CN220076343U - Electricity exchanging device - Google Patents

Abstract

The utility model relates to the field of power exchange, and discloses a power exchange device, which comprises a power exchange base and a battery tray mechanism arranged on the power exchange base, wherein the battery tray mechanism comprises a tray frame, a battery transfer bin is formed in the tray frame, one end opening of the tray frame forms a battery inlet and outlet end for a power exchange battery to enter and exit the battery transfer bin, and an electromagnetic traction mechanism for drawing the power exchange battery to enter and exit the battery transfer bin is arranged on the tray frame; the electricity exchanging base is provided with a rotating mechanism, a lifting mechanism and a linear sliding rail mechanism which are used for respectively realizing the rotation, the up-down movement and the horizontal movement of the tray frame. The utility model realizes the change of the position of the battery in a horizontal pushing or sucking mode in the power conversion process, effectively reduces the stroke of the power conversion device, improves the power conversion efficiency, shortens the power conversion period, improves the customer experience, and simultaneously can avoid the lifting and falling risk of the battery.

Description

Electricity exchanging device

Technical Field

The utility model relates to the field of power conversion, in particular to a power conversion device.

Background

The conventional power exchange device in the power exchange station generally adopts a top surface hoisting mode and a side hoisting mode when the power exchange battery is subjected to power exchange, the two modes all require the power exchange device to lift the power-deficient battery on the power exchange end to a certain height, then the power exchange battery is placed in a battery bin in the power exchange station, then the power exchange device moves to a corresponding position of a battery bin to take out the full-power battery, the power exchange battery is lifted to a certain height again and then moves to the power exchange end, and finally the power exchange battery is controlled to descend and is fixed at the power exchange end.

This kind of hoist and mount formula of changing electricity needs lifting up many times, puts down the battery, and route stroke is longer in the cycle of changing electricity, and repetitive operation has greatly increased the time of changing electricity, and it is inefficiency to change electricity, and customer experience feels poor to still need to realize hoist and mount and aim at changing the electric end, change electric precision and be difficult to guarantee.

Disclosure of Invention

The utility model provides a power conversion device aiming at the problems of hoisting type power conversion in the prior art.

In order to solve the technical problems, the utility model is solved by the following technical scheme:

the battery tray mechanism comprises a tray frame, a battery transferring bin is formed inside the tray frame, a battery inlet and outlet end for a battery to be transferred to and from the battery transferring bin is formed at one end opening of the tray frame, and an electromagnetic traction mechanism for drawing the battery to be transferred to and from the battery transferring bin is arranged on the tray frame;

the electricity exchanging base is provided with a rotating mechanism, a lifting mechanism and a linear sliding rail mechanism which are used for respectively realizing the rotation, the up-down movement and the horizontal movement of the tray frame.

Preferably, the electricity changing base comprises a base plate, the lifting mechanism is arranged above the base plate and comprises a supporting frame and a jacking cylinder for realizing up-and-down movement of the supporting frame, the jacking cylinder is arranged on the base plate, and the end part of a piston rod is hinged to the supporting frame. The lifting of battery tray mechanism can be realized to jacking cylinder, and then the mode through changing battery tray mechanism height goes to change the height of trading the electric battery, makes it can aim at corresponding battery compartment or bracket storehouse, realizes trading the accurate going on of electric work.

Preferably, the rotating mechanism comprises a turntable mounting plate, a turntable is arranged in the middle of the turntable mounting plate, a rotating motor for realizing rotation of the turntable is arranged on the bottom surface of the turntable mounting plate, and the tray frame is fixed on the turntable. The arrangement of the rotating mechanism can realize the steering of the battery tray mechanism, so that the battery inlet and outlet ends can be aligned to the battery bin or the bracket bin, and the smooth and accurate position switching of the battery can be realized.

