专利摘要:
Expendable blades for use in tire buffing machines are disclosed having teeth with an outer edge and outwardly diverging leading and trailing side edges which form sharp prongs with the outer tooth edge for deep attack into the tire carcass; these teeth also having secondary or fine cutting edges comprised by the converging side edges of a cut-out, e.g., circular, in the outer edge of said teeth and surface-finish or buffing edges comprising the trailing edge of notches or slots which interrupt the outer tooth edge between the cut-out and one or both sharp prongs of the leading and trailing tooth side edges.
公开号:SU884559A3
申请号:SU752137825
申请日:1975-05-20
公开日:1981-11-23
发明作者:Е.Дженсен Вэйн;К.Стэнфилд Чарльз
申请人:Би Энд Джей Мануфакчуринг Компани(Фирма);
IPC主号:
专利说明:

one
The invention relates to equipment for the machining of rubber and can be used in devices for removing treads from used tires.
A known tool for removing protectors .c of used tires, made in the form of replaceable sheet processing elements mounted on a drive hub with a tooth-Ocuta working part having a main cutting edge for coarse turning 1.
A disadvantage of the known tool is that its cutting edge 15 provides only rough turning.
The purpose of the invention is to improve the quality of the treated surface.
The goal is achieved by the fact that at the top of the tooth there is a cavity, which forms additional cutting edges for fine turning, and there is a slot between the main and additional cutting edges, which form grinding cutting edges, and the depth of the cavity is less than the height of the tooth, and the main and additional cutting edges located in different planes.
At the same time, the grinding edges of the slot are located to the top of the tooth at an angle greater than the angle of the main and additional cutting edges to it.
In addition, the tooth of the face machining element is made with two oppositely directed cutting edges and two slits, each of which is located between the main and additional cutting edges.
At the same time, additional cavities are made at the sites of the slots.
In addition, the main and additional cutting edges are made concave.
FIG. 1 shows the instrument, the overall appearance; in fig. 2 is a plan view; in fig. 3 - sheet processing element with a toothed working part; in fig. 4 - the same, top view; in fig. 5 - the same, on an enlarged scale; in fig. 6 is a section A-A in FIG. 3; in fig. 7 and 8 .- options for positioning the toothed working part with respect to the processing element 5; in fig. 9-14 - options for the location of the main and additional cutting
edges in different planes; in fig. 15-20 cutting edges, respectively depicted in FIG. 9-14; in fig. 21-23 - various embodiments of the toothed working part; in fig. 24-26 are embodiments of a processing element; in fig. 27, an embodiment of the working part) in FIG. 28 - the same, top view; in fig. 29 shows an embodiment of the processing element; in fig. 30 is a hub for fastening the machining element shown in FIG. 29; FIG. 31 is the working part of the tool for the hub shown in FIG. thirty; on league. 32 and 33 illustrate embodiments of the working part of the tool for the hub shown in FIG. thirty; in fig. 34 is a tool with machining elements shown in FIG. 32 and 33; in fig. 35 section bb in fig. 34; on Fig hub with machining elements made in the form of a single tooth; in fig. 37 - the same, on an enlarged scale; in fig. 38 is a sectional view BB in FIG. 37; in fig. 39 is a cross-section of the FIG. 36; in fig. 40 is a variant of the tooth of the working part; in fig. 41 is a section DD in FIG. 40; in fig. 42 and 43, the hub with the teeth shown in FIG. 40
The tool contains a hub 1, formed by the front 2 and rear 3 disks, in which central holes are made, with which they are mounted on the end of the shaft 4 of the engine 5. Both disks have the same shape and the same size. Axial pins 6 (Fig. 2) are fixed on the rear disc, which are intended for mounting individual processing elements 7 onto them. Elements 7 are arranged concentrically around the X-X axis of the hub so that their outer working edges protrude beyond the outer edge of the hub and are cut off from the tire T worn out protector.
The elements 7, in accordance with one of the variants (Fig. 3), are made by stamping from sheet metal and have a concave-convex shape, forming segments 8 having a predetermined angular extent.
The angular extent of each element 7 is approximately 72, which makes it possible to form one closed ring out of five separate elements that are installed with each other. Each segment 8 consists of a main part 9 with flat parallel outer surfaces and a convex working section 10 (Fig. 5), which lies in the same plane as the main part 9. In other embodiments, the working section of the element can be made inclined with respect to to the main part 9. In the main part 9 there are holes q and, with the help
which elements 7 are mounted on the fingers 6 between the disks 2 and 3 of the hub 1.
