DE202021107037U1 - Energy storage system and electric vehicle - Google Patents

Abstract

An energy storage system comprising a cabinet and electrochemical cells, the cabinet comprising a cabinet body and fastening mechanisms, the fastening mechanisms each comprising a storage rack, a drive module and a pressing component, the storage rack is arranged in the cabinet body, the electrochemical cell is arranged in the storage rack in a pluggable manner, the drive module is arranged on the storage rack, the press component is connected to the drive module, the drive module is able to drive the press component to rotate between a first position and a second position and when the press component is in the first position , the pressing component exerts a fastening force to fasten the plurality of electrochemical cells in the storage rack.

Description

TECHNICAL AREA

This application relates to the field of energy technologies and more particularly to an energy storage system and an electric vehicle.

BACKGROUND

With the rapid development of energy storage technologies, the lithium battery market is growing rapidly, and lithium battery products, in ascending order of size, include an electrochemical cell, a battery module, a battery pack, and a battery case. When lithium batteries are used in the power demand industry, especially in the electric vehicle industry, electrochemical cells are usually first connected in series and parallel to form a standard packaging module, and then the standard packaging module is placed in an assembly space such as an energy storage cabinet, rack and chassis of an electric vehicle to separately complete a power connection and a sample bundle connection and form a backup power supply system to power the vehicle. Currently, a manufacturer assembles a pack using electrochemical cells and then a battery module using a BMS. A large amount of protection and fastening devices must be configured. In addition, disassembling a single electrochemical cell after the battery module is assembled is difficult, and the entire pack must be replaced and serviced. Consequently, costs and a production cycle are affected.

SUMMARY OF UTILITY MODEL

In view of this, there is a need to provide an energy storage system and an electric vehicle to facilitate recycling and maintenance.

A first aspect of embodiments of this application provides an energy storage system that includes a cabinet and electrochemical cells. The cabinet includes a cabinet body and fastening mechanisms. The attachment mechanisms each include a bearing frame, a drive module, and a press component. The storage rack is arranged in the cabinet body. The electrochemical cell is arranged in the storage rack in a pluggable manner. The drive module is arranged on the storage rack. The pressing component is connected to the drive module. The drive module is capable of driving the press component to rotate between a first position and a second position. When the pressing component is in the first position, the pressing component applies a fastening force to secure the plurality of electrochemical cells in the storage rack.

In the energy storage system, the electrochemical cell can be used as a minimum unit. When the storage rack supports the electrochemical cell, the drive module drives the press component to be close to the storage rack to fix the electrochemical cell. A structure is simple, and recycling and maintenance of the electrochemical cell are convenient. In addition, the electrochemical cell is coupled directly to the cabinet body in a pluggable manner. This can reduce manufacturing costs, can fully utilize the space in the cabinet body, and improves an energy storage density of the cabinet body.

In a possible configuration of the first aspect, the storage rack includes a bottom plate, a first side plate and second side plates, the bottom plate, the first side plate and the second side plates form a receiving cavity for receiving the electrochemical cell, the drive module is rotatably arranged on the second side plates and is driven by the drive module, the pressing component is able to move toward the bottom plate to press the electrochemical cell in the receiving cavity. The receiving cavity formed by the bottom plate, the first side plate and the second side plates cooperates with the drive module rotatably mounted on the second side plates to confine the electrochemical cell in the receiving cavity through cooperation with the pressing component.

In a possible configuration of the first aspect, the drive module includes connecting rod components, the pressing component includes pressing plates, the connecting rod components each include a connecting rod base, a pressing rod, an adjustment rod and a driving rod, the connecting rod base is arranged on the second side plate, the pressing rod and the adjusting rod are rotatable on the connecting rod base, one end of the press rod is further connected to the press plate, and the drive rod is rotatably connected to the press rod and the adjustment rod. With the connecting rod base, press rod, adjustment rod and drive rod rotatably connected to each other, the drive rod can be rotated to drive the press rod to rotate and move to the Drive press plate to press the electrochemical cell. Compared to a manner in which the electrochemical cell is attached using a screw, the attachment time is reduced.

In a possible configuration of the first aspect, the drive module further includes synchronization rods, the synchronization rods each contain a connecting part and at least two synchronization parts, the connecting part connects the synchronization parts and the synchronization parts are each rotatably arranged on one of the drive rods. When one of the connecting rod components is rotated, the synchronizing rod connected to the drive rod can drive the remaining connecting rod components to rotate together and drive the compression plates connected to the connecting rod components to rotate together to cooperatively compress or release the electrochemical cell.

In a possible configuration of the first aspect, two sides of the press plate are each connected to one of the press rods. The pressing rods are arranged on the two sides of the pressing plate, so that the pressing plate can be pressed against the accommodating cavity more stably to stably fix the electrochemical cell in the accommodating cavity.