Preferably, the linear sliding rail mechanism comprises a linear sliding rail motor and a heavy-load sliding rail fixed on the upper surface of the supporting frame, a heavy-load sliding block matched with the heavy-load sliding rail is arranged on the bottom surface of the turntable mounting plate, and the linear sliding rail motor drives the heavy-load sliding block to do linear reciprocating motion on the heavy-load sliding rail through the screw rod sliding block mechanism. The cooperation of heavy-duty slide rail and heavy-duty slider can realize the horizontal movement of whole battery tray mechanism, makes it can move to near battery compartment or change electric end position department, has realized that follow-up better battery to change pulls.

Preferably, the tray frame comprises a bottom rectangular frame, a top U-shaped frame and a plurality of stand columns connected between the bottom rectangular frame and the top U-shaped frame, the bottom rectangular frame, the top U-shaped frame and the stand columns are jointly constructed into a battery transferring bin, and the U-shaped opening end of the top U-shaped frame forms a battery inlet and outlet end.

Preferably, the electromagnetic traction mechanism comprises a linear module and further comprises an electromagnet which can move towards or back to the inlet and outlet ends of the battery on the linear module and is used for adsorbing the battery. The driving to the battery that trades is realized through the form of electro-magnet absorption for the battery that trades can horizontal movement realize changing the change of position between device, the battery that trades, this kind of absorption mode also can guarantee the battery that trades at the inside stability of device that trades simultaneously, avoids trading the electric in-process and breaks away from the position, and in addition to the battery that trades the electric in-process direction positioning effect that trades, make the battery that trades can be fast, accurate in place.

Preferably, the linear module comprises two linear sliding rails distributed on two sides of the tray frame and two linear sliding blocks respectively sliding along the two linear sliding rails, and the electromagnet is in a strip shape and two ends of the electromagnet are respectively fixed on the two linear sliding blocks.

Preferably, the electromagnetic traction mechanism further comprises an electromagnet driving mechanism, the electromagnet driving mechanism comprises a driving wheel and a driven wheel which are arranged at two ends of the linear slide rail, a transmission belt is connected between the driving wheel and the driven wheel, the linear slide block is connected to the transmission belt, the electromagnetic traction mechanism further comprises a bidirectional servo motor fixed on the tray frame, and two driving shafts which are respectively connected with the driving wheels on the linear slide rails at two sides are connected to the bidirectional servo motor. The linear sliding blocks on two sides are synchronously driven by the bidirectional servo motor, so that synchronous movement of two ends of the electromagnet is realized, and the stability of linear movement of the electromagnet is ensured.

Preferably, two motor installation seats are arranged at the end part of the top U-shaped frame far away from the U-shaped opening end, the electromagnetic traction mechanism is fixed on the upper end surface of the top U-shaped frame, and driving shafts on two sides of the bidirectional servo motor are respectively installed on the two motor installation seats. The setting of motor mount pad can guarantee the stability when two-way servo motor works, guarantees that the drive shaft stably outputs power, realizes electro-magnet both ends synchronous motion.

Preferably, a battery sliding rail or a roller matched with the bottom of the battery is arranged on the upper end face of the rectangular bottom frame, and the bottom of the battery frame is provided with the roller capable of rolling on the battery sliding rail or the battery sliding rail sliding on the roller. The battery slide rail can realize that the battery that trades better at trading electric installation and trading electric end and remove to realize trading the change position that the battery changed.

The utility model has the remarkable technical effects due to the adoption of the technical scheme:

in the power conversion process, the power conversion device and the power conversion end or the battery compartment are positioned at the same horizontal position, the change of the position of the power conversion battery is realized by adopting a horizontal pushing or sucking mode, the stroke of the power conversion device is effectively shortened, the power conversion efficiency is improved, the power conversion period is shortened, the customer experience is improved, and the risk of falling of the power conversion battery during hoisting can be avoided.

Drawings

Fig. 1 is a schematic structural diagram of a power conversion device in embodiment 1 of the present utility model.

