CN117227668A - Vehicle position adjusting device trades - Google Patents

Abstract

The application discloses a position adjusting device of a battery changing vehicle, which is arranged in a battery changing channel of a battery changing station and comprises a driving mechanism and a transmission mechanism, wherein a power output end of the driving mechanism is connected with the transmission mechanism, so that the transmission mechanism acts on the battery changing vehicle to adjust the position or the angle of the battery changing vehicle, and the vehicle body of the battery changing vehicle is parallel to the length direction of the battery changing channel. The vehicle position adjusting device for the battery pack and the vehicle body can drive the transmission mechanism to move through the driving mechanism to realize automatic position adjustment of the battery pack and the vehicle body, can save manual operation, improves the accuracy and efficiency of vehicle position adjustment, is friendly to drivers with different degrees of driving skills, does not need to repeatedly adjust the vehicle position, provides more convenient conditions for the vehicle power change, realizes relative position matching of the battery pack and the vehicle body, easily realizes the disassembly and assembly process of the battery pack and the vehicle body, and improves the power change efficiency.

Description

Vehicle position adjusting device trades

The present application claims priority from chinese patent application CN2022115318647, whose filing date is 2022, 12, 1. The present application incorporates the entirety of the above-mentioned chinese patent application.

Technical Field

The application relates to the technical field of electric vehicle power conversion, in particular to a vehicle position adjusting device for power conversion.

Background

The electric vehicle has the advantages of zero emission, low noise, high operation and maintenance cost performance and the like, and is increasingly favored by users. The energy used by the electric vehicle is the electric energy provided by a battery pack carried by the electric vehicle, and the electric vehicle needs to be charged after the electric energy is used up. The battery pack of an electric vehicle is generally configured in a fixed type and a replaceable type, wherein the fixed type battery pack is generally fixed on the vehicle, and the vehicle is directly used as a charging object during charging. The battery pack can be quickly taken down to be independently replaced, namely, the battery which is pre-charged can be directly arranged on the vehicle, and the detached battery which is full of electricity can be independently charged to be arranged on the vehicle which is charged in a follow-up mode, so that the vehicle can be replaced with the full-charged battery in a very short time to quickly complete continuous voyage and energy supplement. Particularly, for large vehicles, due to the structure, loading requirements and the like, a large battery with large capacity is often arranged on a heavy truck, and the charging time of the large battery is longer, so that the power change mode for the heavy truck is more convenient to supplement energy.

In the power exchange process, the position accuracy of the vehicle directly influences the working conditions of disassembling and assembling the battery pack of the related equipment, if the position accuracy of the vehicle is inaccurate, the problem of power exchange failure or repeated power exchange is easily caused, and the situation that the related equipment, the battery pack and the vehicle are mechanically worn and even blocked in the power exchange process can be caused. In the current electric vehicle power change process, a power change vehicle firstly moves to a power change potential, and then power change operation is carried out on a battery on the power change vehicle by power change equipment. When the electric vehicle is changed to the electric potential, the electric vehicle is usually shifted by an offset angle, namely an included angle exists between the vehicle body and the length direction of the electric channel, so that the electric device is required to be moved to a position matched with the electric vehicle to change the electric power, the movement stroke of the electric device is increased, the electric power changing track is complex, and when the offset angle is larger, the problem of insufficient adjustment range of the electric device possibly exists, and the electric power changing operation is not facilitated.

Disclosure of Invention

The application provides a position adjusting device for a battery-changing vehicle, which can adjust the position or the angle of a vehicle body of an electric vehicle so as to solve the problems of complex battery-changing track, low battery-changing efficiency, insufficient adjustment range of the battery-changing device and the like of the battery-changing device.

The technical scheme adopted by the application is as follows:

the utility model provides a trade electric vehicle position adjustment device, sets up in the trade electric channel of a trade electric power station, including actuating mechanism and drive mechanism, actuating mechanism's power take off end with drive mechanism connects, makes drive mechanism acts on trade electric vehicle to with trade electric vehicle carries out position or automobile body angle adjustment, makes trade electric vehicle's automobile body with trade the length direction of electric channel is parallel.

In the technical scheme, the power output end of the driving mechanism is connected with the transmission mechanism, so that the transmission mechanism acts on the electric vehicle, the transmission mechanism can be driven to move through the driving mechanism, so that the automatic position adjustment of the electric vehicle can be realized by the transmission mechanism, manual operation can be saved, the precision and the efficiency of the position adjustment of the electric vehicle can be improved, the electric vehicle is friendly to drivers with different degrees of driving skills, the positions of the electric vehicle are not required to be adjusted repeatedly by the drivers, and more convenient conditions are provided for the electric vehicle. The driving mechanism is used as a power source to provide power output, the transmission mechanism is used as an intermediate structure to act on the battery changing vehicle so as to enable the battery changing vehicle to act, when the battery changing vehicle is regulated to the length direction of the vehicle body parallel to the battery changing channel, the battery changing device can smoothly and rapidly execute the processes of dismantling the battery of the battery changing vehicle and installing the full battery on the premise that the battery changing vehicle reaches the battery changing potential, and the battery changing device is convenient to change the battery along a preset track due to the fact that the position of the battery changing vehicle is regulated, so that the battery changing device can be prevented from moving greatly to adapt to the position of the battery changing vehicle, the relative position matching between the battery pack and the vehicle body is easier to realize, the dismounting process of the battery pack and the vehicle body is easy, and the battery changing efficiency is improved.