Axial pins 6 fixed to the rear disk 3 are combined into appropriate groups depending on the number of elements forming a common ring, and in the front disk 2 there are appropriately arranged holes b in which the outer ends of the fingers 6 enter.
The distance between the fingers 6 and the holes to corresponds to the distance between the holes o and b, or between the holes a and c (dashed lines) .and b, which are made in segments 8 (depending on whether two or three finger). The hole a has a round shape and its diameter is larger than the diameter of the finger 6 passing inside it.
Holes c and b have the same shape and the same diameter; however, it is more expedient to make hole b (and hole c.) Oval in order to facilitate the installation of the segments on the fingers. The smallest diameter of the oval holes b and c should be equal to the diameter of the hole a, which excludes the possibility of moving the segments after the final assembly of the hub.
The segments 8 are arranged in several separate rows and are separated from each other in the axial direction of the gaskets 11, which are disks with central holes having a certain diameter. Separate segments can be used as shims, the size and shape of which correspond to the size and shape of segments 8, while the shim segments should have holes for fingers 6 to pass through. Segments 8 and shims 11 are assembled with each other so that the segments 8 are located in separate parallel planes. Another mount is possible. Thus, for example, the segments may be arranged in continuous rows or in rows, i.e., the shape of a helix with the axis coinciding with the axis of the hub X - X. In some cases, to obtain an oscillating effect during the rotation of the hub, adjacent segments in each row set at different angles to the x axis x. in that case, when the segments are not located around the circumference, the ends of the disks 2 and 3 should have specially treated areas with shoulders, designed for proper mutual placement of the segments.
The hub 1 together with the knives of the gaskets is mounted on the end of the shaft of the engine 5 and pressed against the flange 12 of the shaft 4 with the help of a nut 13. On the working part 10 of each of the segments 8 there are located main outlets 14 and smaller hollows 15 located between the main cut-outs (Fig. 3). Each of these cut-outs has a circular shape, and the length of the cut-out arc exceeds 180 and is approximately equal to zoo. All main notches 14 are preferably of the same size, and the centers 16 are located along the line b-1 at equal distances from the outer edge of the segment, and the distance between the centers of these protrusions is approximately two diameters of the circle of the notch. The main notches 14 divide the outer segment segment into equally spaced and equally sized teeth 17 (Fig. 5). Each of these teeth is separated from the neighboring teeth by a cylindrical notch 14, which has a mouth of 18, the length of the arcs of which is less than the diameter of the notch and is approximately 60 °. Each tooth 17 has a concave front edge 19 formed by the wall of one of the notches 14, and an oppositely directed concave rear edge 2 formed by the wall of the adjacent cut 14. Above the b-b center line. where the centers of the 16 main cuts 14 are located, the concave front 1 and rear 20 edges of each tooth extend from each other in areas whose arc length is approximately 60, as a result of which they are at the intersection of the cuts 14 with the outer edges the tooth 21 of the outer part 10 of the segment 8 form sharp protrusions 22 and 23. Each tooth 17 has a relatively narrow web 24, which is located on the center line b-b and is equal in length to the diameter of the main cutter 14. Sections of the concave front and rear cutting edges 19 and 20 located in Above the center line L-b, the angular extent is 60 °, and together with the outer edge of the tooth 21 form sharp ends 22 and 23, and due to the concave shape of these areas, the sharp ends of the teeth are cut off at an angle of less than 60 ° (since A-a, passing through the extreme point of the cusp and the extreme point of the base of the tooth 21, is inclined to the center line L-b at an angle of 60 °). The angle of inclination of the cusp of the tooth does not exceed 30 °. Due to this, the protrusion formed by the cutting edge 22 of each tooth 17 can deeply enter into the tire carcass material, while the presence of the shed 18 located between this protrusion and the previous tooth allows for removing rather large chips from the outer surface of the carcass. Below the center line L-d, the anterior and posterior edges of teeth 25 and 26 diverge from each other along q, y, the angle of which is 90, resulting in a wide base: e of the tooth, which can withstand considerable loads and exclude possible tooth breakage. Thus, the proposed shape of the front and rear edges of the teeth 17 makes it possible to obtain a cutting tool with high strength properties close to the strength CBC.iCT of the watch glass. The cavities 15, located on the outer edge of the tooth 21 between the front and rear edges of the teeth, are designed so that their centers 27 are located at equal distances from the outer edge of the knife. At the same time, each of these cuts has an open section 28, the arc length of which is 6 °, and the outward front 29 and rear 30 edges, the length of the arc of which is also equal to bo. At the intersection of the front 29 and rear 30 edges of the valleys 15 with the outer edge of the tooth 21, sharp protruding ends are formed, the inner parts of which have an inclination angle of less than 60 ° (approximately 30%). The troughs 