Fig. 2 is a schematic structural diagram of the battery cell at the battery-exchanging end in embodiment 1 of the present utility model.

Fig. 3 is a schematic view of the battery tray mechanism of fig. 1.

Fig. 4 is a schematic structural view of the power conversion base in fig. 1.

Fig. 5 is a schematic diagram of an assembly between the rotary mechanism and the linear slide mechanism of fig. 4.

Fig. 6 is a schematic structural view of the electromagnetic traction mechanism of fig. 1.

Fig. 7 is a schematic view of the structure of the battery cell of fig. 2.

Fig. 8 is a schematic structural diagram of the power conversion terminal in fig. 2.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings and examples.

Example 1

1-8, including the battery 1 that trades, the device 2 that trades and trade the electric end 3, the device 2 that trades includes trading the electric base 21 and sets up the battery tray mechanism 22 on trading the electric base 21, battery tray mechanism 22 includes tray frame 201, tray frame 201 inside constitutes battery and transports storehouse 202, tray frame 201's one end opening constitutes and supplies battery access end 203 that trades battery 1 business turn over battery transport storehouse 202, wherein tray frame 201 includes bottom rectangular frame 204, top U-shaped frame 205 and connects a plurality of stands 206 between bottom rectangular frame 204 and top U-shaped frame 205, and on the side of tray frame 201 and lie in between adjacent stands 206 still be equipped with side shield 228, bottom rectangular frame 204, top U-shaped frame 205 and stand 206 constitute battery transport storehouse 202 jointly, the U-shaped open end of top U-shaped frame 205 constitutes battery access end 203, in order to strengthen the structural stability and the bearing capacity of bottom rectangular frame 204, be equipped with a plurality of reinforcing cross arms 229 that evenly arrange in bottom rectangular frame 204.

The tray frame 201 is provided with an electromagnetic traction mechanism 23 for drawing the battery 1 into and out of the battery transfer bin 202, the electromagnetic traction mechanism 23 comprises a linear module 220, and an electromagnet 221 which can move towards or back to the battery inlet and outlet end 203 on the linear module 220 and is used for adsorbing the battery 1.

The battery changing terminal 3 comprises a bottom bracket 31, a bracket bin 32 for accommodating the battery 1 is formed in the bottom bracket 31, the bottom bracket 31 comprises a bracket bottom frame 301 and bracket baffle rods 302 arranged on two sides of the bracket bottom frame 301, and the bracket bottom frame 301 and the bracket baffle rods 302 form the bracket bin 32.

The battery transfer bin 202 can run at the same level as the cradle bin 32 or battery bin with the battery access end 203 facing the cradle bin 32 or battery bin.

In this embodiment, the battery replacing device 2 and the battery replacing terminal 3 or the battery compartment are located on the same horizontal plane, so that the battery transferring compartment 202 and the bracket compartment 32 or the battery compartment are horizontally and oppositely arranged, the battery replacing device 1 is enabled to operate and replace electricity in the horizontal plane in the battery replacing process, the falling risk caused by lifting or lowering the battery replacing device 1 in the existing lifting process is avoided, meanwhile, the battery replacing device 1 is not required to be lifted in the process, and therefore no obvious lifting and lowering actions exist in the operation process of the battery replacing device 1 between the battery replacing device 2 and the battery replacing terminal 3 and in the operation process between the battery replacing device 2 and the battery compartment, and the battery replacing device can be directly operated horizontally, so that the travel of the battery replacing device 2 can be shortened, the battery replacing efficiency is effectively improved, and the customer experience is improved.

The bottom rectangular frame 204 and the upper end face of the bracket underframe 301 are respectively provided with a matching piece in sliding fit or rolling fit with the bottom of the battery, in this embodiment, the matching pieces on the bottom rectangular frame 204 and the upper end face of the bracket underframe 301 are battery slide rails 207 which are oppositely arranged and are in longitudinal directions along the in-out direction of the battery 1, the battery 1 comprises a rectangular battery frame 11, the bottom of the battery frame 11 is provided with a roller 12 capable of rolling on the battery slide rails 207, and the middle of the roller 12 is provided with an annular guide groove 13 matched with the battery slide rails 207.