Preferably, the transmission mechanism acts on the wheels of the electric vehicle under the action of the driving mechanism, so that at least one part of the electric vehicle moves along the width direction of the electric exchanging channel, and the electric vehicle is adjusted towards the direction parallel to the length direction of the electric exchanging channel; the transmission mechanism comprises a movable plate which is used for being supported under the wheels of the battery-changing vehicle, the movable plate is connected with the driving mechanism, and the movable plate and the wheels synchronously move under the action of the driving mechanism.

In this technical scheme, after actuating mechanism drive mechanism, actuating mechanism applys effort in trading the wheel of electric vehicle to eliminate the skew angle (the contained angle between the length direction of automobile body and the trade electric passageway before the adjustment promptly) of trading electric vehicle, thereby adjust the automobile body, actuating mechanism acts on the wheel, and the application range is little, based on this actuating mechanism simple structure, small, can promote the holistic miniaturization of adjusting device, in order to avoid too much taking and trade electric passageway, reduce the influence to trading electric equipment layout. In addition, the movable plate provides a parking position for the wheels, and in the adjustment process of the power exchange vehicle, the movable plate can synchronously move with the wheels, and the moving direction can be perpendicular to the direction of the power exchange channel, so that the wheels are prevented from being blocked from moving due to large friction between the wheels and the movable plate.

Preferably, the movable plate is connected with the driving mechanism, and the driving mechanism is used for driving the movable plate to reciprocate along the width direction of the electricity exchanging channel.

In the technical scheme, the driving mechanism is used for driving the movable plate to reciprocate along the width direction of the power exchange channel, namely, the driving mechanism can drive the movable plate to realize bidirectional movement along the width direction of the power exchange channel, can realize bidirectional angle adjustment of a vehicle, and meets the requirement of multi-angle adjustment of the power exchange vehicle in the power exchange process.

Preferably, a rolling element is arranged on the lower side of the movable plate, and the rolling element rolls relative to the power exchanging channel when the movable plate moves.

In the technical scheme, the rolling element rolls relative to the power exchange channel when the movable plate moves, the translation of the movable plate driven by the driving mechanism is converted into the rolling of the rolling element, and the rolling friction is small, so that the acting force of the driving mechanism on the power exchange vehicle through the transmission mechanism can be reduced, the driving energy is saved, the cost is saved, and the adjustment efficiency is improved.

Preferably, the driving mechanism comprises a motor and a screw rod connected with the output end of the motor, a nut is arranged on the screw rod, the movable plate is fixedly connected with the nut, and the motor can drive the screw rod to rotate so that the nut drives the movable plate to reciprocate.

In this technical scheme, lead screw and nut cooperation form ball screw kinematic pair, and motor drive lead screw rotates, and the rotation of lead screw converts the reciprocal rectilinear movement of nut into, and then makes the nut drive fly leaf reciprocating movement, simple structure, the transmission is reliable, stable.

Preferably, the power exchange channel is further provided with a positioning platform, the movable plate is provided with a telescopic plate along the end part of the power exchange channel in the width direction, and the other end of the telescopic plate is connected with the positioning platform.

In this technical scheme, the expansion plate can stretch out and draw back at the fly leaf removal in-process, then locating platform and expansion plate seal and shelter from the structure that is located the fly leaf below, have both realized shielding the effect, can prevent again that external object accident from dropping to the fly leaf below and disturbing the device operation.

Preferably, the vehicle position adjusting device further comprises a wheel positioning assembly, the wheel positioning assembly limits wheels of the vehicle along the length direction of the vehicle, the wheel positioning assembly comprises a first positioning piece and a second positioning piece which are oppositely arranged along the advancing direction of the vehicle, and a positioning space is arranged between the first positioning piece and the second positioning piece so as to limit the wheels in the positioning space.

According to the technical scheme, the wheel positioning assembly is arranged, so that the wheels can be limited along the length direction of the battery-changing vehicle, the wheels are limited in the positioning space formed by the cooperation of the first positioning piece and the second positioning piece, on one hand, the parking position of the vehicle is limited, the battery-changing vehicle is parked at the preset position, on the other hand, the stability of the wheels in the adjustment process of the battery-changing vehicle can be kept, the wheels are always limited in the preset area range, the battery-changing vehicle is kept under the preset battery-changing potential, and a reliable condition is provided for the subsequent battery-changing process.

Preferably, the first positioning piece and/or the second positioning piece can be flattened towards the driving direction of the battery-changing vehicle, and arch along the retreating direction of the battery-changing vehicle.

In the technical scheme, when the first positioning piece and/or the second positioning piece are unfolded, the wheels can conveniently drive into the positioning space or drive out of the positioning space, and when the first positioning piece and/or the second positioning piece are arched, the limit of the wheels in the positioning space is realized.

