangement may be provided. The helmet can be configured with a visor 12. The visor 12 is made of a transparent material and works to prevent sand and rain from entering the helmet. The visor 12 includes two legs 13 (see Figures 33 and 34). The two legs 13 are arranged on two sides of the carcass body 1, respectively, and can oscillate about an axis of the visor O4 with respect to the carcass body 1. That is, the visor 12 can be fastened to avoid the wind, sand and rain, and the visor 12 can also be opened to facilitate user activities such as drinking water and talking. A load bearing rail side 14 is arranged on at least one of the two legs 13 of the visor 12 (as shown in Figures 33-36), and the leg 13 with the load bearing rail side 14 is arranged between the support base 3 and the housing body 1. A through opening 15 is formed in the inner support plate 3a of the support base 3 facing the housing body 1 (as shown in Figures 4 and 7-9), and a trigger pin 16 which extends out of the opening 15 and which can come into contact with the load bearing rail side 14 of the leg 13 is disposed on the external gear 5 (as shown in Figures 4, 17, 18, 20 and 33-36). When the visor 12 is in a fully fastened and closed state, the arrangement of the trigger pin 16 and the load bearing rail side 14 satisfies several conditions: if the chin guard 2 is opened from the full helmet frame position, the trigger pin 16 must be able to contact the load bearing rail side 14 on leg 13 of visor 12 and thereby cause visor 12 to rotate and open; and, if the chin guard 2 returns to the full-shell frame position from the half-shell frame position, during the first two-thirds of the return travel of the chin guard 2, the trigger pin 16 must be able to come into contact with the load bearing rail side 14 on the leg 13 of the visor 12 and thereby causing the visor 12 to rotate and open. Here in the description "if the chin guard 2 is opened from the full helmet frame position, the trigger pin 16 must be able to come into contact with the load bearing rail side 14 at the leg 13 of the visor 12 and , therefore, to make the visor 12 rotate ", it is not necessary for the trigger pin 16 to immediately contact the load bearing rail side 14 of the leg 13 to cause the visor 12 to immediately open one time chin guard 2 is activated and chin guard 2 is allowed to activate after a certain delay, including delay due to functional design, delay caused by elastic deformation of related parts, gap removal or other reasons, or the like . Of course, in the embodiments of the present disclosure, there is a case where the trigger pin 16 immediately contacts the load bearing rail side 14 of the leg 13 to actuate the visor 12 to immediately open. once chin guard 2 is activated Figure 33 shows the process of connecting internal gear 4, outer gear 5, trigger pin 16, visor 12 and legs 13 of visor 12 when chin guard 2 is opened from the full helmet frame position to the semi-helmet frame position (here, chinrest 2 performs an initial rotating action), in which Figure 33 (a) shows that chinrest 2 is located in the full helmet frame position to be rotated and the visor 12 is in the fully fastened state; Figure 33 (b) shows that chin guard 2 begins to rotate as internal gear 4 rotates ^ external gear 5 is driven to rotate by internal gear 4 ^ trigger pin 16 rotates synchronously with external gear 5 ^ pin of trigger 16 comes into contact and actuates the load bearing rail side 14 on leg 13 ^ leg 13 begins to oscillate around the axis O4 of the visor ^ visor 12 begins to open and ascend; Figure 33 (c) shows that the chin guard 2 rotates continuously towards the proximity of the dome of the casing body 1 ^ the internal gear 4 rotates and continuously drives the trigger pin 16 so that it is continuously rotated by the external gear 5 ^ the pin trigger 16 pushes the load bearing rail side 14 and continuously actuates the visor 12 to swing up and ascend to the highest elevation position of the visor 12 by the load bearing rail side 14; Figure 33 (d) shows that the chin guard 2 rotates continuously towards the rear side of the casing body 1 ^ the internal gear 4 rotates and continuously drives the trigger pin 16 to rotate continuously by the external gear 5, but at this time , the visor 12 has already reached and remained in the highest elevation position and the trigger pin 16 has already moved away from the load bearing rail side 14 of the leg 13; and, Figure 33 (e) shows that the chin guard 2 already reaches the semi-hull structure position, and the trigger pin 16 moves further away from the load bearing rail side 14 of the leg 13 under actuation of the internal gear 4 and external gear 5. Figure 34 shows the process of connecting the internal gear 4, the external gear 5, the trigger pin 16, the visor 12 and the legs 13 of the visor 12 during the process of returning the visor 12 from the semi-helmet frame position to the full helmet frame position, in which Figure 34 (a) shows that the chin guard 2 is located in the semi-helmet frame position to be rotated and the visor 12 is in the fully fastened state; Figure 34 (b) shows that the chin guard 2 begins to return and rotates the internal gear 4 rotates ^ the external gear 5 is driven to rotate by the internal gear 4 ^ the trigger pin 16 rotates synchronously with the external gear 5 ^ in this moment, the trigger pin 16 does not come into contact with the load bearing rail side 14 on the actuating leg 13, such that the visor 12 