• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A charging system comprising a power rail (15) and a current collector (2 '). The current collector (2 ') comprises a power take-off head (5) and a power take-off head drive mechanism. The power rail (15) is disposed adjacent to a position above a vehicle in a loading position, and includes a vertical insulated substrate (15-1) and a plurality of power supply electrodes (15-2) integrated on the side surface thereof. The power supply electrodes (15-2) are distributed in parallel at intervals in a direction up and down. The power take-off head drive mechanism drives the power take-off head (5) to have a vertical lift stroke and a lateral travel stroke. Current-collecting electrodes of the current-collecting head (5) are arranged on the outside thereof in a transverse movement direction and distributed in parallel at intervals in the up-and-down direction. The charging system allows a relatively large parking position deviation, thereby facilitating vehicle operation, has heavy current conductivity and reliable insulation property, facilitates accurate and stable current localization of a current collection head (5) and a power rail (15) while maintaining a safe distance between the charging system and pedestrians, ensures a safe and normal ride of vehicles and is particularly suitable for modern electric busses with energy storage.
    公开号:AT520874A2
    申请号:T9490/2015
    申请日:2015-11-26
    公开日:2019-08-15
    发明作者:Suo Jianguo;Li Jun;Yang Yingyu;Zhang Yanlin;Xiao Yong;Lin Peng;Wang Qiuhong;Feng Ye;Zhang Haifeng;Chen Minjian;Sun Ning;Zhou Jie;Guo Jinyu
    申请人:Crrc Zhuzhou Locomotive Co Ltd;
    IPC主号:
    专利说明:

    Loading System This application claims priority over Chinese Patent Application No. 201510333427.8 entitled "CHARGING SYSTEM" filed in the Chinese State Intellectual Property Office on June 16, 2015, the entire disclosure of which is incorporated herein by reference.
    FIELD The present application relates to the technical field of rapid charging and, more particularly, to a charging system for rapidly charging electric vehicles such as electric buses of the energy storage type.
    BACKGROUND With the development of society, development concepts of urban rail transportation such as energy saving and environmental protection have been continuously improved, and electric buses of the energy storage type have been developed. In a so-called electric bus of the energy storage type, a super capacitor is used to store electrical energy as a power for the pulling force; a pantograph is used for power take-off and feedback; charging is completed quickly within a few seconds while passengers get on and off at a station; and charging can ensure that the electric bus of the energy storage type can drive to the next station for charging. Due to the above characteristics, this type of vehicle is highly demanded and used.
    [0004] Reference is made to FIGS. 1 and 2. Figure 1 is a schematic view showing the structure of a pantograph of a charging system of an electric bus of the conventional energy storage type; and Figure 2 is a side view of Figure 1.
    As shown in the figures, an entire mechanism of the pantograph of the charging system of the electric bus of the conventional energy storage type can be understood as a four-point connection mechanism that runs along a longitudinal direction of the
    2/50
    21825-PCTAT
    Busses is mounted, and a power supply rail Γ is mounted directly above a pantograph 2 '(or a pantograph). Since all the rods in the four-point linkage mechanism have a constant length and the lengths of the rods are fixed in accordance with certain proportions, under the action of a spring or a driving force of a cylinder, a current collector head 3 'of the current collector 2' can be raised or lowered approximately vertically and with the power supply rail Γ come into contact directly above the pantograph 2 'after it has been raised vertically to a certain height in order to achieve a current draw for the bus.
    This pantograph has substantially the same operating principle as a roof-mounted pantograph (or pantograph) of other types of rail transportation vehicles and railless transportation vehicles and the like, and is more applicable to a rail transportation vehicle. In the event that this pantograph is applied to railless transport vehicles, e.g. a bus of the energy storage type, the following disadvantages are shown.
    First, a modern bus of the energy storage type uses conventional rubber wheels and is operated without guidance by rails, which is why a driver or driver can stop the vehicle with a large deviation. The maximum transverse parking position deviation, which is permitted by the above pantograph, is only 200 mm, which is why high demands are placed on the operating technology of the driver or driver and, furthermore, each time the charging process places high demands on the parking position and a parking angle of the vehicle if the vehicle retracts, which is why it is difficult to meet the practical use requirement, which is disadvantageous for the ease of vehicle operation, and thus causes instability in the charging process of the vehicle.
    Second, since the power is provided to the vehicle such that the pantograph is raised to contact the power supply rail directly above the pantograph to be charged when the vehicle enters, the vehicle body can wobble when the passengers and get out, and the wobble of the vehicle body can cause that mounted on the roof of the vehicle
    3/50
    21825-PCTAT
    Pantograph wobbles together, causing the current collector head on the pantograph to wiggle the left and right power rails, increasing contact resistance and causing a problem with current draw.
    Third, in order to ensure that the power pick-up head can come into contact with the power rail after it has been raised, the power pick-up head is generally in the form of a long slide plate, and an over-long power pick-up head can result in an unstable structure.
    Fourth, when the pantograph is lowered, it can occupy a large upper space of the vehicle, which can adversely affect the arrangement of other devices such as an emergency roof exit.
    For this reason, there is a technical problem to be dealt with by specialists in increasing the permissible parking position deviation of the charging system in order to simplify vehicle operation and to improve the stability of the current draw.
    SUMMARY An object of the present application is to provide a charging system. The charging system enables a large parking position deviation to simplify vehicle operation and ensure stable power consumption even when a vehicle body shakes. In addition, the charging system has advantages such as a stable structure and small space taken up.
    To implement the above goal, a charging system according to the present application is provided. The charging system includes:
    a power rail designed to be mounted in a loading position;
    a current collector, which is designed to be installed on top of an electric vehicle and comprises a current collector head and a current collector head drive mechanism, and which is designed to charge the electric vehicle by allowing the current collector head with the
    4/50
    21825-PCTAT
    Power rail is in contact;
    wherein in the loading position the power supply rail is arranged above the vehicle and on a side side of the vehicle; a plurality of power supply electrodes are integrated on one side surface of the power supply rail, and the plurality of power supply electrodes are spaced in an up and down direction and are parallel to each other;
    the current collector head drive mechanism is designed to drive the current collector head to have a vertical lifting stroke and a transverse movement stroke, and the current collector electrodes of the current collector head are arranged on an outside of the current collector head in a transverse movement direction and are arranged in parallel corresponding to the power supply electrodes.
    Preferably, the power pick-up head drive mechanism is a four-link mechanism comprising a base, an upper rod, a lower rod and a pull rod; the current collector head is arranged at an outwardly extending end of the upper rod; and in the vertical lifting stroke the tie rod is kept in a constant length; and in the transverse movement stroke, the drawbar is designed to extend and retract.
    Preferably, the tie rod is a telescopic tie rod with a telescopic control mechanism and has a fixed end hinged to the base and a telescopic end hinged to the upper rod.
    Preferably, the telescopic tie rod is an air cylinder which is provided with a preload pressure.