Preferably, the first positioning piece and/or the second positioning piece comprise a first guiding piece and a second guiding piece, the first guiding piece and the second guiding piece are arranged along the advancing direction of the vehicle, one side of the first guiding piece is hinged with the movable plate, and the other side of the first guiding piece is hinged with the second guiding piece; when the wheel passes, the first guide piece and the second guide piece are flattened under the action of the wheel, and after the wheel passes, the first guide piece and the second guide piece are restored to an arched state.

In the technical scheme, one side of the first guide piece is hinged with the movable plate, and the other side of the first guide piece is hinged with the second guide piece, so that the first guide piece is matched with the rotation of the second guide piece relative to the movable plate to realize the switching between the flattening state and the arching state, and the movable plate is simple in structure and easy to control.

Preferably, one side of the second guiding element away from the first guiding element is connected with the movable plate through an elastic resetting element, and the elastic resetting element is used for pulling the second guiding element towards the direction of the first guiding element so that the first guiding element and the second guiding element are restored to an arched state after the wheels pass.

In the technical scheme, through setting up the elastic restoring piece for the second guide can be automatic after the vehicle passes through resumes to the arched state under the elasticity drive of elastic restoring piece, and the articulated cooperation of second guide and first guide makes the in-process synchronous drive of second guide automatic re-setting first guide reset the rotation towards the direction of arched.

Preferably, the first positioning piece and/or the second positioning piece comprises a first limiting structure, the first limiting structure is mounted on the movable plate, and the first limiting structure is located between the first guiding piece and the second guiding piece; the first limiting structure can be abutted with one side, facing the first guide piece, of the second guide piece so as to limit the moving distance of the second guide piece to the first guide piece.

According to the technical scheme, the first limiting structure is abutted with one side of the second guide piece towards the first guide piece to limit the moving distance of the second guide piece towards the first guide piece, so that the resetting movement of the second guide piece can be kept in an arched state, and the second guide piece can be prevented from excessively moving towards the first guide piece to be close to the first guide piece and difficult to be flattened again.

Preferably, a guide groove is formed in one surface of the second guide piece, which faces the first limiting structure, and when the first guide piece and the second guide piece are unfolded, the first limiting structure can enter the guide groove along the groove edge of the guide groove.

In this technical scheme, the setting of guide way provides the space of dodging for first limit structure when first guide and second guide are flattened, and first limit structure can stretch into the guide way promptly and can not produce the interference to the flattening removal of first guide and second guide, makes first guide and second guide can flatten completely to promote the smoothness and the smoothness of wheel process.

Preferably, the first positioning piece and/or the second positioning piece comprises a second limiting structure, and the second limiting structure can be abutted with one side, away from the first guiding piece, of the second guiding piece so as to limit the moving distance, away from the first guiding piece, of the second guiding piece.

In the technical scheme, the second guide piece and the first guide piece hinged with the second guide piece can be stably maintained in an arched state through the limiting of the second guide piece by the second limiting structure, so that the wheels are better limited, and the wheels are prevented from running out of the positioning space under the unexpected condition of inertia and the like after entering the positioning space.

Preferably, the movable plate is provided with a limiting hole, and the second limiting structure can stretch along the limiting hole.

In this technical scheme, accessible communication means remote control second limit structure is flexible in spacing downthehole, and convenient operation easily realizes, realizes spacing to the second guide when second limit structure stretches out spacing hole, releases the spacing to the second guide when retracting into spacing hole, makes the second guide can realize from the transformation of arch state towards flattening state.

By adopting the technical scheme, the application has the following technical effects: the power output end of the driving mechanism is connected with the transmission mechanism, so that the transmission mechanism acts on the battery-changing vehicle, the driving mechanism can drive the transmission mechanism to move so that the transmission mechanism can realize automatic position adjustment of the battery-changing vehicle, manual operation can be saved, the accuracy and the efficiency of position adjustment of the battery-changing vehicle are improved, the battery-changing vehicle is friendly to drivers with different degrees of driving skills, the drivers do not need to repeatedly adjust the position of the battery-changing vehicle, and more convenient conditions are provided for battery-changing of the battery-changing vehicle. The driving mechanism is used as a power source to provide power output, the transmission mechanism is used as an intermediate structure to act on the battery changing vehicle so as to enable the battery changing vehicle to act, when the battery changing vehicle is regulated to the length direction of the vehicle body parallel to the battery changing channel, the battery changing device can execute the dismantling of the battery changing vehicle and the installation of the full battery on the premise that the battery changing vehicle reaches the battery changing potential, and the battery changing device is convenient to change the battery along a preset track due to the fact that the position of the battery changing vehicle is regulated, the battery changing device can be prevented from moving greatly to adapt to the position of the battery changing vehicle, the relative position matching between the battery pack and the vehicle body is easier to realize, the disassembling process of the battery pack and the vehicle body is easy, and the battery changing efficiency is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

fig. 1 is a schematic structural diagram of a wheel of a battery-powered vehicle limited to a position adjusting device according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a position adjustment device at a first view angle according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of a position adjustment device at a second view angle according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a position adjustment device at a third view angle according to an embodiment of the present application;

FIG. 5 is a schematic structural view of an assembly formed by a position adjustment device, a positioning platform and a telescopic plate according to an embodiment of the present application;

FIG. 6 is a schematic structural diagram of a positioning platform according to an embodiment of the present application;

fig. 7 is a schematic structural diagram of a slider of a position adjustment device provided by an embodiment of the present application in a state of being matched with a slide rail of a positioning platform.