is still in the fully fastened state; Figure 34 (c) shows that the chin guard 2 returns and rotates continuously towards the vicinity of the dome of the casing body 1 ^ the trigger pin 16 already rotates to contact the load bearing rail side 14 below the drive of internal gear 4 and external gear 5 ^ drive leg 13 begins to act under actuation of trigger pin 16 ^ visor 12 oscillates around the axis of visor O4 and moves away from the fully fastened position ^ visor 12 ascends and the return trip of chin guard 2 during this time does not reach two-thirds of the full return trip; Figure 34 (d) shows that chin rest 2 continuously returns ^ internal gear 4 rotates and continuously actuates trigger pin 16 to continuously rotate by external gear 5 ^ trigger pin 16 pushes load bearing rail side 14 and continuously actuates the visor 12 to swing up to the highest elevation position of the visor 12 by the load bearing rail side 14; and, Figure 34 (e) shows that the chin guard 2 already returns to the full helmet structure position, and the internal gear 4 rotates and continuously actuates the trigger pin 16 so that it rotates continuously by the external gear 5, but the Visor 12 has already reached and remained in the highest lift position and trigger pin 16 has already moved away from the load bearing rail side 14 of leg 13. It should be noted that, in embodiments of the present disclosure, for each of the two legs 13, the corresponding function can be performed by providing only one side of the load bearing rail 14. Therefore, compared to CN107432520A, in the embodiments of the present disclosure, the design of the mechanism to operate the visor 12 can be greatly simplified, and the leg 13 can be simplified in design and have a more reasonable structure, which can be obviously seen in the embodiments shown in Figures 33-36 (can see from the drawings that the legs 13 are significantly improved in terms of thickness and structural arrangement in a load bearing direction, and the stiffness and strength of the legs 13 are also significantly improved). On the other hand, the trigger pin 16 to actuating the leg 13 has a more reasonable arrangement. First, the path of movement of the firing pin 16 can be limited in a smaller range, thus facilitating the compact design. Second, a load bearing point at which the trigger pin 16 contacts and actuates the load bearing rail side 14 of the leg 13 is further from the visor axis O4 of the visor 12 and closer to a force application point of the visor locking mechanism 12. Therefore, the actuation force between the trigger pin 16 and the load bearing rail side 14 can be obviously reduced. It is undoubtedly beneficial for improving the reliability of the trigger pin 16 and the load bearing rail side 14. In the embodiments of the present disclosure, with the above design and arrangement, during the chin rest rotation process 2, the chin guard 2 can be effectively prevented from getting stuck by the visor 12 or the chin guard 2 from being hit by the visor 12, such that the safety and reliability of the helmet when in use is improved.
[0167] In embodiments of the present disclosure, the following design and arrangement may be provided. The first toothed locking teeth 17 are arranged on the legs 13 of the visor 12, the second locking teeth 18 corresponding to the first locking teeth 17 are arranged on the support base 3 or / and the carcass body 1, and A locking spring 19 is arranged on the support base 3 or / and the casing body 1 (as shown in Figures 35 and 36). The first locking teeth 17 move synchronously with the visor 12, and the second locking teeth 18 can move or oscillate with respect to the housing body 1. When the visor 12 is fastened, the second locking teeth 18 can move close to the first locking teeth 17 under the action of the locking spring 19, such that the visor 12 is loosely locked (see Figures 35 (a) and 36 (a)). When the visor 12 is opened by an external force, the first locking teeth 17 can actuate and force the second locking teeth 18 to compress the locking spring 19, and the second locking teeth 18 produce a displacement to evade and unlock the first locking teeth 17 (see Figures 35 (b) and 36 (b)). Figure 35 illustrates the process of moving the chin guard 2 from the full helmet frame position to the semi-helmet frame position to unlock the visor 12 which is initially in the fully fastened position, and Figure 36 illustrates the process returning the chin guard 2 from the semi-helmet frame position to the full helmet frame position to unlock the visor 12 which is initially in the fully fastened position. Here, it should be noted that, in embodiments of the present disclosure, the locking structures of the first locking teeth 17 and the second locking teeth 18 can be locked in a single pair, or they can be locked in two or more pairs. In embodiments of the present disclosure, the "unlocking" described herein means that the second locking teeth 18 prevent the rotation of the first locking teeth 17 under the actuation pressure generated by the rotation of the first locking teeth 17, particularly in the case of unlocking the visor 12 in the fully fastened position. In Figure 35, Figure 35 (a) shows that the chin guard 2 is located in the full helmet frame position and the second locking teeth 18 are locked with the first locking teeth 17 on the legs 13 of the visor 12 , such that the visor 12 is locked in a fully fastened state in which the user can protect himself from