    [0017] The telescopic control mechanism preferably comprises:
    a fixed deflection roller which is arranged at a lower end of the drawbar;
    a fixed idler block disposed on a rotating shaft at a lower end of the lower rod;
    a movable pulley block, which is based on a movable
    5/50
    21825-PCTAT
    Mechanism is mounted;
    a steel cable wound around the fixed pulley and alternately wound around the fixed pulley block and the movable pulley block, the steel cable having one end connected to a hinged end of the upper rod on which the upper rod connects to the tie rod or a telescopic end of the drawbar is articulated and has another end connected to the base; and a cam fixed on the rotating shaft at the lower end of the lower rod so as to be coaxial with the rotating shaft, and the cam is configured to support the movable pulley block and to rotate the movable pulley block to tighten the steel cable or to loosen.
    Preferably, a driven idler roller is disposed on one side of the movable idler block and coaxial with the movable idler block, and the cam is engaged with the driven idler roller.
    [0019] A buffer spring is preferably arranged between the movable deflection roller block and the base.
    Preferably, the movable guide roller block is mounted swinging on the base via a swing frame.
    Preferably, the pull rod is an elastic pull rod, a body of the pull rod is provided with an elastic telescopic section in a length direction, and the elastic telescopic section is formed by a spring.
    Preferably, the power supply electrodes are arranged on an insulating substrate, an insulating section is arranged between every two adjacent power supply electrodes, the insulating section is higher than the undersides of the power supply electrodes and lower than the contact surfaces of the power supply electrodes, and the insulating section is parallel with a plurality of grooves the power supply electrodes.
    Preferably, the power supply rail is provided with a guide plate, and the guide plate is above the power supply electrodes and perpendicular to a plane
    6/50
    21825-PCTAT, in which the power supply electrodes are arranged.
    [0024] The current collection head preferably comprises:
    a connector assembly configured to connect the power pick-up drive mechanism;
    a side current collector assembly connected to the connector assembly via a rotary connector, the current collector electrodes being integrated on one side of the side current collector assembly; and a guide assembly connected to a pivot portion of the rotary connector and disposed over the connector assembly and / or the side power take-off assembly and having a roller component.
    Preferably, the connection arrangement is a spring suspension device, which comprises:
    a connection plate in which a left shaft hole and a right shaft hole are arranged;
    a movable support frame slidably connected to the link plate in an up and down direction by a left support shaft and a right support shaft; and a support spring disposed between the connection plate and the movable support frame, and the support spring having one end supported on the connection plate and another end supported on the movable support frame.
    Preferably, an adjusting screw is arranged on the connecting plate, and one end of the support spring is supported on the adjusting screw.
    Preferably, the rotary connector comprises:
    a support frame configured to connect the connector assembly; a current collector assembly mounting plate configured to install the side current collector assembly; and a universal connector with a fixed portion that mates with the
    7/50
    21825-PCTAT
    Support frame is connected, and a universal rotating section which is connected to the current collector assembly mounting plate.
    Preferably, the universal connector comprises a connecting shaft and a universal bearing, the connecting shaft has one end which is connected to the support frame and another end which is connected to an inner ring of the universal bearing by a shaft sleeve, and an outer ring of the universal bearing is connected to the current collector assembly mounting plate.
    Preferably, the loading system further includes an elastic recovery device disposed between the support frame and the current collector assembly mounting plate and configured to hold a position of the current collector assembly mounting plate with respect to the support frame.
    [0030] Preferably, the elastic recovery device comprises:
    first elastic support pins disposed above the universal connector on left and right sides in a horizontal direction and each having a fixed end connected to the support frame and a telescopic end supported on the current collector assembly mounting plate;
    second elastic support pins arranged under the universal connector on the left and right sides in the horizontal direction and each having a fixed end connected to the support frame and a telescopic end supported on the current collector assembly mounting plate; and third elastic support pins arranged in the longitudinal direction on the left and right sides and each having a fixed end connected to the support frame and a telescopic end which extends upwards and in a horizontal support position which corresponds to the telescopic End corresponds to, on which the current collector assembly mounting plate is supported.
    Preferably, the guide assembly includes a wheel disc support frame, and radial support arms that are extended outward are provided along a circumferential direction of the wheel disc support frame, an outgoing end of each of the support arms is included
    8/50
    21825-PCTAT is provided with a support disc, and a ball or roller that can roll freely is provided on top of each support disc.
    Preferably, the side current collector assembly is provided with an insulating separator, and each of the current collecting electrodes is mounted on the insulating separator by buffers at two ends of the current collecting electrode.
    Preferably, buffers of each of the current drain electrodes are connected by a first connecting rod and a second connecting rod, which are arranged symmetrically in a left and right direction; opposite ends of the first connecting rod and the second connecting rod are hinged to each other, another end of the first connecting rod and another end of the second connecting rod are hinged to the respective buffers, and a middle part of each of the first connecting rod and the second connecting rod is hinged to the insulating separator ,
    Preferably, one side of the insulating separator for mounting the electrodes is provided with transition plates which correspond to the current drain electrodes. In the present application, a plurality of power supply electrodes of the power supply rail are integrated on the vertical insulating substrate and distributed at intervals and in parallel to each other. In use, the power supply electrodes are located on one side of the charging position of the vehicle and are located above the vehicle and on the side of the vehicle. The current collector is mounted on the top of the vehicle in a direction perpendicular to a length direction of the vehicle body, and the current collector electrodes of the current collector head are mounted on the side surface of the current collector head in the transverse direction, thereby forming a side charging system for charging in the lateral position. In operation, after the electric vehicle has been parked, the power rail is located in a lateral position of the pantograph, and the movement of the pantograph head has a variable track that includes a vertical lifting movement and a transverse movement. The pantograph is first raised approximately vertically to a certain height (higher than 1500 mm)
    9/50
    21825-PCTAT is raised and then moves horizontally outward a certain distance (more than 600 mm) until the power take-off electrodes contact the power supply electrodes to achieve a power take-off function. Since the current collector head of the pantograph has a far-reaching horizontal movement function, the permissible maximum parking position deviation can be increased, which facilitates the operation of the vehicle. The power rail and the power pickup head have good electrical conductivity and reliable insulation performance to facilitate the accurate and stable positioning and power pickup of the power pickup head relative to the power supply rail while keeping a safe distance from the pedestrian, thereby improving charging performance while improving the safe and normal driving of the vehicle is ensured, which is why the charging system is particularly suitable for modern electric buses of the energy storage type.
    BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic view showing the structure of a pantograph
    Shows charging system of a conventional energy storage type electric bus;
    Figure 2 is a side view of Figure 1;
    Fig. 3 is a schematic view showing the structure of an embodiment of a charging system according to the present application;
    Fig. 4 is a schematic view showing the structure of a pantograph in Fig. 3;
    Figure 5 is a view of the design principle of the pantograph;
    Fig. 6 is a schematic view showing the structure of an embodiment of the pantograph in Fig. 5;
    Figure 7 is a partially enlarged view of positions of a fixed idler block and a movable idler block in Figure 6;
    Figure 8 is a reference side view showing the pantograph of Figure 6 in one
    10/50
    21825-PCTAT
    Shows state of use;
    Figure 9 is a view of another design principle of the pantograph;
    Figure 10 is a schematic view showing the lifting and transverse movement of the pantograph in Figure 9;
    Figure 11 is a schematic view showing the lowering of the pantograph in Figure 9;
    Figure 12 is a schematic view showing the structure of a power rail;
    Figure 13 is a side view of the power rail in Figure 12;
    Figure 14 is a top view of the power rail in Figure 12;
    Fig. 15 is a schematic front view showing an electrode surface of a current pickup head;
    Figure 16 is a left view of the current collector head in Figure 15;
    Figure 17 is a rear view of the current collector head in Figure 15;
    Figure 18 is a top view of the current collector head in Figure 15;
    Fig. 19 is a perspective view of the power pickup head in Fig. 15 as viewed from a rear side;
    Fig. 20 is a schematic half-sectional view showing a spring suspension device in Fig. 15;
    Figure 21 is a right view of the spring suspension device in Figure 20;
    Figure 22 is a schematic half-sectional view of a rotary connector in Figure 15;
    Figure 23 is a right view of the rotary connector in Figure 22; and Fig. 24 is a perspective view showing the current collecting head device in Fig. 15 viewed from a front side.