15 have a diameter less than the diameter of the main notches 15, and are located above the line of centers L-b above the narrowest section 24 of the tooth. There is a third group of cutting edges, which are located on the sides of the projections 15 and which are used for final processing (grinding) of the frame surface. These third cutting edges are formed by the rear edges 32 and 33 of the slots 34 and 35. The rear edges 33 and 32 of these slots are made and are located parallel to the forward leading edges of the slits. The rear edge 32 of the slit 34 is inclined to the outer edge of the tooth 21 at an angle of 60 ° and has a positive rake angle, taking into account the direction of rotation of the knife. This determines the angular extent of the main leading edge of the tooth, however it is made more blunt than the first 22 and second 31 cutting edges of the tooth. Another cutting edge 33 has a negative rake angle of approximately 120 ° and, unlike the cutting edge 22, It has no cutting effect on the tire material. Thus, the rear edges 33 and 32 of both slots 34 and 35 form a kind of grinding cutting edges. Since the main grinding effect on the tire being processed is exerted by those areas of the cutting edges 32 and 33, which are located at the intersection of the slots 34 and 35 with the outer edge of the tooth 21, it is advisable
The inner ends of these slots are located adjacent to the line of centers -l. l increase the strength of the tooth and the smaller amount of heat absorbed during the rhenium process, the slots 34 and 35. should be placed in the middle between the edges 29 and 30 and the edges 22 and 23. For this purpose, the slots are inclined and are parallel to the chorema-a of the cutting edges 22 and 23, as a result of which the width of the knife and, in particular, those parts of the knife which come into contact with the tire carcass during its processing, are divided into equal parts 36 by hollows 15 and slots 34 and 35 located to the side of these notches. 34 and 35 should be long enough for Oba could tilting the troughs arranged on the side of the blade sections 15, to expose the cutting edges 33 and 32 and position these edges and the front cutting edge 22 of the knife and a second cutting edge 31 in different planes. For this, the inner ends of the slots 34 and 35 are located adjacent to the narrowest part of the tooth 24.
Sections 36 of the outer edge 2 of the tooth, located between the slots 34 and 35 of the cavity 15, can be bent by placing them in the plane forming an acute angle with the main plane of the knife (Fig. 3 and 4). in this case, the areas 37 of the outer crust of the tooth 21, which are located between the slots 31 and 35 and the main cutting edges of the teeth 19 and 20 that form the sharp protrusions of the tooth, can either be left in the tooth plane or bent back or other side relative to the main plane of the knife and the outer portions of the tooth 26.
The bending of the portions 37 is performed when the portions 36 are not folded, but remain in the main plane of the tooth. With this bending, not only the first and second cutting edges are exposed, but also the grinding cutting edges, which are formed by narrow slits, are exposed, which contributes to their better penetration into the material of the processed logs. Sections 36 of each adjacent tooth are bent and arranged in planes at an angle to the main plane of the knife, in which the Zubiev 8 sections lie. The sections 36 of the tooth can be bent to the other side (compared to the knife shown in Fig. 3 and four).
Both portions of J6 of each tooth can also be bent to one side. (Fig. 10 and 16) and have a 0-F form. Sections 36 of adjacent teeth can be bent in different directions and located, respectively, on opposite sides of the main plane.
knife., in both cases, the sections of all the teeth 37 lie in the main plane of the knife, i.e. made unbent. Sections 37 are also bent, and they are bent in the same direction as sections 36 (FIG. 12) or located on the other side of the knife (FIGS. 13 and 19).
FIG. 14 and 20 sections 36, located on one side of the main plane of the knife, are bent towards each other, and sections 32 are also bent towards each other and intersect the main plane of the knife. The angle at which the tooth portions 36 and 37 are folded may be the most varied, however, the best results are obtained when the plane of the folded portions forms an angle of 30-35 with the main plane of the knife.
You can also use knives with only one narrow slot, in this case, the cavity 15 and slot 34 or
35 should be arranged in such a way that the outer edge of the tooth is divided by a slot and a cut into areas of equal length. It is advisable to make the edges of the slots 33 and 32 straight. However, with the limb of the outer sections
36 and 37 teeth optionally slotted
34 and 35 to be made relatively wide. However, in some cases it is advisable to make the working surface of the abraded edges 33 and 32 slightly concave (Fig. 15). As a rule, slots 34 and 35 are non-radial, which helps to reduce the temperature in the area of the tire treatment. FIG. 23, slots 34 and 35 are made in the form of open half-circular cuts 38 located on the outer edge of the 21 teeth adjacent to its front 19 and rear 20 cutting edges, the cuts 38 should be relatively small (i.e. the depth of these cuts should be approximately half their widths). At the same time, a narrow slot 39 is made in the lower part of the semicircular notch 38, which facilitates bending of the tooth sections 36 and 37 and the formation of open rear cutting edges 40, which are used to finalize the texture of the frame surface to be processed.