Of course, the matching parts on the upper end surfaces of the rectangular frame 204 and the bracket bottom frame 301 can be provided as a plurality of rollers 12 as required, and the battery sliding rail 207 sliding on the rollers 12 is arranged at the bottom of the battery frame 11 to realize the operation of the battery 1 on the battery exchange terminal 3 and the battery exchange device 2.

In addition, a guide groove 13 with a U shape is arranged in the middle of the battery slide rail 207 so as to realize the matching between the battery slide rail and the roller 12. The battery transferring bin 202 and the bracket bin 32 for accommodating the battery 1 are formed on the battery replacing device 2 and the battery replacing end 3 respectively, so that the position stability of the battery replacing 1 can be maintained when the battery replacing 1 is positioned on the battery replacing device 2 or the battery replacing end 3, rollover of the battery replacing 1 in the operation process is avoided, and the safety of the battery replacing process is improved.

In the power conversion process, the power conversion battery 1 can directly horizontally run between the battery slide rail 207 on the power conversion device 2 and the battery slide rail 207 on the power conversion end 3 under the action of the electromagnetic traction mechanism 23, and the matching of the battery slide rail 207 and the guide groove 13 on the roller 12 can further ensure the positioning of the operation of the power conversion battery 1 and ensure the accuracy and stability of the operation of the power conversion battery 1.

In order to further ensure the power changing process and the stability and positioning accuracy after the battery is installed, and realize the matching of the plug pins 304 on the connector bracket and the plug holes on the battery frame 11, so as to realize that the battery and the vehicle are electrically connected, the bracket underframe 301 is provided with a pneumatic positioning mechanism, the pneumatic positioning mechanism comprises a connector bracket 303 which can move up and down, the connector bracket 303 is provided with the plug pins 304 which are matched and plugged with the power changing battery 1, and the connector bracket 303 realizes the up-and-down movement by means of an air cylinder arranged on the bracket underframe 301. Meanwhile, a pneumatic positioning mechanism is also arranged in a battery compartment of the battery replacement station so as to fix the battery 1. The power conversion base 21 in the embodiment is provided with a rotating mechanism 208, a lifting mechanism 209 and a line slide rail mechanism 210 for respectively realizing the rotation, the up-down movement and the horizontal movement of the tray frame 201;

the power conversion base 21 comprises a base plate 211, a lifting mechanism 209 is arranged above the base plate 211, the lifting mechanism 209 comprises a supporting frame 212 and a jacking air cylinder 213 for realizing up-and-down movement of the supporting frame 212, the jacking air cylinder 213 is arranged on the base plate 211, and the end part of a piston rod is hinged on the supporting frame 212;

the rotating mechanism 208 comprises a turntable mounting plate 214, a turntable 215 is arranged in the middle of the turntable mounting plate 214, a rotating motor 216 for realizing the rotation of the turntable 215 is arranged on the bottom surface of the turntable mounting plate, and the tray frame 201 is fixed on the turntable 215;

the linear slide rail mechanism 210 comprises a linear slide rail motor and a heavy-load slide rail 218 fixed on the upper surface of the support frame 212, a heavy-load slide block 219 matched with the heavy-load slide rail 218 is arranged on the bottom surface of the turntable mounting plate 214, and the linear slide rail motor drives the heavy-load slide block 219 to do linear reciprocating motion on the heavy-load slide rail 218 through the screw rod slide block mechanism.