outside dust, rain or the like; Figure 35 (b) shows that chin rest 2 begins to rotate from the full helmet frame position and has opened slightly ^ chin rest 2 drives internal gear 4 at this time ^ internal gear 4 drives outer gear 5 ^ outer gear 5 drives trigger bolt 16 ^ trigger pin 16 drives load bearing rail side 14 on leg 13 ^ leg 3 swings around visor shaft O4 ^ first locking teeth 17 rotate and they compress the second locking teeth 18 for unlocking ^ the second locking teeth 18 are unlocked such that the visor 12 begins to move away from the fully fastened position and is in a slightly open state. This state is advantageous for ventilation and vapor dissipation in the helmet by using fresh external air. It should be noted that, Figure 35 (b) shows that the second locking teeth 18 have unlocked the first locking teeth 17 for the first time (that is, the visor 12 is actuated away from the fully fastened position) and performs a second unlocking (that is, the visor 12 is allowed to remain in the slightly open state). Figures 35 (c) and Figure 35 (d) show that the chin guard 2 is continuously moved to the semi-helmet structure position and the visor 12 is actuated to a greater degree of opening by the trigger pin 16, but the first locking teeth 17 are completely separated from the second locking teeth 18 at this time. In Figure 36, Figure 36 (a) shows that the chin guard 2 is located in the semi-helmet structure position and the second locking teeth 18 are locked with the first locking teeth 17 on the legs 13, in such a way so that the visor 12 is locked in a fully fastened state in which the user can protect himself from outside dust, rain or the like; Figure 36 (b) shows that the chin rest 2 begins to return and rotate from the semi-hull structure position, and during the first two-thirds of the return trip of the chin rest 2, the trigger pin 16 comes into contact with visor 12 and causes visor 12 to swing about a fixed axis ^ first locking teeth 17 rotate and compress second locking teeth 18 for unlocking ^ second locking teeth 18 unlock so that visor 12 begins to move away from the fully fastened position and is in a slightly open state; and, Figures 36 (c) and 36 (d) show that the chin guard 2 continuously returns to the full helmet structure position and the visor 12 is actuated to a greater degree of opening by the trigger pin 16, but the former locking teeth 17 are completely separated from the second locking teeth 18 at this time. Here, in embodiments of the present disclosure, weak locking means that the visor 12 can remain in the locked position (ie, in the fastened state) if the visor 12 is not intentionally actuated; and, when the helmet user forcibly pulls the visor 12 with his hands or forcibly operates the chin guard 2 such that the trigger pin 16 of the external gear 5 forcibly operates the side of the support rail of the helmet. load 14 on the leg 13 of the visor 12, the visor 12 can still be unlocked and opened.
[0168] Compared to existing technologies, the embodiments of the present disclosure have the following notable advantages. By using the arrangement mode of forming an associated mechanism by the chin guard 2, the internal gear 4, the external gear 5 and the drive member 7, the internal gear 4 and the external gear 5 can rotate and mesh with each other to form a kinematic torque, and a restraint torque in sliding fit with the branch 2a of the chin guard 2 is constituted in the internal gear 4, such that the branch 2a, the internal gear 4 and the external gear 5 can be driven together to rotate ; meanwhile, branch 2a is driven to produce a reciprocating movement with respect to internal gear 4 by drive member 7 connected to external gear 5 and branch 2a of chin guard 2, such that the position and posture of the chin guard 2 can be precisely changed in conjunction with the action of opening or closing chin guard 2. Therefore, the transformation of chin guard 2 between full helmet frame position and semi-helmet frame position is performed, and maintain the uniqueness and reversibility of the geometric movement path of the chin guard 2. In accordance with the embodiments of the present disclosure, based on the mode of arrangement and the mode of operation of the associated mechanism, during the posture transformation process of the chin guard 2, the body of the branch 2a of the chin guard 2 can be rotated synchronously with the internal gear 4, to cover basic or even co Fully the through groove 6 in the internal gear 4. Therefore, external foreign matter can be prevented from entering the restraining torque, and the reliability of the helmet when in use is guaranteed. What's more, the path of external noise entering the inside of the helmet can be blocked and the comfort of the helmet when in use is improved. Meanwhile, since the operation space occupied by the external gear rotating around a fixed axis is relatively small, a more flexible arrangement option is provided for the fixing structure of the support base 3, the rigidity can be improved. 3, therefore, the overall safety of the helmet can be further improved.
[0169] The above embodiments are merely various preferred embodiments of the present disclosure and are not intended to limit the scope of protection of the present disclosure. Therefore, various equivalent variations made in accordance with the structures, shapes and principles of the present disclosure will fall within the scope of protection of the present disclosure.