    11/50
    21825-PCTAT Reference numbers in FIGS. 1 and 2:
    Γ power supply rail,
    3 'current collector head.
    Reference numbers in FIGS. 3 to 24:
    I base, lower bar,
    4.1 lower tie rod,
    Current collector head, fixed deflection pulley, movable deflection pulley block,
    II swing frame, driven pulley,
    Power supply rail,
    Vehicle body,
    Feather;
    5-1 connection arrangement,
    5-121 left support shaft,
    5-12 movable support frame,
    5-14 linear bearing,
    5-2 side power take-off arrangement,
    5-22 buffers,
    5-221 telescopic shaft,
    5-24 transition plate,
    5-26 second connecting rod;
    5-3 rotary connector,
    5-32 connecting shaft,
    5-34
    5-35
    5-4
    5-42
    5-44
    5-23
    5-222
    5-25
    5-31
    5-33
    Current collection device mounting board,
    Shaft sleeve, 5-36
    Guide assembly 5-41
    Support arm 5-43
    Bullet;
    2 'pantograph, upper rod,
    Pull bar,
    4- 2 spring,
    Steel cable, fixed pulley block,
    Cam,
    Rotary shaft
    Buffer spring,
    Guide plate,
    Air cylinder,
    5- 11 connecting plate,
    5-122 right support shaft,
    5-13 adjusting screw,
    5-15 spring,
    5-21 insulating separator,
    Electrode,
    Housing, first connecting rod,
    Support frame,
    Universal stock,
    Guide assembly mounting plate,
    Radscheibenstützrahmen,
    Support disk,
    12/50
    21825-PCTAT
    5-51 first elastic support pin, 5-52 second elastic support pin, 5-53 third elastic support pin, 15-1 insulating substrate, 15-2 Power supply electrode, 15-3 insulating, 15-4 Groove.
    DETAILED DESCRIPTION In order that those skilled in the art can better understand the solution of the present application, the present application is described in detail with reference to the drawings and embodiments.
    [0063] The terms as above, below, inside and outside are defined herein based on the positional relationships shown in the drawings. According to the drawings, the corresponding positional relationships can be changed accordingly. For this reason, these terms are not to be understood as absolute restrictions on the scope of the present application.
    Reference is made to FIGS. 3 and 4. Figure 3 is a schematic view showing the structure of an embodiment of a charging system according to the present application; and FIG. 4 is a schematic view showing the structure of a pantograph in FIG. 3.
    The essence of the charging system provided by the present application is that a current collector is mounted perpendicular to a length direction of the vehicle body, a guide plate 16 (or a guide rail) and a power supply rail 15 are assembled and perpendicular to each other, the guide plate 16 is horizontally mounted on an upper end of the power supply rail 15, and the power supply rail 15 is mounted laterally. After being lifted vertically, the pantograph extends outward under the action of the guide plate 16 and then comes into contact with the side power supply rail 15 for power consumption.
    The loading system has an automatic guiding ability. The pantograph
    13/50
    21825-PCTAT can extend outward under the action of the guide plate 16 by a distance in the range of 0 mm to 700 mm, and a transverse swing size is increased, whereby the bus has a larger parking position deviation, which simplifies the difficulty of the operation for the driver. Meanwhile, a current collector head 5 of the current collector is mounted on a movable connector, which is why the current collector head 5 has a certain degree of freedom, and the wobbling of the vehicle body in the left and right direction can result in the movement of the current collector head 5 of the current collector in a direction up and down being transformed. The current collector head 5 always tends to move upward, and the guide plate 16 further limits the degree of freedom of the upward displacement of the current collector head 5, therefore the current collector head 5 is prevented from wobbling with the vehicle body, and thus the instability can the decrease in current caused by the wobbling of the vehicle body while the passengers get on and off is eliminated.
    [0067] Reference is made to FIG. 5 and FIG. 6. Figure 5 is a view of the design principle of the pantograph, and Figure 6 is a schematic view showing the structure of an embodiment of the pantograph in Figure 5.
    As shown in the figures, the current collector mainly consists of a base 1, an upper rod 2, a lower rod 3, a pull rod 4 and a current collector head 5 and the like. The base 1, the upper rod 2, the lower rod 3 and the pull rod 4 form a four-point linkage mechanism to drive the current collecting head 5 to move. The lower rod 3 has a lower end which is hinged to the base 1 via a rotating shaft and an upper end which is hinged to the upper rod 2. The pull rod 4 has a lower end which is articulated on the base 1 and an upper end which is articulated on a connecting lever at an outgoing end of the upper rod 2. The upper rod 2 is designed as a V-shaped frame structure in which an outwardly extending end of the V-shaped frame structure is narrow and another end is wide, which is why the upper rod 2 is also referred to as an upper frame.
    The pull rod 4 is a telescopic pull rod and it is as an air cylinder
    14/50
    21825-PCTAT with a preload pressure inside. A lower end of a cylinder body of the air cylinder is hinged to the base 1, and an upper end of a piston rod of the air cylinder is hinged to the upper rod 2. The current tapping head 5 is mounted on the outwardly extending end of the upper rod 2 via a universal bearing. A current draw part of the current collector head 5 is arranged on an outer side thereof in a transverse direction of movement of the current collector head 5, and a plurality of current collector electrodes of the current collector head 5 for the current collector are spaced upward and downward on an outer side surface of the current collector head 5 and are parallel to each other.
    Reference is also made to FIG. 7, which shows a partially enlarged view of positions of a fixed deflection roller block and a movable deflection roller block in FIG. 6.
    The pull rod 4 is provided with a telescopic control mechanism which is designed to release the pull rod 4 to allow the pull rod 4 to extend and retract when the current collector head 5 changes from a vertical lifting movement to an outward transverse movement and also lock the tie rod 4 to allow the tie rod 4 to have a constant length when the current collector head 5 is converted from an inward transverse movement to a vertical downward movement.
    The telescopic control mechanism consists mainly of a steel cable 6, a fixed deflection roller 7, a fixed deflection roller block 8, a movable deflection roller block 9 and a cam 10 and etc. The fixed deflection roller 7 is mounted on a lower end of the pull rod 4. The fixed pulley block 8 is mounted on a rotating shaft at a lower end of the lower rod 3. The movable pulley block 9 is mounted on the base 1 via a Y-shaped swing frame 11, and a lower end of the swing frame 11 is hinged to the base 1. The movable deflection roller block 9 is arranged in a groove at an upper end of the swing frame 11. The steel cable 6 has one end connected to an outer side of a link shaft of the upper rod 2 and the pull rod 4, and another end which is connected to the
    15/50
    21825-PCTAT
    Base 1 is connected. The steel cable 6 is wound around the fixed deflection roller 7 and then alternately around the fixed deflection roller block 8 and the movable deflection roller block 9. The section of the steel cable 6 above the fixed deflection roller 7 is parallel to the pull rod 4 to ensure that a pulling force of the steel cable has the same direction as a load direction of the pull rod, to enable the load formation to be more appropriate.