The lifting mechanism 209 and the linear sliding rail mechanism 210 can realize the linear motion of the battery tray mechanism 22 in the horizontal direction and the vertical direction so as to realize the adjustment of the height of the battery tray mechanism 22 and the distance between the battery tray mechanism and the battery compartment or the battery exchange end 3; the rotating mechanism 208 can realize the rotating motion of the battery tray mechanism 22 so as to realize the adjustment of the orientation angle of the battery inlet and outlet ends 203, and the three adjustment modes can ensure that the battery 1 can run among the battery compartment, the battery replacing device 2 and the battery replacing end 3, so that the battery can stably and accurately run to a target position to realize efficient and accurate battery replacement.

In the operation process, if the position of the battery 1 is required to be raised or lowered, the lifting cylinder 213 in the lifting mechanism 209 is started to push the supporting frame 212 to move upwards or downwards, and then the whole battery tray mechanism 22 is driven to move upwards or downwards so as to change the height position of the battery 1 inside the battery tray mechanism, and the battery 1 is always adsorbed in the battery transferring bin 202 under the action of the electromagnet 221 in the process, so that the position is stable and no falling risk exists.

If the battery 1 can be aligned to the battery compartment or the bracket compartment 32, the rotating motor 216 drives the turntable 215 to rotate, and then drives the battery tray mechanism 22 to rotate, so that the battery inlet and outlet end 203 is aligned to the battery compartment or the bracket compartment 32, and the wire slide motor drives the screw rod to rotate, and the screw rod drives the screw rod slide block to drive the turntable mounting plate 214 to horizontally move to the position close to the battery compartment or the bracket compartment 32 under the matching of the heavy-load slide block 219 and the heavy-load slide rail 218, so that the electromagnetic traction mechanism 23 mechanism can smoothly and accurately adsorb the battery 1, the position of the battery 1 in the horizontal direction is switched between the battery compartment, the battery changing device 2 and the battery changing end 3, the position is switched after the battery 1 is lifted up and down, the movement stroke of the battery 1 is greatly reduced, and the battery changing efficiency is provided.

In this embodiment, the linear module 220 in the electromagnetic traction mechanism 23 includes two linear sliding rails 222 distributed on two sides of the tray frame 201 and two linear sliding blocks 223 sliding along the two linear sliding rails 222 respectively, and the electromagnet 221 is in a strip shape and two ends of the electromagnet 221 are fixed on the two linear sliding blocks 223 respectively.

The electromagnetic traction mechanism 23 further comprises an electromagnet driving mechanism, wherein the electromagnet driving mechanism comprises a driving wheel 217 and a driven wheel 224 which are arranged at two ends of the linear slide rail 222, a transmission belt is connected between the driving wheel 217 and the driven wheel 224, a sliding block is connected to the transmission belt, the electromagnetic traction mechanism further comprises a bidirectional servo motor 225 which is fixed on the tray frame 201, and two driving shafts 226 which are respectively connected with the driving wheels 217 on the linear slide rails 222 at two sides are connected to the bidirectional servo motor 225.

The end of the top U-shaped frame 205 far away from the open end of the U-shape is provided with two motor mounting seats 227, the electromagnetic traction mechanism 23 is fixed on the upper end surface of the top U-shaped frame 205, and the driving shafts 226 on both sides of the bidirectional servo motor 225 are respectively mounted on the two motor mounting seats 227.

The electromagnetic traction mechanism 23 is arranged on the top surface of the tray frame 201, so that the space of the battery transferring bin 202 is not occupied, and interference to the entering of the battery 1 into the battery transferring bin 202 is avoided. When the electric power conversion device works, the electromagnet 221 slides to a position close to the target electric power conversion battery 1 along the linear sliding rail 222 under the action of the electromagnet driving mechanism, the electromagnet 221 adsorbs the electric power conversion battery 1 after being electrified, and then the electric power conversion battery 1 is pulled into or pushed out of the battery transfer bin 202 under the action of the driving belt, so that the position of the electric power conversion battery 1 among the battery bin, the battery transfer bin 202 and the bracket bin 32 is switched.