In a possible configuration of the first aspect, the fastening mechanisms each further include a restraining component, the restraining component includes restraining members and restraining blocks, the restraining member is disposed on the bottom plate, and the restraining block is disposed on the pressing plate. The limiting component is arranged such that a plugged position of the electrochemical cell can be limited.

In a possible configuration of the first aspect, the restriction component further includes a fastening member and restriction grooves arranged on the first side plate, and the fastening member is arranged on a pressing plate away from the first side plate. The fastening element and the limiting grooves are arranged in such a way that the electrochemical cell can be limited in an insertion direction of the electrochemical cell.

In a possible configuration of the first aspect, a width of the limiting element gradually decreases in a direction away from the floor panel. The limiting element, which gradually decreases in width, facilitates the placement and positioning of the electrochemical cell.

In a possible configuration of the first aspect, the storage rack includes a bottom plate, a first side plate, a top plate and a bearing plate, the first side plate is connected to the bottom plate and the top plate, the bearing plate is arranged on a side of the bottom plate which is close to the top plate and the first side plate, the top plate and the bearing plate form a receiving cavity for receiving the electrochemical cell. The receiving cavity formed by the bearing plate, the top plate and the first side plate can cooperate with the drive module to confine the electrochemical cell in the receiving cavity.

In a possible embodiment of the first aspect, the pressing component includes a pressing plate, the pressing plate is movably arranged on a side of the top plate that is close to the bottom plate, the drive module includes pressure bars, screw tensioning elements, a drive rod and drive gears, the pressure bar is arranged on the bearing plate and slid onto the press plate, the screw tightening member is placed on the pressure bar, the drive rod is rotatably placed on the bearing frame, and the drive gear is placed on the drive rod and meshes with the screw tightening member. The drive rod is rotated to drive the screw tensioner to adjust a length of the press bar so that the press plate is close to the bearing plate to secure the electrochemical cell. Compared to a manner in which the electrochemical cell is attached using a screw, the attachment time is reduced.

In a possible configuration of the first aspect, the storage frame further includes elastic members, and the pressing plate is movably arranged on the top plate by using the elastic member. The elastic element is arranged in such a way that the pressing plate is pressed against and released from the bearing plate.

In one possible configuration of the first aspect, the pressing component further includes a baffle, and the baffle removably covers the receiving cavity to cooperate with the first side plate to secure the electrochemical cell. The baffle plate cooperates with the first side plate to secure the electrochemical cell in a mating direction of the electrochemical cell.

In a possible configuration of the first aspect, the energy storage system contains fer ner a battery management system, and the battery management system is electrically connected to the electrochemical cell. The battery management system is arranged to facilitate the control and management of the electrochemical cell to improve safety performance and work efficiency.

A second aspect of embodiments of this application provides an electric vehicle that includes a powertrain, an energy storage system, and wheels. The energy storage system provides electrical energy to the drive train, and the energy storage system is the energy storage system in one of the first aspects or the possible configurations. The wheels are connected to the drive train.

character list

• 1 12 is a schematic structural diagram of an energy storage system according to Embodiment 1 of this application;
• 2 is a schematic three-dimensional diagram of a fastening mechanism of FIG 1 shown energy storage system;
• 3 1 is a schematic three-dimensional diagram of the attachment mechanism shown in FIG 2 is shown and which is in a different condition;
• 4 is a partially schematic exploded view of a three-dimensional effect of the in 2 attachment mechanism shown;
• 5 1 is a schematic three-dimensional diagram of the attachment mechanism shown in FIG 4 is shown and which is at a different angle;
• 6 FIG. 13 is a schematic three-dimensional diagram of a connecting rod component of FIG 4 attachment mechanism shown;
• 7 is a schematic exploded view of a three-dimensional effect of the in 6 tie rod component shown;
• 8th 12 is a schematic structural diagram of an energy storage system according to Embodiment 2 of this application;
• 9 is a schematic three-dimensional diagram of a fastening mechanism of FIG 8th shown energy storage system;
• 10 is a partially schematic exploded view of a three-dimensional effect of the in 9 attachment mechanism shown; and
• 11 is a schematic exploded view of a three-dimensional effect of the in 9 attachment mechanism shown.

Reference List

100

fastening mechanism

10, 50

storage rack

11, 51

bottom plate

12, 52

First side plate

121, 521

connection hole

13

Second Side Plate

131

Side wall

132

connecting wall

133

mounting wall

14, 55

receiving cavity

20, 60

drive module

21

connecting rod component

211

connecting rod base

212

press rod

213

adjustment rod

214

drive rod

2141

handle part

22

sync bar

221

connection part

222

synchronization part

30, 70

pressing component

31, 71

press plate

40

limiting component

41

boundary element

42

522: limiting groove

43

boundary block

44

fastener

53

cover plate

54

bearing plate

541, 711

guide hole

56

elastic element

72

flapper

721

grip hole

722

mounting hole

61

pressure bar

62

screw tensioning element

63

drive rod

631

rotary part

64

drive gear

200

cabinet

201

cabinet body

300

400: Energy storage system

301

electrochemical cell

302

Electrochemical cell body

303

electrode

304

Handle

This application is further described in the following specific implementations with reference to the foregoing accompanying drawings.