Reference numerals:

the device comprises a position adjusting device, a movable plate, a 111 positioning seat, a 112 limiting seat, a 113 sliding block, a 114 limiting hole, a 12 first positioning piece, a 121 first guiding piece, a 122 second guiding piece, a 1221 guiding groove, a 13 second positioning piece, a 14 elastic resetting piece, a 15 first limiting structure, a 16 second limiting structure, a 17 cylinder, a 18 rolling piece, a 191 motor, a 192 screw rod and a 193 nut;

2, a power-changing vehicle and 21 wheels;

3 positioning platform, 31 guide rail;

4 expansion plate.

Detailed Description

In order to more clearly illustrate the general inventive concept, a detailed description is given below by way of example with reference to the accompanying drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, however, the present application may be practiced in other ways than those described herein, and therefore the scope of the present application is not limited to the specific embodiments disclosed below.

In the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; the device can be mechanically connected, electrically connected and communicated; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present application, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

In the embodiment of the application, a vehicle position adjusting device for replacing a vehicle is provided, and for convenience of explanation and understanding, the following matters provided by the application are all described on the basis of the structure of the illustrated product. It will of course be appreciated by those skilled in the art that the above-described construction is provided as a specific example and illustrative only and is not intended to constitute a specific limitation on the scope of the application.

As shown in fig. 1 to 5, the position adjustment device 1 for a battery exchange vehicle provided by the present application is disposed in a battery exchange channel of a battery exchange station, the position adjustment device 1 includes a driving mechanism and a transmission mechanism, a power output end of the driving mechanism is connected with the transmission mechanism, so that the transmission mechanism acts on the battery exchange vehicle 2 to adjust a position or a vehicle body angle of the battery exchange vehicle 2, and a vehicle body of the battery exchange vehicle 2 is parallel to a length direction of the battery exchange channel. For example, the transmission mechanism may be applied to the whole of the electric vehicle, so that the driving mechanism drives the whole of the electric vehicle to move to realize position adjustment, or the transmission mechanism may be applied to a part of the electric vehicle structure, as shown in fig. 1, the application schematically shows an embodiment of the transmission mechanism applied to the wheel 21 of the electric vehicle 2 (only a part of the electric vehicle 2 is schematically shown in the drawing), and the driving mechanism drives the electric vehicle body to move through the transmission mechanism to adjust the angle of the vehicle body, thereby achieving the purpose that the vehicle body of the electric vehicle is parallel to the length direction of the electric channel.

In the application, the vehicle position adjusting device 1 is arranged in a power exchanging channel of a power exchanging station, and is suitable for the vehicle entering the power exchanging channel to exchange power. The power output end of the driving mechanism is connected with the transmission mechanism, so that the transmission mechanism acts on the battery-changing vehicle, the driving mechanism can drive the transmission mechanism to move so that the transmission mechanism can realize automatic position adjustment of the battery-changing vehicle, manual operation can be saved, the accuracy and the efficiency of position adjustment of the battery-changing vehicle are improved, the battery-changing vehicle is friendly to drivers with different degrees of driving skills, the drivers do not need to repeatedly adjust the position of the battery-changing vehicle, and more convenient conditions are provided for battery-changing of the battery-changing vehicle.

The driving mechanism is used as a power source to provide power output, the transmission mechanism is used as an intermediate structure to act on the battery changing vehicle so as to enable the battery changing vehicle to act, when the battery changing vehicle is regulated to the length direction of the vehicle body parallel to the battery changing channel, the battery changing device can smoothly and rapidly execute the processes of dismantling the battery of the battery changing vehicle and installing the full battery on the premise that the battery changing vehicle reaches the battery changing potential, and the battery changing device is convenient to change the battery along a preset track due to the fact that the position of the battery changing vehicle is regulated, so that the battery changing device can be prevented from moving greatly to adapt to the position of the battery changing vehicle, the relative position matching between the battery pack and the vehicle body is easier to realize, the dismounting process of the battery pack and the vehicle body is easy, and the battery changing efficiency is improved.

As to the manner in which the transmission mechanism drives the electric vehicle to move to adjust the position or the vehicle body angle, the present application is not limited, and as a preferred embodiment of the present application, as shown in fig. 1 and 2, the transmission mechanism may be caused to act on the wheels 21 of the electric vehicle 2 under the action of the driving mechanism, so that at least a portion of the electric vehicle 2 moves along the width direction of the electric channel, and the electric vehicle 2 is adjusted to be parallel to the length direction of the electric channel; the transmission mechanism comprises a movable plate 11 which is used for being supported under the wheels 21 of the battery-changing vehicle 2, the movable plate 11 is connected with the driving mechanism, and the movable plate 11 and the wheels 21 synchronously move under the action of the driving mechanism.