    The cam 10 is configured to rotate the position of the movable pulley block 9 via a cam surface of the cam 10, and is fixed to a rotating shaft 12 at the lower end of the lower rod 3 so as to be coaxial with the rotating shaft 12 , A driven deflection roller 13 is arranged on one side of the movable deflection roller block 9 and coaxial with the movable deflection roller block 9. The cam 10 is engaged with the driven pulley 13, and the driven pulley 13 of the movable pulley block 9 is supported on the cam 10. When rotated together with the rotary shaft 12, the cam 10 can drive the movable deflection roller block 9, tighten or loosen the steel cable 6.
    The driven pulley 13 can act to prevent dry friction when the cam 10 drives the movable pulley block 9 to move. It is also feasible for the cam 10 to drive the movable deflection roller block 9 directly, without the driven deflection roller 13 being provided in the process.
    In order to prevent a large impact from being caused when the steel cord 6 is released immediately after the cam 10 loosens the steel cord, a buffer spring 14 is provided between one side of the movable pulley block 9 and the base 1.
    [0076] Reference is made to FIG. 8, which is a reference side view showing the
    Current collector of Figure 6 shows in a state of use.
    As shown in Figure 8, in practical use, a power supply device is mounted at a charging location, generally a bus station, and a power supply rail 15 of the power supply device is mounted vertically at a position to the side of a vehicle and above the vehicle.
    16/50
    21825-PCTAT
    A plurality of power supply electrodes are spaced apart in the upward and downward directions and parallel to each other, and an arrangement of the plurality of power supply electrodes corresponds to the arrangement of electrodes of the power takeoff head 5. Each of the power supply electrodes has a length greater than a length of each of the power pickup electrodes of the power pickup head 5 to allow the power pickup head 5 to contact the power supply rails 15 within a wide range in the forward and backward direction when the vehicle retracts. Each of the power supply electrodes does not have a width larger than a width of each of the power pickup electrodes of the power pickup head 5 to improve the power pickup stability. A guide plate 16 (or a guide rail) is mounted horizontally above the power supply rail 15 so as to be perpendicular to a plane in which the power supply rail is arranged, and is designed to limit the degree of freedom of the power pickup head 5 in the vertical direction after the current collector head 5 has been raised to a certain height to stop the current collector head 5 from moving further upwards and to drive the current collector head 5 instead to make an outward transverse movement. The guide plate 16 can be designed as a flat steel plate and the like. The side pantograph is mounted on a roof of the vehicle and perpendicular to a length direction of the vehicle body 17. A lifting plane of the four-point link mechanism and the transverse direction of movement of the current collector head are both perpendicular to the length direction of the vehicle body 17.
    When the vehicle retracts and the current collector head 5 of the pantograph must come into contact with the power supply rail 15, the rotary shaft 12 is rotated by a combined action of an air cylinder 18 and a spring 19. Since a convex part of the cam 10 is engaged with the driven idler roller 13 of the movable idler block 9, the movable idler block 9 does not act when the rotary shaft 12 is initially rotated through a certain angle (such as 0 degrees to 30 degrees), thereby reducing the Length of the steel cable 6 is constant. An air pressure is always given in the air cylinder of the pull rod 4, a tensile force caused by the steel cable 6 on the
    17/50
    21825-PCTAT
    Air cylinder is applied is greater than the pressure in the air cylinder, and the air cylinder is kept at a constant length. For this reason, the current collecting head 5 is raised approximately vertically in a vertical plane perpendicular to the length direction of the vehicle body.
    If the current collector head 5 is raised to a height of approximately 1500 mm, the current collector head 5 is supported on a lower surface of the guide plate 16 via a slide roller on top of the current collector head 5. In this case, the cam 10 is driven by the rotary shaft 12 to rotate through an angle of more than 30 degrees, and a non-convex part of the cam 10 starts to engage the driven pulley 13 of the movable pulley block 9. Under the pulling action of the steel cable 6, the movable deflection roller block 9 swings together with the oscillating frame 11 towards the fixed deflection roller block in order to release the steel cable 6. Since the steel cable 6 is released, a tensile force applied by the steel cable 6 to the air cylinder is eliminated, whereby the air cylinder can expand linearly under the action of air pressure to achieve the function of a telescopic pull rod. In this case, the current collector head 5 is restricted by the guide plate 16 from rising further upwards, the pull rod 4 changes its length automatically, and the current collector head 5 can move outwards by 0 mm to 700 mm in the vertical plane perpendicular to the longitudinal direction of the vehicle body move transversely until it comes into contact with the power supply rail 15 of the power supply device for power consumption. After charging is complete, the pantograph is retracted to a folded state by performing a reverse action. During the pantograph retraction process, the preload pressure in the air cylinder may allow the tie rod to retract automatically when the pantograph head 5 is lowered.
    The steel cable is wound in several rotations around the fixed deflection roller block 8 and the movable deflection roller block 9, and according to the principle of the stroke reinforcement of the movable deflection rollers, a gain factor is related to the number of fixed deflection rollers and to movable deflection rollers. If the gain factor is N, after the movable deflection roller block 9 turns to
    18/50
    21825-PCTAT fixed pulley block 8 moved by a distance of L, the steel cable to be released by a length of LxN. Thus, a small movement of the movable deflection roller block 9 can loosen or pull the steel cable exactly by a sufficient length to meet the requirement of extending and retracting the pull rod 4.
    In addition to being mounted on the base 1 by the swing frame 11, the movable idler block 9 on the base 1 can also be mounted by other movable mechanisms such as a straight line movement mechanism. For example, two ends of the movable pulley block 9 are mounted on slide rails, therefore the movable pulley block 9 can move on the slide rails under the action of the cam 10 and the tensile force of the steel cable 6, and the functions of releasing and retracting the steel cable 6 can also be achieved. This means that the movable deflection roller block 9 can be mounted in any way as long as the movable deflection roller block 9 can move away from and towards the fixed deflection roller block 8.
    It is apparent to a pull rod that requires a telescopic control mechanism that the telescopic control mechanism of the pull rod in the following shapes can be made with a steel cable, pulleys and the cam in addition to the above structural shape.
    One form is electrical control. The telescopic function of the air cylinder type pull rod can be locked or released by inserting a lock pin between the air cylinder body and the piston rod, or by withdrawing the lock pin from the air cylinder body and the piston rod, and the lock pin is controlled by a small motor, an air cylinder or one electromagnetic mechanism. An angle sensor or a stroke switch can be mounted on the four-point connection mechanism in order to control an operating torque of the locking pin. When the power take-off head 5 is raised to a certain height, the angle sensor issues an angle signal to operate the lock pin, and alternatively, a rod of the four-point link mechanism triggers the stroke switch to further operate the lock pin.
    19/50
    21825-PCTAT Another form is a mechanized controller. Since the relative positions between the rods are constantly changed in one lifting operation, the telescopic moment of the pull rod 4 can be controlled according to an angular variation of the upper rod with respect to the pull rod 4.