In all considered variants of knives, the first main cuts and hollows have the shape of a circle. In time, these notches and hollows can. have another shape. For example, they can be made in the form of various polygons (Fig. 21 and 32). In this case, in all the variants, the anterior end of each tooth must have a positive rake angle and should be located at an acute angle to the outer edge of the tooth 21, since only in this case the main cutting edges of tooth 9 can penetrate sufficiently deep into the material pro. The vector of the tire and its rough turning are possible, and the second cutting edges 30 can provide the final turning of the surface being machined and giving it the required shape. For this, the rear 1 teeth of the teeth are made in such a way that the angle between them and the outer edge of the knife does not exceed 60. With these requirements in mind, cutting edges can be obtained using both round and multi-angle cuts. In FIG. 22, the main cutting edge 41 is made straight and inclined to the outer edge of the tooth 44 at an angle of less than 60 °. To avoid weakening the tooth, it is desirable that the inclined edges 41 and 42 descending outward do not descend below the center line (dashed lines 43 and 44 in FIG. 22) and gradually shifted to the radial sections of the straight coal notches 45 and 46 (FIG. 16). In FIG. 21, the lower lateral sides of the notch 45 and 46 are not radially arranged, but are made inclined towards the inside of the notch, thereby increasing the width of the base of the tooth. The different configurations can also have n valleys 25, which can be performed, in particular, in the form of cuts (Figs 2 and 22). At the same time, the specified ratio between the sizes of the first and second cuts should be maintained, as well as the specified location of the narrow cuts 34 and 35. forming the grinding edges of the knife. The open area of the cavities should also be smaller than the open area of the main cuts, which, in turn, should be approximately equal to the length of their inclined edges 41 and 42 located between the outer edge of the tooth and the center line. In some cases, you can reduce the open area of the main cuts. , - both round and polygonal (figs. 21 and 22), with the front bend of the protruding end of the tooth 22 at a certain angle to the plane of the rest of the tooth. The outer working part 10 of the knife 2 is located between the main notches 14 (with the exception of the bent sections 36 and 37 of the teeth), lies in the same plane as the base of the knife 7. This also applies to the knives in which the entire working part 10 of the knife is bent under by some angle to the plane of the base of the knife (FIGS. 6 and 7). In the knife shown in FIG. 6, the working plane of the knife with the teeth 17 is bent to the plane of the base of the knife approximately at an angle of 30 °, and in the knife shown in FIG. 7, approximately on the first one, furthest from the engine 5, a row of knives 47 is made with teeth 17 bent away by 30 (FIG. 6). The rest of the rows are .. all located beyond this area, when viewed in the direction of rotation of the edge (arrow K), are made with red teeth, In knives with bent teeth (Figs 6 and 7) it is advisable to bend the outer edge sections 36 and 37 teeth, which contributes to a deeper penetration of the main cutting teeth into the material being processed and improves the characteristics of the tool. In all the considered variants, the knives have the shape of segments 8 with a convex outer edge and a concave inner edge (FIG. 3). On Fig shows a variant of the knife with two convex working areas, on which are located the first cutting edges 19, the second cutting edges 30 and grinding edges 33 and 32. When using such knives mounted on the hub of the machine between its extreme disks 2 and 3, The tire treatment process is carried out using only one working area of the knife. Ji blunting the cutting edges of section 10 of the knife can be removed from the hub and turned over so that further processing of the tire is performed using its other working section 48, which doubles the service life of the knife. In any shape of the knife (FIGS. 3 and 24), each tooth of the knife has front and rear main cutting edges, a depression and one or more narrow slits that form the grinding edges of the knife. Knife variants are shown in FIGS. 27 and 28. The main part of the teeth 49 has a front main cutting edge 19 with a protruding sharp end 22, which has a positive rake angle smaller than 60 °. At the outer edge 22 of each tooth 49 there is a cavity 15, which forms an additional cutting edge 30 with the greatest sharp protruding end 31, and a narrow slot 35 forming a grinding edge 33 located between the main cutting edge 19 and the depression 15. The rear edge 50 of the main notch 51 does not this has a sharp cutting area, and therefore the knife cannot be rearranged after the wear of its cutting edges. On the teeth x 49 of this knife there is no second narrow slot 34 with a negative rake angle grinding edge. However, in addition to the teeth 49, the teeth 52 also have these teeth, which are U-shaped with two outwardly converging: edges 52, are bent out of the plane of the teeth 17 (FIG. 28) to the side opposite to which the sections 36 are bent teeth 49,
The main cutout 51, which separates the kill from each other, is made in a round portion of the posterior edge of this cutout and it resembles the front cutting edge of the tooth 49. The cutout 51 differs in shape from the round (Fig. 3) or polygonal cut (Fig. 21 and 22), and makes It is equally wider and has a wider open area, which increases the depth of penetration of the tooth into the material of the rotor being cut off from the tire.