In particular, during a power change, the vehicle 2 may travel in the power change channel to a position where at least a portion of the wheels 21 are pressed above the movable plate 11, and the wheels 21 and the movable plate 11 remain relatively fixed, so that in a process of driving the movable plate 11 by the driving mechanism to move, the movable plate 11 drives the wheels 21 to move along the width direction of the power change channel, so that the vehicle 2 is adjusted to be parallel to the length direction of the power change channel. It can be understood by those skilled in the art that after the driving mechanism drives the transmission mechanism, the transmission mechanism applies an acting force to the wheels 21 of the electric vehicle 2 so as to eliminate the offset angle of the electric vehicle 2 (i.e. the included angle between the vehicle body and the length direction of the electric exchanging channel before adjustment), thereby adjusting the vehicle body, the transmission mechanism acts on the wheels 21, the acting range is small, the structure is simple and the volume is small based on the transmission mechanism, the overall miniaturization of the adjustment device can be promoted, so that the excessive occupation of the electric exchanging channel is avoided, and the influence on the arrangement of the electric exchanging equipment is reduced. In addition, the movable plate 11 provides a parking position for the wheel 21, and the movable plate 11 can move synchronously with the wheel 21 during adjustment of the power exchanging vehicle, and the moving direction can be perpendicular to the direction of the power exchanging channel, so as to prevent large friction between the wheel 21 and the movable plate 11 from obstructing the movement of the wheel 21. In other embodiments, the transmission mechanism may be applied to other structures of the electric vehicle 2 to drive at least a part of the electric vehicle 2 to move along the width direction of the electric transfer path, for example, the transmission mechanism may also be applied to a longitudinal beam of the vehicle body, and perform position or vehicle body angle adjustment after lifting at least a part of the vehicle body to a certain height.

Because of the structural limitation of the wheel 21, as a preferred example of the present embodiment, as shown in fig. 2, the vehicle position adjustment device 1 may further include a wheel positioning assembly for limiting the wheel 21 of the electric vehicle 2 along the length direction of the electric vehicle 2, the wheel positioning assembly including a first positioning member 12 and a second positioning member 13 disposed opposite to each other along the advancing direction of the electric vehicle 2, and a positioning space being provided between the first positioning member 12 and the second positioning member 13 to limit the wheel 21 in the positioning space.

It can be understood by those skilled in the art that by arranging the wheel positioning assembly, the wheels 21 can be limited along the length direction of the electric vehicle, so that the wheels 21 are limited in the positioning space formed by the cooperation of the first positioning piece 12 and the second positioning piece 13, on one hand, the parking position of the vehicle is limited, the electric vehicle 2 is parked in the preset position, the wheels 21 are prevented from being separated from the movable plate 11, on the other hand, the stability of the wheels 21 in the adjustment process of the electric vehicle 2 can be kept, the wheels 21 are always limited in the preset area range, the electric vehicle 2 is kept under the preset electric potential, and reliable conditions are provided for the subsequent electric current exchanging process. In a preferred example, as shown in fig. 2, the adjustment device may be provided with two vehicle positioning assemblies at intervals to be adapted in a one-to-one fit to the left and right wheels 21 attached to the same axle of the vehicle body.

Further, the first positioning member 12 can be flattened in the entering direction of the battery-change vehicle, and can arch in the retracting direction of the battery-change vehicle. In a preferred embodiment, the wheel 21 may be driven into the positioning space formed by the first positioning member 12 and the second positioning member 13 in cooperation with each other, for example, when the wheel 21 rolls the first positioning member 12, the first positioning member 12 is flattened so that the wheel 21 easily enters the positioning space, and when the wheel 21 enters the positioning space, the first positioning member 12 arches upward and forms a positioning space with the second positioning member 13 arching upward to prevent the wheel 21 from moving forward and backward, so as to limit the wheel 21 in the positioning space, and after the electric vehicle is completely replaced, the wheel 21 may be removed from the positioning space. The second positioning member 13 can be flattened in the driving direction of the electric vehicle, and arch in the backward direction of the electric vehicle, i.e., the wheel 21 located in the positioning space can move toward the second positioning member 13, when the wheel 21 rolls the second positioning member 13, the second positioning member 13 is flattened, so that the wheel 21 moves out of the movable plate 11 through the second positioning member 13, and the second positioning member 13 returns to the arch state after the wheel 21 moves out. It should be noted that the direction of the wheel 21 moving out of the positioning space is not limited in the present application, for example, the first positioning member 12 may be assisted to be flattened again by an external tool after the power change is completed, so that the wheel 21 may move toward the first positioning member 12 and move out through the first positioning member 12.

Regarding the structure of the first positioning member 12, as a preferred embodiment, as shown in fig. 2, the first positioning member 12 includes a first guide member 121 and a second guide member 122, the first guide member 121 and the second guide member 122 being arranged in the advancing direction of the exchanging vehicle, one side of the first guide member 121 being hinged with the movable plate 11, the other side being hinged with the second guide member 122; when the wheel 21 passes, the first guide 121 and the second guide 122 are flattened by the wheel 21, and after the wheel 21 passes, the first guide 121 and the second guide 122 return to the arched state.