权利要求:
Claims (20)
[1]
1. A helmet with a transformable chin guard structure with gear restraint, comprising:
a carcass body;
a chin guard; Y
two support bases,
wherein the two support bases are arranged on two sides of the carcass body, respectively, and the two support bases are fixed to the carcass body or integrated with the carcass body;
wherein the chin guard is provided with two branches which are arranged on two sides of the carcass body, respectively;
wherein for each of the two support bases, an internal gear constrained by the support base and / or the carcass body and an external gear constrained by the support base and / or the carcass body are provided;
wherein the internal gear can rotate about an axis of the internal gear, and the external gear can rotate about an axis of the external gear;
wherein the internal gear comprises a body or accessory having a through slot, and a drive member is provided which runs through the through slot;
wherein the support base, branch, internal gear, external gear, and drive member on one side of the casing body constitute an associated mechanism;
wherein in the associated mechanism, the branch is disposed outside the through slot of the internal gear, the external gear and the internal gear are meshed together to form kinematic torque, and the internal gear is in sliding fit with the branch to constitute a sliding kinematic pair;
wherein the actuating member is in engagement restraint with the external gear at one end of the drive member, such that the drive member can be driven by the external gear or the external gear can be driven by the drive member; the actuation member is in engagement restraint with the branch at the other end of the actuation member, such that the branch can be actuated by the actuation member or the actuation member can be actuated by the branch; Y,
wherein an actuation and operation logic executed by the chin guard, internal gear, external gear and actuation member in the associated mechanism comprises at least one of three situations a), b) and c):
a) the chin guard begins with an initial rotating action; then the chin guard actuates the internal gear to rotate through the branch; after which, the inner gear drives the outer gear by the gear between the inner gear and the outer gear; and then, the outer gear drives the branch to move by the drive member, and the branch is caused to slide displacement relative to the inner gear by a restriction between the inner gear and the branch of the slidable kinematic torque, of such that the position and posture of the chin rest are correspondingly changed during a chin rest rotation process;
b) the internal gear begins with an initial turning action; then, the internal gear drives the chin guard to perform a corresponding rotational movement by means of the sliding kinematic torque constituted by the internal gear and the branch; meanwhile, the inner gear drives the outer gear to rotate by the gear between the inner gear and the outer gear, and the outer gear drives the branch to move by the drive member and the branch is forced to make a displacement slidable with respect to the internal gear by a restriction between the branch and the internal gear of the slidable kinematic torque, such that the position and posture of the chin rest are correspondingly changed during a process of rotation of the chin guard; Y
c) the external gear begins with an initial turning action; then, the outer gear drives the inner gear to rotate by the meshing relationship between the outer gear and the inner gear; after which, the internal gear drives the chin guard to perform a corresponding rotational movement by means of the sliding kinematic torque constituted by the internal gear and the branch; and meanwhile, the outer gear drives the branch to move by the drive member and the branch is caused to slide displacement relative to the internal gear by a restriction between the branch and the inner gear of the sliding kinematic pair, of such that the position and posture of the chin rest are correspondingly changed during a chin rest rotation process.
[2]
The helmet with the transformable chin guard structure with gear restriction according to claim 1, wherein in the associated mechanism, the kinematic torque constituted by the internal gear and the external gear is a flat gear drive mechanism.
[3]
The helmet with the transformable chin guard structure with gear restriction according to claim 2, wherein in the associated mechanism, the internal gear and the external gear are cylindrical gears; and, when the inner gear and the outer gear are meshed with each other, a pitch radius R of the inner gear and a pitch radius r of the outer gear satisfy a relationship: R / r = 2.
[4]
The helmet with the gear restraint transformable chin guard structure according to claim 3, wherein in the associated mechanism, the actuating member comprises a surface of revolution structure having an axis of revolution, the axis of revolution can always rotate around an external gear shaft synchronously together with the outer gear, and the axis of revolution is arranged parallel to the outer gear axis and intersects a pitch circle of the outer gear.
[5]
The helmet with the gear restraint transformable chin guard structure according to claim 4, wherein the surface structure of revolution of the actuating member is a cylindrical surface structure or a circular conical surface structure.