DESCRIPTION OF EMBODIMENTS

The following describes technical solutions in embodiments of this application with reference to the accompanying drawings in the embodiments of this application.

The following terms "first," "second," and the like are used for descriptive purposes only and should not be taken as an indication or implication of relative importance or as an implication of a set of stated technical features. Thus, a feature delimited by “first,” “second,” or the like, may explicitly or implicitly include one or more features. In the descriptions of this application, unless otherwise specified, “plural” means two or more than two. Additionally, in this application, orientation terms such as "upper/s", "lower/s", "left/s" and "right/s" are defined relative to orientations in which components in the accompanying Drawings are placed schematically. It should be understood that these orientation terms are relative concepts and are used for relative description and clarification and can change accordingly based on changes in the orientations in which the components are placed in the accompanying drawings.

In this application, unless expressly stated and limited otherwise, a term “compound” should be understood in a broad sense. For example, the "connection" may be a fixed connection, a detachable connection, or an integral connection; and may be a direct connection or an indirect connection by using an intermediate medium. The term "and/or" used in the specification includes any and all combinations of one or more associated listed items.

When the following embodiments are described in detail with reference to a schematic diagram, for convenience of description, a diagram indicating a partial structure of a component is not partially enlarged based on a general proportion, and the schematic diagram is just an example and should be used Do not limit the scope of protection of this application herein.

Embodiment 1

1 12 shows an energy storage system 300 according to Embodiment 1 of this application. The energy storage system 300 includes a cabinet 200 and electrochemical cells 301 . A plurality of pluggable electrochemical cells 301 are arranged in the cabinet 200 .

The cabinet 200 includes a cabinet body 201 and fastening mechanisms 100. A plurality of fastening mechanisms 100 are arranged in the cabinet body 201. FIG. A plurality of pluggable electrochemical cells 301 are positioned within mounting mechanism 100 . The fixing mechanism 100 is configured to restrict and fix a position for arranging the electrochemical cell 301 .

A battery management system (Battery Management System, BMS) may further be disposed within the cabinet body 201 to control the use, temperature, safety performance, and the like of the electrochemical cell 301 plugged into the cabinet body 201. Alternatively, the BMS system may be located externally in a building such as an industrial building or a house and is electrically connected to the cabinet body 201 to control the electrochemical cell 301 plugged into the cabinet body 201.

As in 2 and 3 As shown, the attachment mechanism 100 includes a storage rack 10, a drive module 20, and a pressing component 30. The storage rack 10 is fixedly disposed in the cabinet body 201. As shown in FIG. The storage rack 10 is configured to support the electrochemical cell 301 plugged into the storage rack 10 . The drive module 20 is arranged on the storage rack 10 . The pressing component 30 is connected to the drive module 20 . The drive module 20 is capable of driving the press component 30 to move between a first position and a second position and when the press component 30 is at the first position, the fastening force of the pressing component 30 is large, so that the electrochemical cell 301 inserted into the storage rack 10 can be pressed into the storage rack 10 to prevent the electrochemical cell 301 from the storage rack 10 separated will.

As in 4 and 5 As shown, the storage rack 10 includes a bottom panel 11, a first side panel 12 and two second side panels 13. The two second side panels 13 each extend outward from two opposite side edges of the bottom panel 11 in a direction perpendicular to a plane of the bottom panel 11. The first side panel 12 is connected to the bottom panel 11 and the two second side panels 13 . The bottom plate 11, the first side plate 12 and the two second side plates 13 form a receiving cavity 14 for receiving the electrochemical cell 301.

The first side plate 12 is provided with connecting holes 121 . The connection hole 121 is used for protruding an electrode 303 (see the following description) of the electrochemical cell 301 accommodated in the accommodating cavity 14 .

The drive module 20 includes a plurality of connecting rod components 21 and synchronizing rods 22. The plurality of connecting rod components 21 are arranged on the two second side plates 13 in opposition to each other. The sync bar 22 is rotatably disposed on the tie bar component 21 , and the plurality of tie bar components 21 are connected using one of the sync bar 22 . The pressing component 30 is connected between two connecting rod components 21 which are arranged opposite to each other. When the connecting rod components 21 connected to the pressing component 30 rotate, the pressing component 30 can rotate accordingly to press the electrochemical cell 301 disposed in the receiving cavity 14 . Rotating two of the connecting rod components 21 that are arranged opposite to each other can drive the synchronizing rods 22 connected to the two connecting rod components 21 to move to drive the remaining connecting rod components 21 to rotate together and the pressing component connected to the connecting rod components 21 30 drive to rotate together to squeeze or release the electrochemical cell 301.