    For example, the telescopic function of the air cylinder type pull rod is still locked or released by inserting the lock pin between the air cylinder body and the piston rod or by pulling the lock pin out of the air cylinder body and the piston rod. Unlike the above electrical control mode, in the mechanized control mode, the upper rod 2 is directly provided with a trigger block or a trigger board in cooperation with the locking pin or connected to a locking pin via a gear mechanism. Thus, when the power take-off head 5 is raised to a certain height, the trigger block or board can drive a pin shaft to extend outward directly or through the gear mechanism to unlock the air cylinder and piston rod. If the power take-off head 5 has to be lowered, the trigger block or the trigger board can drive the pin shaft to move inwards directly or via the gear mechanism in order to lock the air cylinder and the piston rod again.
    In addition to the air cylinder, the pull rod can also be designed in other forms, e.g. as an elastic tie rod.
    Reference is made to FIGS. 9 to 11. Figure 9 is a view of another design principle of the pantograph, Figure 10 is a schematic view showing the lifting and transverse movement of the pantograph in Figure 9, and Figure 11 is a schematic view showing the pantograph lowering in Figure 9.
    As shown in the figures, the pull rod 4 is an elastic pull rod which is formed by a lower pull rod 4-1 and a spring 4-2 which are butt-connected to one another. The spring 4-2 is arranged on an upper side and articulated on the upper rod 2. The lower tie rod 401 is arranged on a lower side and articulated on the base 1. The specification of the spring 4-2 can be determined by a force which by the
    20/50
    21825-PCTAT
    Drawbar is carried while the current collector head is raised to ensure that the spring 4-2 has a constant length when the current collector head is raised or lowered vertically, and it can extend and retract when the current collector head moves transversely. In this implementation, a limit on the telescopic characteristic of the spring is controlled by calculating a value of the force, and for this reason, no telescopic control mechanism has to be provided for the pull rod, which is a simple embodiment of the present application.
    It is apparent that the position of the lower tie rod 4-1 and the position of the spring 4-2 can be exchanged as required, i.e. the pull rod 4 can be installed upside down. Or the elastic tie rod is formed by two tie rods and a spring which are butt-connected, the two tie rods are arranged at two ends, and the spring is arranged in the middle. Or the elastic pull rod is formed by two springs and a pull rod which are butt-connected, the two springs are arranged at two ends and the pull rod is arranged in the middle. Or the elastic pull rod is formed by several springs and several pull rods, which are alternately butt-connected.
    In addition to this, as another form of the pull rod 4, the pull rod 4 may be formed by two rod sections assembled via a telescopic structure, a spring is arranged between the two rod sections, and a biasing pressure is provided by the spring, which is also a function similar to that of the air cylinder type pull rod.
    [0091] Reference is made to FIGS. 12 to 14. Fig. 12 is a schematic view showing the structure of a power rail, Fig. 13 is a side view of the power rail in Fig. 12, and Fig. 14 is a plan view of the power rail in Fig. 12.
    As shown in the figures, an insulating substrate 15-1 of the power rail 15 is made of an insulating material, and is a whole piece of an insulating board. Since the insulating substrate 15-1 must be arranged vertically in use, it is
    21/50
    21825-PCTAT defines the insulating substrate 15-1 herein as a vertical insulating substrate. Mounting interfaces for the power supply electrodes 15-2 are distributed on the insulating substrate 15-1. The power supply electrodes 15-2 are made of a conductive material, and four electrodes are integrated on the insulating substrate 15-1.
    The four power supply electrodes 15-2 are a positive electrode, a negative electrode, a ground electrode and a signal electrode, respectively, arranged in intervals from top to bottom on a board surface on one side of the insulating substrate 15-1 in the order listed and in parallel to each other. The power supply electrodes 15-2 have the same lengths, and the contact surfaces of the power supply electrodes 15-2 are arranged in the same vertical plane. The power supply electrodes 15-2 extend a certain distance beyond the insulating substrate 15-1 on one side in the length direction of the insulating substrate 15-1.
    It is apparent that the signal electrode can be omitted as required, and only the three electrodes including the positive electrode, the negative electrode, and the ground electrode are indispensable.
    A convex insulating portion 15-3 is arranged between all two adjacent power supply electrodes 15-2. The insulating portion 15-3 and the insulating substrate 15-1 are integrally formed. The insulating portions 15-3 are higher than the undersides of the power supply electrodes 15-2 and lower than the contact areas of the power supply electrodes 15-2. Each of the insulating portions 15-3 has four grooves 15-4 in parallel with the power supply electrodes 15-2. The grooves 15-4 extend beyond the undersides of the power supply electrodes 15-2 to increase a creepage distance between the power supply electrodes 15-2. Obviously, the grooves 15-4 can also be viewed as being formed by several parallel ribs according to the figures.
    As described above, a guide plate 16 is further provided on the support frame of the power rail 15 to restrict the degree of freedom of the power pickup head 5 in the vertical direction. The guide plate 16 is above the
    22/50
    21825-PCTAT
    Power supply electrodes 15-2 arranged and perpendicular to the insulating substrate 15-1. The guide plate 16 may be directly connected to the insulating substrate 15-1 to be perpendicular to the insulating substrate 15-1, or it may be connected to other parts (e.g. the support frame), and the guide plate 16 is only perpendicular in one mounting position the insulating substrate 15-1.
    Reference is made to FIGS. 15 to 19. Figure 15 is a schematic front view showing an electrode surface of the current collector head, Figure 16 is a left view of the current collector head in Figure 15, Figure 17 is a rear view of the current collector head in Figure 15, Figure 18 is a plan view of the current collector head in Figure 15, and Figure 19 is a perspective of the current collector head in Figure 15 viewed from a rear side.
    The current pick-up head consists mainly of parts, comprising a connection arrangement 5-1, a side current collection arrangement 5-2, a rotary connector 5-3 and a guide arrangement 5-4. These parts are bolted together in order to form a unit.
    The connection arrangement 5-1 is designed to mount the entire current collector head device on a drive mechanism (e.g. the four-point connection mechanism) of the current collector. The side power take-off assembly 5-2 is connected to the connection assembly 5-1 through the rotary connector 5-3. The guide assembly 5-4 is connected to a rotary portion of the rotary connector 5-3 and is disposed over the connector assembly 5-1 and the side current collector assembly 5-2, and has a roller component.
    Since the side power take-off assembly 5-2 is also connected to the rotating portion of the rotary connector 5-3, in operation the guide assembly 5-4 and the side power take-off assembly 5-2 rotate together with respect to the connection assembly 5-1. For this reason, the guide arrangement 5-4 can also be installed on the side current collector arrangement 5-2, which has the same effect as the case
    23/50
    21825-PCTAT that the guide assembly 5-4 directly on the rotary section of the rotary connector
    5-3 is installed. The installation position of the guide assembly 5-4 can be determined according to practical requirements such as the size of the components and the layout space.
    Reference should also be made to FIG. 20 and FIG. 21. Fig. 20 is a schematic half-sectional view showing a spring suspension device in Fig. 15, and Fig. 21 is a right view of the spring suspension device in Fig. 20.
    The connector assembly 5-1 is also a connector component for installing the current collector head on the current collector. The connection arrangement 5-1 is designed as a spring suspension device which mainly consists of a connection plate 5-11 and a movable support frame 5-12, which are connected by a support shaft.