The design of knives with teeth shown in FIG. 8 is more preferred.
FIG. Figures 25 and 26 show variants of knives made respectively as a whole disk 54 or a whole ring 55. In these knives there are teeth 17 located along their entire outer edge, which are formed by corresponding circular notches 14. On each tooth, in addition, there are hollows 15 and narrow slit slots .34 and 35. Sections 36 and 37 of the teeth are bent away from the plane of the knife (similar to FIG. 4) in order to expose the rear edges of the narrow slots. Knife refueling (bending of the corresponding portions of their teeth) can also be performed in accordance with the variants shown in FIG. 9-14, The central holes 56 are also made in the disks 54 (FIG. 25), for mounting the disks on the shaft 4 of the engine 5 when assembling the hub 1, and in the knives having the shape of a ring (FIG. 26), holes 57 are made designed to install the knives on the corresponding palyda rear disc hub. The blade knives 54 do not have such openings and, when assembling the hub, are simply clamped between the front and rear disks of the hub.
FIG. 29 shows the knife 58, made in the form of a flat sheet 59 with a straight working section 60. On the right -. The working section 60 of the knife has a tooth 17, separated from each other by the main notches 14, a notch 15 is made on the outer edge 21 of each tooth, located in the middle between the adjacent main notches 14, and also narrow slots 34 and 35 located between the cavity 15 and the front 22 and rear 23 sharp edges and forming edges 33 and 32 of the knife.
Knives are used in the processing of covers with the hub shown in FIG. 30, for which installation holes 61 are made in them (Fig. 29). These holes are located at equal distances from the working edge 60 of the knife and, with their help, the knives are mounted on the fingers 62 of the mounting unit 63 (Fig. 31). On the same fingers install partitions 64,
which separate the adjacent knives from each other.
Several such mounting blocks 63 together with knives and partition walls are mounted on the upper side of the disk 65, in the center of which a cylindrical hole is made (Fig. 30). On the outer diameter of the disk 65 there is an annular edge 66 with holes 67 in which the ends of the fingers 62 of the respective blocks 63 are included. The cam clips 68 located on the disk 65 are used to attach the blocks 63 to the disk 65. After the blocks 63 are mounted on the disk, the working edges 60 the knives protrude beyond the ribs of the disk 66, and the knives themselves are located in the tangential direction relative to the axis of rotation of the hub. The axis of rotation of the hub Xx coincides with that shown in FIG. 1 axis and not perpendicular to this axis.
FIG. 32 and 33 show the knives that are used in the hub shown in FIG. 34 and 35, which consists of a main disk with a central hole, into which the motor shaft enters, and a disk 70, which is mounted over the disk 69 and fixed to its outer surface with screws 71. In the disk 69 there is a ring groove 72 in which a ring 73 is inserted On the ring there are two concentrically arranged annular grooves 74 and 75. In the groove 74 are inserted knives, shown in FIG. 32, and the groove 75 — the knives shown in FIG. 33. The disc 70 has slots 76, which are located tangentially to the axis of the disc and are grouped into groups, each of which consists of eight separate slots.
Depicted in FIG. 33, the blade consists of a base 77 and two cutting edges 78, which are parallel to each other and perpendicular to the plane of the base 77 of the blade. The knife shown in FIG. 32 also consists of a flat base 78 and several (six) vertically positioned cutting edges 79. The cutting edges 78 of the knife shown in FIG. 33, and the cutting edges 79 of the knife shown in FIG. 32, are parallel to each other, and. perpendicular to the plane of the base of the corresponding knife. On the working faces 79 and 77, there are teeth 17 formed by the main notches 14, and on the teeth x there are hollows 15 and inclined narrow slots 34 and 35 (Fig. 29) The working edges of the knife shown in Fig. 32 are not formed (as in a knife shown in Fig. 23) by the outer edges of the base of the knife, and made in the form of upwardly bent portions of the base located in its middle part.