[6]
The helmet with the gear restraint transformable chin guard structure according to claim 5, wherein,
the coupling restriction between the drive member and the outer gear is that the drive member is attached to the outer gear or integrated with the outer gear, and the drive member is in rotary fit with the branch; or
the coupling restriction between the drive member and the outer gear is that the drive member is in rotary fit with the outer gear, and the drive member is attached to the branch or integrated with the branch; or the coupling restriction between the drive member and the outer gear is that the drive member is in rotary fit with the outer gear, and the drive member is also in rotary fit with the branch.
[7]
The helmet with the transformable chin guard structure with gear restriction according to claim 6, wherein a first anti-disengagement member capable of preventing axial play of the internal gear is arranged on the support base, the body of casing and / or external gear; a second anti-disengagement member capable of preventing axial play of the external gear is arranged on the internal gear, the support base and / or the casing body; and, a third anti-disengagement member capable of preventing axial loosening of the chin guard branch is disposed on the internal gear.
[8]
The helmet with the gear restraint transformable chin guard structure according to claim 7, wherein at least one of the outer gear gear teeth is designed as an abnormal gear tooth having a thickness greater than average thickness of all effective gear teeth in the outer gear, and the driving member is only connected to the abnormal gear tooth.
[9]
The helmet with the gear restraint transformable chin guard structure according to claim 8, wherein the through slot of the internal gear is a flat straight through slot which is arranged to point or pass through a gear shaft internal; the sliding kinematic torque constituted by the sliding fit of the internal gear with the branch is a linear sliding kinematic torque, and the linear sliding kinematic torque is arranged to point or pass through the internal gear shaft; and, the straight through slot and the linear sliding kinematic pair are superimposed on each other or parallel to each other.
[10]
The helmet with the gear restraint transformable chin rest structure according to claim 9, wherein when the chin rest is in a full helmet structure position, the axis of revolution of the surface of revolution structure of the member drive in at least one associated mechanism overlaps the internal gear shaft, and the linear restraint elements comprised in the slidable kinematic torque in the associated mechanism are perpendicular to a plane constituted by the internal gear shaft and the gear shaft external.
[11]
The helmet with the gear restraint transformable chin guard structure according to claim 10, wherein a central angle a covered by all effective gear teeth in the internal gear is greater than or equal to 180 degrees.
[12]
The helmet with the gear restraint transformable chin guard structure according to claim 11, wherein a first clamping structure is arranged on the support base and / or the carcass body; at least a second clamping structure is arranged on the body of the internal gear or an extension of the internal gear; an actuation spring for pressing and actuating the first clamping structure near the second clamping structure is further disposed on the support base and / or the carcass body; the first clamping structure and the second clamping structure are male and female clamping structures coupled to each other; And, when the first clamping structure and the second clamping structure are clamped together, the effect of clamping and maintaining the chin rest in the current position and posture of the chin rest can be achieved.
[13]
The helmet with the gear restraint transformable chin guard structure according to claim 12, wherein the first attachment structure has a convex tooth configuration; the second clamping structure has a groove configuration; At least one second clamping structure is provided, wherein a second clamping structure is clamped with the first clamping structure when the chin guard is in a full helmet frame position and another second clamping structure is clamp fitted with the first holding frame when the chin guard is in a semi-helmet frame position.
[14]
The helmet with the gear restraint transformable chin rest structure according to claim 13, wherein another second clamp structure is clamped with the first clamp structure when the chin rest is in a chin frame position. uncovered face.
[15]
The helmet with the gear restraint transformable chin guard structure according to claim 14, wherein the shell body comprises a spring reinforcement arranged on the support base and / or the carcass body; when the chin guard is in the full helmet frame position, the bracing spring compresses and stores energy; When the chin guard rotates from the full helmet frame position to a shell body dome, the bracing spring releases the elastic force to help open the chin guard; and, when the chin guard is located between the full helmet frame position and the open face frame position, the reinforcing spring stops acting on the chin guard.
[16]