    The connection plate 5-11 is provided with a bolt hole for connecting the drive mechanism of the current pickup head, and with a longitudinal left shaft sleeve and a longitudinal right shaft sleeve on a side facing the electrodes. A left support shaft 5-121 and a right support shaft 5-122 of the movable support frame 5-12 are installed in the left shaft sleeve and the right shaft sleeve of the connection plate 5-11, respectively. Two ends of each of the support shafts are fixed to the movable support frame 5-12 by lock nuts, a linear bearing 5-14 is provided between a left shaft hole and the left support shaft, and another linear bearing 5-14 is provided between a right shaft hole and the right support shaft whereby the sliding connection between the movable support frame 5-12 and the connection plate 5-11 is provided in the up and down direction, and the movable support frame 5-12 can be in an axial direction of the support shaft with respect to the connection plate 5-11 be moved.
    A cylindrical compression spring 5-15 is further mounted between the connecting plate 5-11 and the movable support frame 5-12. The spring 5-15 has one end which acts on an adjusting screw 5-13 of the connecting plate 5-11 and another end which acts on the
    24/50
    21825-PCTAT movable support frame 5-12 acts on. The height for mounting the adjustment screw 5-13 can be adjusted to provide a suitable spring force so that some cushioning can be provided by the inner spring 5-15 when the current pickup head hits a roof of the charging station when the current pickup head is raised to prevent damage to the current collector head caused by a large impact force.
    Reference is made to FIG. 22 and FIG. 23. FIG. 22 is a schematic half-sectional view of the rotary connector in FIG. 15, and FIG. 23 is a right view of the rotary connector in FIG. 22.
    The rotary connector 5-3 acts to allow the side current collector assembly 5-2 to have a multidirectional degree of freedom of rotation. The rotary connector 5-3 uses a universal bearing axis mechanism and is provided with a spring restoration device.
    The rotary connector 5-3 mainly consists of a support frame 5-31, a connecting shaft 5-32, a universal bearing 5-33 and a current collector assembly mounting plate 5-34, which are connected together. One end of the connection shaft 5-32 is threaded and is designed to connect to the support frame 5-21, and a lock nut is installed to lock the connection shaft 5-32 with respect to the support frame 5-21. Another end of the connecting shaft 5-32 is provided with a step and is designed to connect to an inner ring of the universal bearing 5-33 through a shaft sleeve 5-35. An outer ring of the universal bearing 5-33 is connected to the current collector assembly mounting plate 5-34 by a bolt.
    The guide arrangement 5-4 is designed in the form of a wheel disc. Six radial support arms 5-42, which extend outward, are arranged along a circumferential direction of a wheel disk support frame 5-41 of the guide arrangement 5-4. A tapered end of each of the support arms 5-42 is provided with a support washer 5-43, the support washer 5-43 has an upper surface in the form of an upward arc, and a ball 5-44
    25/50
    21825-PCTAT (or a roll) that can roll freely are recorded at the highest middle position of the top of the support disc 5-43. A guide assembly mounting plate that extends rearward and in the form of a cantilever is connected to the center of the top of the current collector assembly mounting plate 5-34 by a bolt. The wheel disc support frame 5-41 is mounted over the guide assembly mounting plate 5-36. The wheel disc can cooperate with the roof to limit the heights of the current collection electrodes, and can also slide through the balls along the roof towards the charging electrodes.
    A spring restoration device is further mounted on the support frame 5-31. First elastic support pins 5-51 of the spring restoration device are arranged in positions above the universal bearing on left and right sides in a horizontal direction, and each of the first elastic support pins 5-51 has a fixed end connected to the support frame 5-31, and a telescopic end supported on the current collector assembly mounting plate 5-34. Second elastic support pins 5-52 of the spring restoration device are arranged in positions under the universal bearing on the left and right sides in the horizontal direction, and each of the second elastic support pins 5-52 has a fixed end connected to the support frame 5-31. and a telescopic end supported on the current collector assembly mounting plate 5-34. Third elastic support pins 5-53 of the spring restoration device are arranged in the longitudinal direction on the left and right sides, and each of the third elastic support pins 5-53 has a fixed end connected to the support frame 5-31 and a telescopic end that extends upward and is seated in a horizontal support position corresponding to the telescopic end on a corresponding side of the two sides of the guide assembly mounting plate 5-36.
    The spring recovery device acts to allow the side power take-off assembly 5-2 to be restored to an initial position with respect to the support frame 5-31 when the wheel disc is not in contact with the roof of the charging station and the side power take-off assembly 5- 2 not with the
    26/50
    21825-PCTAT
    Charging electrodes is in contact, i.e. when no external force is applied to the side current collector assembly 5-2.
    The current collector head, which is designed to accommodate the universal spherical axis, can ensure that the electrodes have multidirectional degrees of freedom to ensure a more stable connection between the electrodes and the charging electrodes, as well as a high-quality current collector. In addition, the spring restoration device enables the current collecting head to be kept in an initial state when it is not operating, thereby compensating for an error of the universal ball axis.
    Reference is made to FIG. 24, which is a perspective showing the current collecting head device in FIG. 15 when viewed from a front side.
    As shown in FIG. 24, the side power take-off device 5-2 mainly consists of an insulating separator 5-21, a buffer 5-22 and a power take-off electrode 5-23, which are connected. The side current collector assembly 5-2 is a component that enables the current collector head to contact the charging electrodes to transmit current. The insulating separator 5-21 between the side power take-off assembly 5-2 and the rotary connector 5-3 ensures insulation performance of the current collector and the vehicle body of the energy storage type bus. A threaded sleeve is pre-embedded in the isolating partition 5-21 to enable the isolating partition 5-21 to be connected to the current collector assembly mounting plate 5-34 of the rotary connector 5-3 by a bolt.
    The number of current sink electrodes 5-23 is four, and the four current sink electrodes 5-23 are each a positive electrode, a negative electrode, a ground electrode, and a signal electrode. The signal electrode is an optional configuration and the remaining three electrodes are necessary configurations, in operation a charging current flows in through the positive electrode and flows through a high voltage cable and a bus power storage power supply and then flows
    27/50
    21825-PCTAT beyond the negative electrode to form a charge loop. The grounding electrode is connected to a frame structure of the pantograph and the vehicle body of the bus of the energy storage type in order to implement the grounding protection.
    The current drain electrodes 5-23 are made of a conductive material. Four current pickup electrodes are integrated on the insulating partition 5-21, and are sequentially spaced from top to bottom on a plate surface on an outside of the insulating partition 5-21 and parallel to each other. The current collector electrodes have the same lengths, and the contact surfaces of the current collector electrodes are arranged in the same vertical plane.
    Current-taking electrodes extend beyond the insulating separator 5-21 by a certain distance on one side in the length direction of the insulating separator 5-21.
    [0116] Two buffers 5-22 are each mounted between a current sink electrode 5-23 and the insulating separator 5-21 to provide some buffering when the current sink electrode 5-23 comes into contact with the charging electrode. Each of the buffers 5-22 comprises a telescopic shaft 5-221, a housing 5-222 and a spring (which is shielded and not shown in the figure), which is arranged inside the housing 5-222 and designed to elastically extend the telescopic shaft 5 -221 to connect to the housing 5-222. The housing 5-222 is connected to a rear side of the power take-off electrode 5-23, and the telescopic shaft 5-221 is connected to the insulating separator 5-21.