Example 2

The power conversion method is realized by adopting the power conversion system in the embodiment 1, the power conversion system further comprises a central control system, the central control system comprises a laser visual positioning mechanism arranged on the power conversion device 2, and a light sensor module arranged at the power conversion end 3, and the method specifically comprises the following steps:

step S1, a central control system receives a battery replacement signal to acquire a replaceable target position of a replacement battery 1 and a full battery bin position;

step S2, determining a battery bin position which can be used for placing a target position of the power-deficient battery 1;

step S3, the central control system controls the power exchanging device 2 to operate and reach the target position of the power exchanging end 3 under the action of the laser visual positioning mechanism, the rotating mechanism 208, the lifting mechanism 209 and the linear sliding rail mechanism 210;

step S4, the electromagnetic traction mechanism 23 runs to the position of the battery 1 on the battery replacement end 3 and is attached, and the battery 1 is magnetically attracted after being electrified;

step S5, the electromagnetic traction mechanism 23 operates to draw the battery 1 with insufficient power to be separated from the bottom bracket 31 of the power conversion end 3 to the battery tray mechanism 22;

step S6, the central control system controls the power conversion device 2 to operate to the position of an empty battery compartment;

step S7, the electromagnetic traction mechanism 23 operates to draw the battery 1 with insufficient power to be separated from the battery tray mechanism 22 to an empty battery bin;

step S8, fixing the empty battery bin space and the power-shortage battery 1;

step S9, the central control system controls the power conversion device 2 to operate and reach the position of the full-power conversion battery 1 under the action of the laser visual positioning mechanism, the rotating mechanism 208, the lifting mechanism 209 and the linear sliding rail mechanism 210;

step S10, the electromagnetic traction mechanism 23 operates to the full-charge battery 1 device and is attached, and after the full-charge battery 1 is electrified, the full-charge battery 1 is magnetically attracted;

step S11, the electromagnetic traction mechanism 23 operates to draw the full-charge battery 1 to be separated from the battery bin to the battery tray mechanism 22;

step S12, the central control system controls the power conversion device 2 to run to the target position of the power conversion terminal 3;

step S13, the electromagnetic traction mechanism 23 operates to draw the full-charge battery 1 to be separated from the battery tray mechanism 22 to the bottom bracket 31 of the battery replacement end 3; step S14, the full-power battery 1 is fixed at the battery replacement terminal 3;

step S15, the electromagnetic traction mechanism 23 is operated to return to the original position of the power conversion device 2;

and S16, the central control system controls the power conversion device 2 to operate and returns to the original position of the power conversion device 2.

In this embodiment, the two side power conversion devices 2 may be configured in the power conversion station, that is, two power conversion devices 2 are disposed between the battery compartment and the power conversion terminal 3, so as to implement the cooperative operation of the power taking and discharging battery, shorten the stroke of the power conversion device 2, further shorten the power conversion time, improve the power conversion efficiency, and the power taking and discharging battery actions of the power conversion device 2 can be completed in the power conversion station without counting the power conversion period of the power conversion terminal 3.

In this embodiment, when the power conversion device 2 cannot work under special conditions, the manual traction mode can be switched to convert power, so that the emergency performance is high.

It is to be understood that, based on one or several embodiments provided in the present utility model, those skilled in the art may combine, split, reorganize, etc. the embodiments of the present utility model to obtain other embodiments, which do not exceed the protection scope of the present utility model.

In summary, the foregoing description is only of the preferred embodiments of the present utility model, and all equivalent changes and modifications made in accordance with the claims should be construed to fall within the scope of the utility model.

Claims (10)

1. The utility model provides a trade electric installation which characterized in that: the battery tray mechanism (22) comprises a tray frame (201), wherein a battery transferring bin (202) is formed inside the tray frame (201), a battery inlet and outlet end (203) for allowing a battery (1) to pass in and out of the battery transferring bin (202) is formed at one end opening of the tray frame (201), and an electromagnetic traction mechanism (23) for drawing the battery (1) to pass in and out of the battery transferring bin (202) is arranged on the tray frame (201);

the electricity exchanging base (21) is provided with a rotating mechanism (208), a lifting mechanism (209) and a line sliding rail mechanism (210) which are used for respectively realizing the rotation, the up-down movement and the horizontal movement of the tray frame (201).