As can be appreciated by those skilled in the art, one side of the first guide member 121 is hinged to the movable plate 11, and the other side is hinged to the second guide member 122, so that the rotation of the first guide member 121 relative to the movable plate 11 cooperates with the rotation of the second guide member 122 relative to the first guide member 121 to realize the switching between the flattened state and the arched state, and the structure is simple and easy to operate. Specifically, the first guide 121 and the second guide 122 may each be made to have a flat plate-like structure so that the flattened wheel 21 smoothly passes through. In particular, the wheel 21 may sequentially enter the positioning space via the first guide member 121 and the second guide member 122, that is, when the wheel 21 rolls the first guide member 121, the first guide member 121 rotates relative to the movable plate 11 and drives the second guide member 122 to rotate during rotation to realize flattening, so that the wheel 21 sequentially enters the positioning space via the first guide member 121 and the second guide member 122. Preferably, the second positioning member 13 has the same structure as the first positioning member 12, and the second positioning member 13 includes a first guide member and a second guide member, the first guide member and the second guide member are arranged along the advancing direction of the electric vehicle, one side of the first guide member is hinged with the movable plate 11, and the other side is hinged with the second guide member; when the wheel 21 passes, the first guide member and the second guide member are flattened by the wheel 21, and after the wheel 21 passes, the first guide member and the second guide member return to the arched state.

As a preferable example, as shown in fig. 2 and 3, a side of the second guide 122 remote from the first guide 121 is connected to the movable plate 11 by an elastic restoring member 14, and the elastic restoring member 14 is used to pull the second guide 122 in a direction approaching the first guide 121 so that the first guide 121 and the second guide 122 are restored to an arched state after the wheels 21 pass.

Specifically, the elastic restoring member 14 may be an extension spring, one end of the extension spring is connected to the movable plate 11, and the other end of the extension spring is connected to a side of the second guide member 122 away from the first guide member 121, where the second guide member 122 may slide along the surface of the movable plate 11 to achieve flattening or arching. By arranging the elastic restoring member 14, the second guiding member 122 can automatically restore to the arched state under the elastic force of the elastic restoring member 14 after the vehicle passes, and the hinge fit of the second guiding member 122 and the first guiding member 121 enables the second guiding member 122 to automatically restore to the original position and synchronously drive the first guiding member 121 to rotate in the arched direction.

As a preferred example, as shown in fig. 4, the first positioning member 12 includes a first limiting structure 15, the first limiting structure 15 is mounted on the movable plate 11, and the first limiting structure 15 is located between the first guide member 121 and the second guide member 122; the first limiting structure 15 can abut against a side of the second guide 122 facing the first guide 121 to limit a moving distance of the second guide 122 to the first guide 121.

Specifically, the first limiting structure 15 may be a protruding structure protruding and fixed on the upper surface of the movable plate 11, so as to abut against the second guiding element 122 when the second guiding element 122 arches under the pulling of the elastic restoring element 14, and further limit the second guiding element 122 to move towards the first guiding element 121. Therefore, by abutting the first limiting structure 15 against the second guide 122 toward the side of the first guide 121 to limit the moving distance of the second guide 122 toward the first guide 121, the restoring movement of the second guide 122 can be kept in the arched state, and the second guide 122 can be prevented from excessively moving toward the first guide 121 to abut against the first guide 121 and be difficult to be flattened again.

Further, as shown in fig. 2 and 3, a guide groove 1221 is formed on a surface of the second guide member 122 facing the first limiting structure 15, and when the first guide member 121 and the second guide member 122 are spread, the first limiting structure 15 can enter the guide groove 1221 along a groove edge of the guide groove 1221.

Preferably, the second positioning piece 13 has the same structure as the first positioning piece 12, the second positioning piece 13 comprises a first limiting structure, the first limiting structure is mounted on the movable plate 11, and the first limiting structure is positioned between the first guiding piece and the second guiding piece; the first limiting structure can be abutted with one side, facing the first guide piece, of the second guide piece so as to limit the moving distance of the second guide piece to the first guide piece. A guide groove is formed in one face, facing the first limiting structure 15, of the second guide piece, and when the first guide piece and the second guide piece are unfolded, the first limiting structure 15 can enter the guide groove along the groove edge of the guide groove.

Those skilled in the art will appreciate that the provision of the guide grooves 1221 provides the first limit structure 15 with a space for avoiding when the first guide member 121 and the second guide member 122 are flattened, i.e., the first limit structure 15 may extend into the guide groove 1221 without interfering with the flattening of the first guide member 121 and the second guide member 122, so that the first guide member 121 and the second guide member 122 may be completely flattened to promote the smoothness and smoothness of the passing of the wheel 21.

In a preferred embodiment, a plurality of first limiting structures 15 may be disposed at intervals along the extending direction of the second guide 122, as shown in fig. 4, and the present application schematically illustrates an embodiment in which two first limiting structures 15 are disposed at intervals between the first guide 121 and the second guide 122. The plurality of first limiting structures 15 are abutted together with the side, facing the first guide member 121, of the second guide member 122, the abutting surface is larger, the stress distribution is more uniform, and the moving distance of the second guide member 122 to the first guide member 121 can be more reliably limited.

As a preferred example, as shown in fig. 2, the second positioning member 13 includes a second limiting structure 16, and the second limiting structure 16 can abut against a side of the second guiding member away from the first guiding member to limit a moving distance of the second guiding member away from the first guiding member.