    Four transition plates 5-24 are bolted at intervals on the insulating partition 5-21, and the buffers 5-22 are bolted to the transition plates 5-24, respectively. Two buffers of each electrode are connected by two connecting rods. Opposing ends of a first connecting rod 5-25 and a second connecting rod 5-26 are hinged to each other, and another end of the first connecting rod 5-25 and another end of the second connecting rod 5-26 are hinged to the respective buffers 22, and a middle part each of the first connecting rod 5-25 and the second connecting rod 5-26 is hinged to the transition plate 5-24. The
    28/50
    21825-PCTAT two buffers 5-22 are connected by a connection mechanism that can implement synchronous buffering and prevent blockage errors that are caused when uneven forces are absorbed.
    The use of the insulating separator 5-21 solves the problem of electrically isolating the current pickup head, making the structure simpler, so that the current pickup head can be made smaller and easier. The spring shock absorbing structures are used on two portions of the current collector head, which prevents structure failure caused by an impact, thereby greatly increasing or increasing the reliability and service life of the current collector head.
    The charging system according to the present application is described in detail hereinbefore. The principle and embodiments of the present application are illustrated herein by specific examples. The above description of the examples is only intended to help understand the core concept of the present application. It should be noted that some of the modifications and improvements to the present application can be made by those skilled in the art without departing from the principle of the present application, and these modifications and improvements are intended to be within the scope of the present application, such as this defined by the claims.
    权利要求:
    Claims (22)
    [1]
    claims:
    1. Charging system that includes:
    a power rail designed to be mounted in a loading position; and a current collector that is designed to be installed on top of an electric vehicle and includes a current collector head and a current collector head drive mechanism and that is designed to charge the electric vehicle by allowing the current collector head to be in contact with the power supply rail, wherein in the loading position the power supply rail is arranged above the vehicle and on a side side of the vehicle; a plurality of power supply electrodes are integrated on one side surface of the power supply rail, and the plurality of power supply electrodes are spaced in an up and down direction and are parallel to each other; and the current collector head drive mechanism is configured to drive the current collector head to have a vertical lifting stroke and a transverse movement stroke, and the current collector electrodes of the current collector head are arranged on an outside of the current collector head in a transverse movement direction and are arranged in parallel corresponding to the power supply electrodes.
    [2]
    2. The charging system of claim 1, wherein the power pick-up head drive mechanism is a four-link mechanism including a base, an upper bar, a lower bar, and a pull bar; the current collector head is arranged at an outwardly extending end of the upper rod; and in the vertical lifting stroke the tie rod is held at a constant length; and in the transverse movement stroke the drawbar is designed to extend and retract.
    [3]
    3. Loading system according to claim 2, wherein the pull rod is a telescopic pull rod with a telescopic control mechanism and an end which is hinged to the base, and
    30/50
    21825-PCTAT has a telescopic end hinged to the upper rod.
    [4]
    4. Loading system according to claim 3, wherein the telescopic tie rod is an air cylinder which is provided with a preload pressure.
    [5]
    5. The loading system of claim 3, wherein the telescopic control mechanism comprises: a fixed idler pulley located at a lower end of the drawbar;
    a fixed idler block disposed on a rotating shaft at a lower end of the lower rod;
    a movable idler block mounted on the base via a movable mechanism;
    a steel cable wound around the fixed pulley and alternately wound around the fixed pulley block and the movable pulley block, the steel cable having one end connected to a hinged end of the upper rod on which the upper rod connects to the tie rod or a telescopic end of the drawbar is articulated and has another end connected to the base; and a cam attached to the rotating shaft at the lower end of the lower rod so as to be coaxial with the rotating shaft, and the cam is configured to support the movable pulley block and to rotate the movable pulley block to tighten the steel cable or loosen up.
    [6]
    6. Loading system according to claim 5, wherein a driven pulley is arranged on one side of the movable pulley block and is coaxial with the movable pulley block and the cam is engaged with the driven pulley.
    [7]
    7. Loading system according to claim 5, wherein a buffer spring is arranged between the movable guide roller block and the base.
    [8]
    8. Loading system according to claims 5, 6 or 7, wherein the movable
    31/50
    21825-PCTAT
    Deflection pulley block is mounted swinging on the base via a swing frame.
    [9]
    9. Loading system according to claim 2, wherein the pull rod is an elastic pull rod, a body of the pull rod is provided with an elastic telescopic section in a length direction and the elastic telescopic section is formed by a spring.
    [10]
    10. The charging system according to claim 1, wherein the power supply electrodes are arranged on an insulating substrate, an insulating section is arranged between every two adjacent power supply electrodes, the insulating section is higher than the undersides of the power supply electrodes and lower than contact areas of the power supply electrodes, and the insulating section is provided with a plurality of grooves is provided in parallel with the power supply electrodes.
    [11]
    11. The charging system according to claim 1, wherein the power supply rail is further provided with a guide plate, and the guide plate is arranged above the power supply electrodes and is perpendicular to a plane in which the power supply electrodes are arranged.
    [12]
    12. The charging system of claim 1, wherein the power pickup head comprises:
    a connector assembly configured to connect the power pick-up drive mechanism;
    a side current collector assembly connected to the connector assembly via a rotary connector, the current collector electrodes being integrated on one side of the side current collector assembly; and a guide assembly connected to a pivot portion of the rotary connector and disposed over the connector assembly and / or the side power take-off assembly and having a roller component.
    [13]
    13. The loading system of claim 12, wherein the connection assembly is a spring suspension device comprising:
    32/50
    21825-PCTAT a connecting plate in which a left shaft hole and a right shaft hole are arranged;
    a movable support frame slidably connected to the link plate in an up and down direction by a left support shaft and a right support shaft; and a support spring disposed between the connection plate and the movable support frame, and the support spring having one end supported on the connection plate and another end supported on the movable support frame.
    [14]
    14. Loading system according to claim 13, wherein an adjusting screw is arranged on the connecting plate and one end of the support spring is supported on the adjusting screw.
    [15]
    15. The loading system of claim 12, wherein the pivot connector comprises: a support frame configured to connect the connector assembly; a power take-off assembly mounting plate designed to mount the side
    Install current collector assembly; and a universal connector having a fixed portion connected to the support frame and a universal rotating portion connected to the current collector assembly mounting plate.
    [16]
    16. The loading system according to claim 15, wherein the universal connector comprises a connecting shaft and a universal bearing, the connecting shaft having one end that is connected to the support frame and another end that is connected to an inner ring of the universal bearing by a shaft sleeve and one Outer ring of the universal bearing is connected to the current collector assembly mounting plate.
    [17]
    17. The loading system of claim 15, further comprising an elastic recovery device disposed between the support frame and the current collector assembly mounting plate and configured to a position
    33/50
    21825-PCTAT to hold the current collector assembly mounting plate with respect to the support frame.