2. A power conversion device according to claim 1, characterized in that: the power exchange base (21) comprises a base plate (211), a lifting mechanism (209) is arranged above the base plate (211), the lifting mechanism (209) comprises a supporting frame (212) and a jacking cylinder (213) for realizing up-and-down movement of the supporting frame (212), the jacking cylinder (213) is arranged on the base plate (211), and the end part of a piston rod is hinged on the supporting frame (212).

3. A power conversion device according to claim 2, characterized in that: the rotating mechanism (208) comprises a turntable mounting plate (214), a turntable (215) is arranged in the middle of the turntable mounting plate (214), a rotating motor (216) for realizing rotation of the turntable (215) is arranged on the bottom surface of the turntable mounting plate, and the tray frame (201) is fixed on the turntable (215).

4. A power conversion device according to claim 3, characterized in that: the linear slide rail mechanism (210) comprises a linear slide rail motor and a heavy-load slide rail (218) fixed on the upper surface of the supporting frame (212), a heavy-load slide block (219) matched with the heavy-load slide rail (218) is arranged on the bottom surface of the turntable mounting plate (214), and the linear slide rail motor drives the heavy-load slide block (219) to do linear reciprocating motion on the heavy-load slide rail (218) through the screw rod slide block mechanism.

5. A power conversion device according to claim 1, characterized in that: the tray frame (201) comprises a bottom rectangular frame (204), a top U-shaped frame (205) and a plurality of stand columns (206) connected between the bottom rectangular frame (204) and the top U-shaped frame (205), the bottom rectangular frame (204), the top U-shaped frame (205) and the stand columns (206) are jointly configured into a battery transferring bin (202), and the U-shaped opening end of the top U-shaped frame (205) forms a battery inlet and outlet end (203).

6. A power conversion device according to claim 5, characterized in that: the electromagnetic traction mechanism (23) comprises a linear module (220) and further comprises an electromagnet (221) which can move on the linear module (220) towards or away from the battery inlet and outlet end (203) and is used for adsorbing the battery (1).

7. A power conversion device according to claim 6, characterized in that: the linear module (220) comprises two linear slide rails (222) distributed on two sides of the tray frame (201) and two linear slide blocks (223) respectively sliding along the two linear slide rails (222), wherein the electromagnet (221) is in a strip shape, and two ends of the electromagnet are respectively fixed on the two linear slide blocks (223).

8. A power conversion device according to claim 7, characterized in that: the electromagnetic traction mechanism (23) further comprises an electromagnet driving mechanism, the electromagnet driving mechanism comprises a driving wheel (217) and a driven wheel (224) which are arranged at two ends of the linear sliding rail (222), a transmission belt is connected between the driving wheel (217) and the driven wheel (224), the linear sliding block (223) is connected to the transmission belt, the electromagnetic traction mechanism further comprises a bidirectional servo motor (225) fixed to the tray frame (201), and two driving shafts (226) which are respectively connected with the driving wheels (217) on the linear sliding rail (222) at two sides are connected to the bidirectional servo motor (225).

9. A power conversion device according to claim 8, characterized in that: the end part of the top U-shaped frame (205) far away from the U-shaped opening end is provided with two motor mounting seats (227), an electromagnetic traction mechanism (23) is fixed on the upper end surface of the top U-shaped frame (205), and driving shafts (226) on two sides of the bidirectional servo motor (225) are respectively mounted on the two motor mounting seats (227).

10. A power conversion device according to claim 5, characterized in that: the upper end face of the bottom rectangular frame (204) is provided with a battery sliding rail (207) or a roller which is matched with the bottom of the battery.