The helmet with the transformable chin guard structure with gear restriction according to any one of claims 1 to 15, wherein in at least one associated mechanism, a ratio of a number of teeth equivalent to the full circumference of the gear internal ZR of the mesh elements included in the internal gear with respect to an equivalent number of teeth of full circumference of the external gear Zr of the mesh elements included in the external gear satisfies a ratio: ZR / Zr = 2.
[17]
The helmet with the transformable chin guard structure with gear restriction according to any one of claims 1 to 15, wherein the external gear in at least one associated mechanism comprises a web plate which is arranged in the external gear .
[18]
18. The helmet with the transformable chin guard structure with gear restriction according to any one of claims 1 to 15, wherein in at least one associated mechanism, the internal gear comprises a through groove constituted in the internal gear, the Through groove participates in the slidable restraint behavior of the internal gear and the branch, and the slidable restraint behavior constitutes a part or all of the slidable kinematic pair constituted by the internal gear and the branch.
[19]
The helmet with the transformable chin guard structure with gear restriction according to any one of claims 1 to 15, further comprising a visor, wherein the visor comprises two legs arranged on two sides of the shell body, respectively , and capable of oscillating about a fixed axis with respect to the carcass body; A load bearing rail side is arranged on at least one of the legs, and the leg with the load bearing rail side is arranged between the bearing base and the carcass body; a through opening is constituted by an inner support plate in the support base facing the casing body, and a trigger pin that extends out of the opening and can come into contact with the load bearing rail side of the leg is arranged in the external gear; and, when the visor is fully fastened, the arrangement of the trigger pin and load bearing rail side satisfies several conditions: When the chin guard is opened from the full helmet frame position, the trigger pin can come into contact with the load bearing rail side on the leg and thus make the visor rotate; and when the chin rest returns to the full helmet frame position from the semi-helmet frame position, during the first two-thirds of the return trip of the chin rest, the trigger pin may come into contact with the rail side of the load bearing on the leg and thus make the visor rotate.
[20]
The helmet with the gear restraint transformable chin guard structure according to claim 19, wherein the first toothed locking teeth are provided on the legs of the visor, and the second locking teeth corresponding to the first teeth locking devices are arranged on the support base and / or on the casing body; a locking spring is arranged on the support base and / or on the casing body; the first locking teeth move synchronously with the visor, and the second locking teeth can move or oscillate relative to the carcass body; when the visor is fastened, the second locking teeth can move close to the first locking teeth under the action of the locking spring, such that the visor is loosely locked; and, when the visor is opened by an external force, the first locking teeth may forcibly actuate the second locking teeth to compress the locking spring to move to give way to the first locking teeth and unlocking the first locking teeth.

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同族专利:

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公开号 | 公开日

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BR112021011073A2|2021-08-31|

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PE20212014A1|2021-10-18|

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EP3884798A4|2022-03-09|

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EP3884798A1|2021-09-29|

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WO2020177342A1|2020-09-10|

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PH12021551218A1|2021-11-08|

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GB202105668D0|2021-06-02|

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GB2592791A|2021-09-08|

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US20210274877A1|2021-09-09|

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KR20210092798A|2021-07-26|

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CN109875177A|2019-06-14|

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CO2021009510A2|2021-08-09|

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CA3116276A1|2020-09-10|

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JP2022515533A|2022-02-18|

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AU2019432494A1|2021-05-20|

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DE112019005996T5|2021-08-12|

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法律状态:
2021-11-18| BA2A| Patent application published|Ref document number: 2878249 Country of ref document: ES Kind code of ref document: A2 Effective date: 20211118 |

优先权:

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申请号 | 申请日 | 专利标题

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CN201910160133.8A|CN109875177A|2019-03-04|2019-03-04|A kind of gear restricted type helmet with changeable jaw guard structure|

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PCT/CN2019/113168|WO2020177342A1|2019-03-04|2019-10-25|Gear-constraint-type helmet with transformable jaw-guard structure|

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