    [18]
    18. The loading system of claim 17, wherein the elastic recovery device comprises:
    first elastic support pins disposed above the universal connector on left and right sides in a horizontal direction and each having a fixed end connected to the support frame and a telescopic end supported on the current collector assembly mounting plate;
    second elastic support pins arranged under the universal connector on the left and right sides in the horizontal direction and each having a fixed end connected to the support frame and a telescopic end supported on the current collector assembly mounting plate; and third elastic support pins arranged in the longitudinal direction on the left and right sides, each having a fixed end connected to the support frame and a telescopic end extending upward and in a horizontal support position corresponding to the telescopic end is supported on the current collector assembly mounting plate.
    [19]
    19. The loading system according to claim 12, wherein the guide assembly includes a wheel disc support frame and radial support arms extending outward are provided along a circumferential direction of the wheel disc support frame, an outgoing end of each of the support arms is provided with a support disc, and a ball or a roller that can run freely, are provided on top of each support disc.
    [20]
    20. The charging system according to claim 12, wherein the side current collecting assembly is provided with an insulating separator, and each of the current collecting electrodes is mounted on the insulating separating element by buffers at two ends of the current collecting electrode.
    [21]
    The loading system of claim 20, wherein the buffers are each of the
    34/50
    21825-PCTAT
    Power take-off electrodes are connected by a first connecting rod and a second connecting rod, which are arranged symmetrically in a left and right direction; the opposite ends of the first connecting rod and the second connecting rod are hinged to each other, another end of the first connecting rod and another end of the second connecting rod are hinged to the respective buffers, and a middle part of each of the first connecting rod and the second connecting rod is hinged to the insulating separator is.
    [22]
    22. Current collector head device according to claim 20 or 21, wherein one side of the insulating separating element for mounting the electrodes is provided with transition plates which correspond to the current collector electrodes.
    类似技术:
    公开号 | 公开日 | 专利标题
    AT520874A2|2019-08-15|charging system
    AT520873A2|2019-08-15|Lateral pantograph and electric vehicle
    EP0011250A1|1980-05-28|Vehicle for loading and transporting heavy loads, especially motor vehicles
    EP1864834B1|2010-06-23|Articulated vehicle composed of several coupled vehicle sections
    AT520871A2|2019-08-15|Trackable pantograph and electric vehicle
    DE102004052067A1|2005-06-09|Battery change system for a truck
    DE19641254A1|1998-04-16|Electric powered commercial vehicle
    AT520872A2|2019-08-15|Pantograph head unit
    DE102015217380A1|2017-03-16|Positioning unit for a charging station and method for contacting
    DE60310787T2|2007-10-11|Independent wheel module and vehicle using such a module
    DE102011002334A1|2012-10-31|Current collector system for vehicle, has current collector carriage that is arranged on outer arm, which is displaced by pivoting arms transversely to direction of travel of vehicle from standby position to engaged position
    DE10361322B4|2006-07-06|Lift used for vehicle maintenance
    DE1605068C3|1975-10-23|Tractor for use on rail and road
    DE102019112498A1|2019-12-24|VEHICLE FLOOR LIFT
    DE102015016679A1|2017-06-22|Abrolltransporteinrichtung, in particular hookloaders, as well as transport unit with a Wechselladerfahrzeug and a Abrolltransporteinrichtung
    EP2792515B1|2021-12-01|Vehicle system for the transport of goods by rail and by road, conversion set for converting a rail vehicle to a vehicle system for the transport of goods by rail in rail mode and on the road in road mode, and conversion method
    EP0429033B1|1994-08-10|Aircraft passenger stairs
    DE2325074A1|1973-12-06|Beak wagon
    DE202010016056U1|2011-03-17|Mast with a movable carriage and a utility on this
    DE4024825C1|1991-10-02|Support legs for semi-trailer - has inner tube sections with supports for feet which pivot
    EP2412600B1|2012-09-05|Roof joint for an articulated vehicle
    EP2358486B1|2014-03-26|Car and method for transporting a drive spindle for a roller of a roll stand
    DE102018122952A1|2019-10-24|Storage and retrieval unit
    DE102009040204B4|2013-11-07|Chassis device with an axle lift unit
    EP3838635A1|2021-06-23|Levelling device
    同族专利:
    公开号 | 公开日
    WO2016201901A1|2016-12-22|
    AT520874A8|2019-11-15|
    CN104901382A|2015-09-09|
    CN104901382B|2018-08-03|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP3608407B2|1998-12-04|2005-01-12|住友金属工業株式会社|Power supply to the carriage, auxiliary cart for reception and power supply, reception method|
    CN1321015C|2005-11-11|2007-06-13|中国人民解放军国防科学技术大学|Lateral current collector|
    CN101580023B|2009-06-18|2011-02-02|上海交通大学|Single pole rotation type public transportation trolley bus trolley-pole|
    WO2013124996A1|2012-02-22|2013-08-29|株式会社日立エンジニアリング・アンド・サービス|Pantograph device for trolley-type truck|
    CN104540705B|2012-05-31|2016-10-19|株式会社日立电力解决方案|The pantograph device of stringing formula truck|
    CN104859455B|2015-06-16|2017-09-08|中车株洲电力机车有限公司|A kind of trolley head device|
    CN104890520B|2015-06-16|2018-02-23|中车株洲电力机车有限公司|A kind of lateral current collector and electric vehicle|
    CN104901382B|2015-06-16|2018-08-03|中车株洲电力机车有限公司|A kind of charging system|
    CN104859456B|2015-06-16|2017-08-18|南车株洲电力机车有限公司|One kind becomes track pantagraph current collector and electric vehicle|CN104859455B|2015-06-16|2017-09-08|中车株洲电力机车有限公司|A kind of trolley head device|
    CN104901382B|2015-06-16|2018-08-03|中车株洲电力机车有限公司|A kind of charging system|
    CN105391135B|2015-12-15|2019-03-15|郑州宇通客车股份有限公司|A kind of charging rack and the charging unit using the charging rack|
    CN105967105B|2016-06-27|2018-09-18|上海振华港机(集团)宁波传动机械有限公司|AGV automatic charge devices|
    DE102016211746A1|2016-06-29|2018-01-04|Siemens Aktiengesellschaft|motor vehicle|
    CN106160088B|2016-07-21|2019-04-05|谢镕安|Platform formula charging system|
    CN106108511A|2016-08-18|2016-11-16|无锡飞达纺织印染机械有限公司|A kind of textile showing stand|
    US20200235522A1|2017-07-19|2020-07-23|Hangzhou Hikrobot Technology Co., Ltd.|Alignment mechanism, charging device and charging system for automatic charging|
    CN208855445U|2018-08-01|2019-05-14|比亚迪股份有限公司|The earthing or grounding means of vehicle and the conducting system of vehicle|
    CN109263479B|2018-10-22|2020-09-22|中车株洲电力机车有限公司|Trolley bus power receiving system|
    CN110850245A|2019-11-19|2020-02-28|国网浙江平湖市供电有限公司|Cubical switchboard partial discharge analogue means based on automatic control|
    EP3828024A1|2019-11-28|2021-06-02|ABB Power Grids Switzerland AG|Electrical vehicle comprising an energy transfer device|
    CN112848901A|2019-11-28|2021-05-28|比亚迪股份有限公司|Current collector|
    CN112848902A|2019-11-28|2021-05-28|比亚迪股份有限公司|Current collector|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    CN201510333427.8A|CN104901382B|2015-06-16|2015-06-16|A kind of charging system|
    PCT/CN2015/095663|WO2016201901A1|2015-06-16|2015-11-26|Charging system|
    [返回顶部]