As shown in FIG. 35 knives 80 and 81 are mounted on ring 73, respectively, made on it.
annular grooves 75 and 74, and the working faces of the knives 78 and 79 pass through the corresponding slots 76 made in the outer disk 70. Here, the vertical working faces 78 of the knife
80, which is mounted in an annular groove 75, passes simultaneously through the notches made at the base of the knife 81. The outer disk 70 is fixed to the disk 69 with screws 71, which simultaneously fix the knives in the corresponding grooves of the ring 73.
The knife 82 depicted in FIG. 37 consists of a rectangular base 83, on the opposite edges of which the working sections 84 of the knife are located,
81.Each of these areas is made in the form of one tooth with a front semicircular cutting edge 19 and a rear semicircular cutting edge 20. On the outer edge of the tooth 21 a notch 15 and two narrow slots 34 and 35 inclined to the middle part of the knife are made, which are located between the notch 15 and the main cutting edges 19 and 20, at the ends of which are located the cusps 22 and 23. The inner ends of the slots 34 and 35 are located above the center line, on which the centers of the semicircles are located, forming the front 19 and rear 20 cutting edges of the tooth.
Thus, the knife has two working sections 84, made in the form of one tooth 17, the geometry of which is similar to the geometry of the tooth shown in FIG. 8.3ub, shown in FIG. 37, has bent portions 36, which are located on the outer edge of the tooth between the slots 34 and 35 and the notch 15 / and the unbent portions 37. The outer portions of the tooth can be bent differently (Fig. 4 and 9-14). In addition, the main cutting edges of the tooth (front and rear) can be made the same as those of the teeth shown in FIG. 21-23.
As shown in FIG. 39, the knives 82 are set circumferentially at equal distances from each other between the two disks of the hub 85 and 86 so that one of the working edges of the knife protrudes beyond the outer diameter of the hub and the other turns out to be located inside the hub and closed by the disks.
As shown in Fig. 37, the base 83 of the knife 20 is bent on section 87, for example, at an angle of 60, with the result that after installing the knives between the disks of the hub 85 and 86, their projecting working areas form a kind of truncated cone whose axis lies H4 axis rotation of the hub xx (Fig. 36), this cone consists of separate equally spaced teeth separated from each other by comparatively large windows 88. For the convenience of assembling the knives at the base of each knife 83
an oval hole 89 is made into which the finger 6 enters, fixed in the disk of the hub 85. The length of the hole 89 is such that each knife 82 can move in the radial direction along the corresponding finger up to the stop of the finger in the outer or inner edge of the oval hole 89. As shown in FIG. 39, in both disks 85 and 86 of the hub are made annular grooves 90 and 91, in which
0 includes bent portions of the teeth located inside the hub between its discs.
FIG. 40 and 41 show a variant of the knife shown in FIG. 37. In
15 of this embodiment, the knife 92 is made unbent and has a flat shape.
As shown in FIG. 42 and 43, two fingers 94 and 95 are attached to the installation disk of the hub 93, and the diameter of the finger 94 is larger than the diameter of the finger 95. At the same time, a hole 97 is made at the base 96 of the knife 92 (Fig. 40), the diameter of which is equal to the diameter of the finger 95. Fingers large diameter 94 offset 95 fingers
5 and are arranged in such a way that when assembling the hub, the rounded front and rear cutting edges of the teeth of adjacent knives form a hole in which the fingers 94 enter. The fingers 94, in this way, serve to fix the knives and prevent their lateral and longitudinal movements. At the same time, they are not directly in contact with the working sections of the teeth of the knives.
5 In addition, annular grooves 98 and 99 are made in the discs, which include bent sections of the inner ends of the knives.
The tool works as follows.
During processing, the tire is rotated around its axis at a speed less than the speed of rotation of the tool 1 hub. The tire is also moved relative to the tool. With
5, the protrusions 31 and 22 are removed from the upper surface of the tread corresponding to the rubber layer. Due to the fact that the depressions 15 have a smaller diameter than the notches 14, the protrusions 31 remove less chips from the tire and thus give the outer surface of the tire carcass a more uniform texture. At the same time, the grinding edges 34 and 35 provide the final surface treatment of the carcass, without significantly changing the shape of this surface, which is obtained by treating the tire with the main and additional tooth edges.
0
When worn, the main and additional edges can be used to work oppositely directed cutting edges, for this segments 8
5 is repositioned on the hub.
The invention provides at the same time a rough turning of the frame with giving it the required shape, thin turning of the frame and polishing the turned surface, which provides further strong adhesion of the new tread applied to the frame during the subsequent vulcanization operation.