As can be appreciated by those skilled in the art, by limiting the second guide member by the second limiting structure 16, the second guide member and the first guide member hinged to the second guide member can be stably maintained in the arched state, so as to better limit the wheel 21, and avoid the wheel 21 from running out of the positioning space after entering the positioning space due to unexpected inertia or the like, particularly, in the embodiment that the wheel 21 enters the positioning space through the first positioning member 12 and runs out of the positioning space through the second positioning member 13, in the state that the second limiting structure 16 limits the second positioning member 13 in the arched state, the wheel 21 is prevented from moving out through the second positioning member 13 due to continuous forward movement due to inertia after entering the positioning space through the first positioning member 12. In other examples, the first positioning member 12 may also include a second limiting structure that can abut against a side of the second guiding member 122 away from the first guiding member 121 to limit a moving distance of the second guiding member 122 away from the first guiding member 121.

In a preferred embodiment, a plurality of second limiting structures 16 may be disposed at intervals along the extending direction of the second guide, as shown in fig. 2, and the present application schematically illustrates an embodiment in which two second limiting structures 16 are disposed at intervals on the movable plate 11. The plurality of second limit structures 16 are in butt joint with the second guide piece together, the butt surface is larger, the stress distribution is more uniform, the moving distance of the second guide piece away from the first guide piece can be more reliably limited, and the second guide piece can be stably kept in an arched state under the stop action of the plurality of second limit structures 16 to reliably limit the wheels 21.

Further, as shown in fig. 2, the movable plate 11 is provided with a limiting hole 114, and the second limiting structure 16 can extend and retract along the limiting hole 114. The second limiting structure 16 realizes limiting the second guide piece 122 when extending out of the limiting hole 114, and releases limiting the second guide piece 122 when retracting into the limiting hole 114, so that the second guide piece 122 can realize conversion from an arched state to a flattened state. In the specific implementation, as shown in fig. 2 and 3, the cylinder 17 can control the second limiting structure 16 to move up and down to change the position, and the second limiting structure 16 can be remotely controlled to stretch and retract in the limiting hole by a communication means, so that the operation is convenient and easy to realize.

Regarding the moving direction of the movable plate 11 driven by the driving mechanism, the movable plate 11 can be driven by the driving mechanism to move along the same direction, but as a preferred embodiment under the present embodiment, on the basis that the movable plate 11 is connected with the driving mechanism, the driving mechanism can be used for driving the movable plate 11 to reciprocate along the width direction of the power exchange channel, that is, the driving mechanism can drive the movable plate 11 to realize bidirectional movement along the width direction of the power exchange channel, so that bidirectional angle adjustment of the vehicle can be realized, and the multi-angle adjustment requirement of the power exchange vehicle in the power exchange process is met.

As a preferred example of the present embodiment, as shown in fig. 3, all the foregoing examples and examples of the present application may further include a rolling member 18 provided on the lower side of the movable plate 11, and the rolling member 18 rolls with respect to the power exchanging channel when the movable plate 11 moves.

Specifically, the rolling elements 18 may be rollers mounted on two opposite sides of the movable plate 11, when the movable plate 11 moves, the rolling elements 18 roll relative to the power conversion channel, so that the translation of the movable plate 11 driven by the driving mechanism is converted into the rolling of the rolling elements 18, the rolling friction is small, and the locking is not easy, thereby reducing the acting force of the driving mechanism on the power conversion vehicle through the transmission mechanism, saving driving energy, saving cost and improving adjustment efficiency.

Regarding a specific form of the driving mechanism, as a preferred example in this embodiment, as shown in fig. 3, all the foregoing embodiments and examples of the present application may further include a motor 191 and a screw 192 connected to an output end of the motor 191, where a nut 193 is disposed on the screw 192, and the movable plate 11 is fixedly connected to the nut 193, and the motor 191 may drive the screw 192 to rotate so that the nut 193 drives the movable plate 11 to reciprocate. The screw rod 192 and the nut 193 are matched to form a ball screw kinematic pair, the motor 191 drives the screw rod 192 to rotate, the rotation of the screw rod 192 is converted into the reciprocating linear movement of the nut 193, and then the nut 193 drives the movable plate 11 to reciprocate, so that the structure is simple, and the transmission is reliable and stable. Specifically, as shown in fig. 3, the motor 191 may be disposed below the movable plate 11, and a plurality of positioning seats 111 are disposed at the bottom of the movable plate 11 at intervals, the positioning seats 111 are used for supporting the screw rod 192 and are rotationally connected with the screw rod 192, a limiting seat 112 in limiting fit with the nut 193 is further disposed at the bottom of the movable plate 11, and fixation of the nut 193 and the movable plate 11 is achieved through limiting fit of the nut 193 and the limiting seat 112, so that synchronous movement of the nut 193 and the movable plate 11 is achieved.

In other embodiments, the driving mechanism may have other suitable structures, only need to drive the movable plate 11 to move, for example, the driving mechanism may also be a cylinder, a telescopic cylinder, etc.

As a preferred example in this embodiment, as shown in fig. 1, 5 and 6, all the foregoing embodiments and examples of the present application may further provide the power exchanging channel with a positioning platform 3, where an end of the movable plate 11 along the width direction of the power exchanging channel is provided with a telescopic plate 4, and the other end of the telescopic plate 4 is connected to the positioning platform 3.