权利要求:
Claims (5)
[1]
1. Tool for successful protectors of used tires, made in the form of replaceable sheet processing elements installed on the drive hub with a toothed working part having a main cutting edge for coarse turning, which, in order to improve the quality of the surface to be processed, is at the top of the tooth a cavity is formed, forming additional cutting edges for a thin skirt, and a slot between the main and additional cutting edges forming a grinding cutting edges, with it depression depth less than the height of the tooth and the major
X
/
and additional cutting edges are located in different planes.
[2]
2. A tool according to claim 1, characterized in that the grinding edges of the slot are located to the top of the tooth at an angle greater than the angle of the main and additional cutting edges to it.
[3]
3. The tool PP. 1 and 2, differing in that the tooth of the sheet processing element is provided with two oppositely directed cutting edges and two slits, each of which is located between the main and additional cutting edges.
[4]
4. The tool of claim 3, which is based on the fact that additional cavities are made at the sites of the slots.
[5]
5. The tool on the PP. 1-4, characterized in that the main and additional cutting edges are concave.
Sources of information taken into account in the examination
1. US patent No. 3618187, cl. 29-79, published. 1971 (prototype)
/ 3 IS f 21 19} /,. Y L / Av J7 17 / - .ZU 7 5 3 fUt-f f,
J7
..
G / 37 7 tl “Pwe.iT X 17 No. Iff FIG. 9 A 7 tftut-IQ J7 3tf U6 J7 7 Jff J7jtf db J7 0W2 / 37 L .7 FIG. / J 37/6 36 "a 6 da FIG // 5J 7
/
F "/ g. / 57
4. / V with s --- --- with ± ac ::: s --- t
j7 36 7.
jr
- v
(--y -
37 c: "7 Fg. / 7
yes c, - if B / D ... "ff 37 Fig / S. .f..5
..y J7
FIG 20
..-
 four,
x-x
# ..:
l / 36 /. W 7 J7 3f IS yj TiS i Fi. No.
eftuz. 18 I / FIG. 29 b / xX 1: X x XX -. /xx.XxXx/V x 1 x-C -x / Vx /, jf X / XX 7 # JtfJ5: No. 78
FIG. 3f 4 .36 / I 7J 72 Fig. 34r 7 / f / I "U
类似技术:
公开号 | 公开日 | 专利标题
SU884559A3|1981-11-23|Tool for removing treads from used tyres
EP0566234B1|1997-10-15|Electric razor
US4021899A|1977-05-10|Tire buffing machine blades having heat dissipation means
SU736867A3|1980-05-25|Tool blade for removing protector from spent tire tread
US5283935A|1994-02-08|Tire rasp blade
US3927447A|1975-12-23|Tire rasp
US4283820A|1981-08-18|Segment-shaped blade
US1395309A|1921-11-01|Tire-dressing wheel
US4336640A|1982-06-29|Cylindrical turning tool
EP0639419B1|2000-01-05|A rasp hub assembly
LV11889B|1998-03-20|Saw blade
US4283819A|1981-08-18|Segment-shaped blade
US6695547B2|2004-02-24|Tire rasp blade and assembly
KR820001884B1|1982-10-18|Tire rasp blade having multi cutting edges
CA2041984C|2000-07-11|Tire rasp blade
DK142269B|1980-10-06|Axially rotating hub for a tire removal tool.
CA2631718A1|2007-07-19|Rasp hub for tire retreading machine
US20180369942A1|2018-12-27|Tire rasp blade
GB1569266A|1980-06-11|Cutting tool for a machine tool
SU1724745A1|1992-04-07|Gin saw
DK142270B|1980-10-06|Tire clearance tool.
GB1570470A|1980-07-02|Scraping tool
同族专利:
公开号 | 公开日
DE2518020C3|1979-01-11|
FI59748C|1981-10-12|
FI305774A|1975-11-21|
ZA745559B|1975-10-29|
DK154996C|1989-06-12|
CH602324A5|1978-07-31|
FR2271923B1|1977-04-15|
IL46245A|1977-03-31|
IT1021658B|1978-02-20|
CA1001419A|1976-12-14|
YU128475A|1982-02-25|
ATA259475A|1980-03-15|
US3879825A|1975-04-29|
FI59748B|1981-06-30|
GB1466119A|1977-03-02|
PH14246A|1981-04-09|
AU473840B2|1976-07-01|
DE2518020B2|1978-05-18|
SE398464B|1977-12-27|
AR203121A1|1975-08-14|
YU36882B|1984-08-31|
JPS5324225B2|1978-07-19|
CS202040B2|1980-12-31|
SE7413421L|1975-11-21|
BE820525A|1975-01-16|
DK541374A|1975-11-21|
HU174536B|1980-02-28|
BR7409310A|1976-05-11|
NO150505B|1984-07-23|
NO150505C|1984-10-31|
FR2271923A1|1975-12-19|
AU7328774A|1976-03-18|
DE2518020A1|1975-12-04|
AT359383B|1980-11-10|
JPS50150979A|1975-12-04|
IN140077B|1976-09-11|
DK154996B|1989-01-23|
ES437334A1|1977-06-01|
NL7413585A|1975-11-24|
PL99803B1|1978-08-31|
NO744086L|1975-11-21|
IL46245D0|1975-03-13|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US3082506A|1959-04-29|1963-03-26|Emil B Jensen|Tire rasp|
US3351997A|1967-03-21|1967-11-14|Neilsen Products Co|Toothed blade for tire rasp|
US3747177A|1969-03-13|1973-07-24|W Jensen|Tire peeling device|
US3618187A|1969-03-13|1971-11-09|Wayne Emil Jensen|Tire peeling device|
US3528153A|1969-08-13|1970-09-15|Ernest W Walter|Rasp blade construction|US4059875A|1975-12-12|1977-11-29|B & J Manufacturing Company|Tire rasp blades with renewable cutting and buffing edges|
US4021899A|1975-12-12|1977-05-10|B. & J. Manufacturing Company|Tire buffing machine blades having heat dissipation means|
US4019234A|1976-05-03|1977-04-26|B & J Manufacturing Company|Tire rasp having reversible blade holder assemblies|
FR2375031B1|1976-10-26|1979-08-31|Ugine Carbone|
JPS569413B2|1976-11-12|1981-03-02|
US4091516A|1977-05-10|1978-05-30|B. & J. Manufacturing Company|Tire rasp blade having multi-cutting edges|
DE2832363A1|1978-07-22|1980-02-21|Sartorius Gmbh|SPRING ELEMENT FOR BENDING BEARINGS OF MOVABLE BEARING COMPONENTS IN PRECISION, FINE AND ANALYSIS SCALES|
ATA708379A|1979-11-05|1981-12-15|Miba Sintermetall Ag|BLADE FOR A CYLINDRICAL TURNING TOOL FOR MACHINING VEHICLE AIR TIRES|
JPS57125514U|1981-01-30|1982-08-05|
US4747194A|1985-10-02|1988-05-31|Spencer Industries Pty. Ltd.|Tire rasp blade|
US5054177A|1988-03-10|1991-10-08|B & J Manufacturing Company|Tire rasp blade|
US4840316A|1988-07-13|1989-06-20|Barclay Randel L|Rubber crumb recovery from vehicle tires|
BR9002650A|1990-05-31|1991-12-03|Hector Oscar Larin|CONSTRUCTIVE ARRANGEMENT IN A SAW AND SEPARATOR ASSEMBLY FOR TIRE SCRAPING|
US5301406A|1991-04-09|1994-04-12|Spencer Industries Pty. Ltd.|Tire rasp blade|
US5461762A|1993-08-31|1995-10-31|B & J Manufacturing Co.|Compound elliptical tire rasp blade|
US6554547B1|2000-08-09|2003-04-29|B & J Manufacturing Company, Inc.|Tire rasp blade and method of use|
US6682272B2|2001-10-12|2004-01-27|B & J Manufacturing|Rubber cutting apparatus|
US7451677B2|2003-01-27|2008-11-18|Eugene Carbide Saw & Machine, Inc.|Saw blade with secondary teeth|
AU2003255189B2|2003-10-21|2009-04-30|Pincott International Pty Ltd|Rasp blade with non-planar teeth|
EP2408613B1|2009-03-17|2014-03-19|Bridgestone Corporation|Tyre production method and system|
AR094373A1|2014-01-06|2015-07-29|Pérez Daniel Ricardo|MINI-PERIPHERAL HOLDER BLADE FOR SURFACE WEAR AND MOUNT ADAPTER DEVICE|
EP2960346A1|2014-06-24|2015-12-30|B & J Rocket Sales AG|A tire rasp blade|
EP3040148A1|2015-01-05|2016-07-06|Daniel Ricardo Perez|Peripheral clamping mini-blade for a superficial roughing down and mounting adapter device|
法律状态:
优先权:
申请号 | 申请日 | 专利标题
US471676A|US3879825A|1974-05-20|1974-05-20|Tire buffing machine blades|
[返回顶部]