Preferably, as shown in fig. 5, the two ends of the movable plate 11 are provided with expansion plates 4, and when the movable plate 11 moves in one direction, one expansion plate 4 expands and contracts, and the other expansion plate 4 stretches. It can be understood by those skilled in the art that the movable plate 11 moves on the positioning platform 3, the telescopic plate 4 can be telescopic in the moving process of the movable plate 11, the telescopic plate 4, the positioning platform 3 and the movable plate 11 enclose a closed space, and then the positioning platform 3 and the telescopic plate 4 seal and shield the structure below the movable plate 11, thereby realizing the shielding effect and preventing external objects from accidentally falling below the movable plate 11 to interfere with the operation of the device.

Further, in order to ensure that the movable plate 11 reliably and stably moves in the positioning platform 3, as shown in fig. 3, 6 and 7, a guide rail 31 may be fixedly disposed in the positioning platform 3, and a sliding block 113 with a sliding groove is fixedly disposed at the bottom of the movable plate 11, and the movement of the movable plate 11 is guided by matching the guide rail 31 with the sliding groove.

The application can be realized by adopting or referring to the prior art at the places which are not described in the application.

In this specification, each embodiment is described in a progressive manner, and identical and similar parts of each embodiment are all referred to each other, and each embodiment mainly describes differences from other embodiments.

The foregoing is merely exemplary of the present application and is not intended to limit the present application. Various modifications and variations of the present application will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the application are to be included in the scope of the claims of the present application.

Claims (10)

1. The utility model provides a trade electric vehicle position adjustment device, sets up in the trade electric channel of a trade electric power station, its characterized in that includes actuating mechanism and drive mechanism, actuating mechanism's power take off end with drive mechanism connects, makes drive mechanism acts on trade electric vehicle to trade electric vehicle carries out position or automobile body angle adjustment, makes trade electric vehicle's automobile body with trade electric channel's length direction parallel.

2. The electric-change vehicle position adjustment device according to claim 1, characterized in that the transmission mechanism acts on wheels of the electric-change vehicle under the action of the drive mechanism to move at least a part of the electric-change vehicle in a width direction of an electric-change passage so as to adjust the electric-change vehicle toward a length direction parallel to the electric-change passage; the transmission mechanism comprises a movable plate which is used for being supported under the wheels of the battery-changing vehicle, and the movable plate and the wheels synchronously move under the action of the driving mechanism.

3. The replacement vehicle position adjustment device according to claim 2, wherein the movable plate is connected to the driving mechanism for driving the movable plate to reciprocate in a width direction of the replacement passage.

4. A battery changing vehicle position adjusting device according to claim 3, wherein a rolling member is provided on the underside of the movable plate, and the rolling member rolls relative to the battery changing passage when the movable plate moves;

and/or the driving mechanism comprises a motor and a screw rod connected with the output end of the motor, a nut is arranged on the screw rod, the movable plate is fixedly connected with the nut, and the motor can drive the screw rod to rotate so that the nut drives the movable plate to reciprocate;

and/or the power exchange channel is also provided with a positioning platform, the movable plate is provided with a telescopic plate along the end part of the power exchange channel in the width direction, and the other end of the telescopic plate is connected with the positioning platform.

5. The electric vehicle replacement position adjustment device according to claim 2, further comprising a wheel positioning assembly that positions wheels of the electric vehicle along a longitudinal direction of the electric vehicle, the wheel positioning assembly including a first positioning member and a second positioning member that are disposed opposite to each other along a forward direction of the electric vehicle, a positioning space being provided between the first positioning member and the second positioning member to define the wheels in the positioning space.

6. The electric vehicle position adjustment device according to claim 5, characterized in that the first positioning member and/or the second positioning member can be flattened in the drive-in direction of the electric vehicle, and arch in the reverse direction of the electric vehicle.

7. The replacement vehicle position adjustment device according to claim 6, wherein the first positioning member and/or the second positioning member includes a first guide member and a second guide member, the first guide member and the second guide member being arranged in a forward direction of the replacement vehicle, the first guide member being hinged to the movable plate on one side and to the second guide member on the other side; when the wheel passes, the first guide piece and the second guide piece are flattened under the action of the wheel, and after the wheel passes, the first guide piece and the second guide piece are restored to an arched state.

8. The replacement vehicle position adjustment device according to claim 7, wherein a side of the second guide member away from the first guide member is connected to the movable plate by an elastic return member for pulling the second guide member in a direction of the first guide member to return the first guide member and the second guide member to an arched state after passing of the wheel.

9. The vehicle position adjustment device according to claim 7, characterized in that the first positioning member and/or the second positioning member includes a first limit structure mounted to the movable plate, the first limit structure being located between the first guide member and the second guide member; the first limiting structure can be abutted with one side, facing the first guide piece, of the second guide piece so as to limit the moving distance of the second guide piece to the first guide piece;

preferably, a guide groove is formed in one surface of the second guide piece, which faces the first limiting structure, and when the first guide piece and the second guide piece are unfolded, the first limiting structure can enter the guide groove along the groove edge of the guide groove.

10. The replacement vehicle position adjustment device according to claim 7, wherein the first positioning member and/or the second positioning member includes a second limit structure that can abut against a side of the second guide member away from the first guide member to limit a moving distance of the second guide member away from the first guide member;

preferably, the movable plate is provided with a limiting hole, and the second limiting structure can stretch and retract along the limiting hole.