As in 4 shown, the press component 30 includes a plurality of press plates 31. As in FIG 6 and 7 As shown, the tie rod components 21 each include a tie rod base 211, a press rod 212, an adjustment rod 213, and a drive rod 214. The tie rod base 211 is disposed on the second side plate 13. As shown in FIG. The pressing rod 212 and the adjustment rod 213 are rotatably mounted on the connecting rod base 211 . Furthermore, ends of two of the pressing rods 212 which are arranged opposite to each other are connected to the pressing plate 31 . The drive rod 214 is rotatably connected to the press rod 212 and the adjustment rod 213 , and the drive rod 214 is further rotatably connected to the synchronizing rod 22 . Rotating drive rod 214 can drive press rod 212 to rotate and drive timing rod 22 to move to drive press plate 31 to press electrochemical cell 301, and using timing rod 22 to drive the remaining connecting rod components 21 to move to spin together.

As in 5 As shown, the synchronizing rod 22 includes a connecting part 221 and at least two synchronizing parts 222. The connecting part 221 connects the plurality of synchronizing parts 222. The synchronizing parts 222 are each arranged rotatably on one of the drive rods 214.

In this embodiment, the attachment mechanism 100 includes two synchronizing rods 22. The two synchronizing rods 22 are each rotatably mounted on connecting rod components 21 on one of the two second side plates 13, and the connecting rod components 21, which are arranged on a same second side plate 13, are arranged using one of the Synchronization rods 22 connected. It can be understood that a sync bar 22 can be configured to connect the tie bar components 21 . For example, a U-shaped sync bar 22 or a sync bar 22 with a plate-shaped frame is configured to connect the connecting bar components 21 on the two second side plates 13 to each other.

A handle portion 2141 also extends from each of the drive rods 214 of two connecting rod components 21 that are away from one side of the first side plate 12. As shown in FIG. The handle portion 2141 is used by an operator to rotate the driving rod 214, to drive the pressing rod 212 to rotate and to drive the synchronization rod 22 to move, to drive the pressing plate 31, to press the electrochemical cell 301, and the remaining conn drive manure rod components 21 to rotate.

As in 4 and 5 As shown, the attachment mechanism 100 further includes a restraining component 40. The restraining component 40 is configured to restrain a plugged position of the electrochemical cell 301. FIG. The restricting component 40 includes restricting members 41, restricting grooves 42, restricting blocks 43 and a fixing member 44. The restricting member 41 is arranged on the bottom plate 11 and extends in an insertion direction of the electrochemical cell 301. The restricting groove 42 is arranged on the first side plate 12. The connection hole 121 is arranged on a bottom wall of the restriction groove 42 . A shape of the restriction groove 42 is a wedge of a cross-sectional shape of the electrochemical cell 301 to restrict an end of the electrochemical cell 301 provided with the electrode 303 during insertion of the electrochemical cell 301 and to avoid poor contact caused by loosening of an electrode end of the electrochemical cell 301 is caused. The limit block 43 is placed on the press plate 31 and driven by the connecting rod component 21 , the limit block 43 can be close to the accommodating cavity 14 with rotation of the press plate 31 . The restraining block 43 is configured to cooperate with the restraining member 41 to position the electrochemical cell 301 from two sides of the receiving cavity 14 . The fastener 44 is disposed on a pressing plate 31 away from the first side plate 12 and is located on a side of the pressing plate 31 away from the first side plate 12 . Driven by the connecting rod component 21, the fastener 44 can move toward the first side plate 12 with rotation of the press plate 31 to cooperate with the first side plate 12 to confine the electrochemical cell 301 in the mating direction.

A width of the confining member 41 in a direction away from the bottom plate 11 gradually decreases to facilitate placement and confinement of the electrochemical cell 301 .

The second side plates 13 each include a side wall 131, a connecting wall 132 and a mounting wall 133. The two side walls 131 are arranged opposite to each other and surround the receiving cavity 14 with the bottom plate 11 and the first side plate 12. The mounting wall 133 is configured to the storage rack 10 to be arranged in the cabinet body 201. The connecting wall 132 connects the side wall 131 and the mounting wall 133. The connecting rod component 21 is arranged on the connecting wall 132. FIG.

The electrochemical cell 301 includes an electrochemical cell body 302, the electrode 303 and a handle 304. The electrode 303 is arranged on one side of the electrochemical cell body 302, and after the electrochemical cell 301 is inserted into the attachment mechanism 100, the electrode 303 from the Connecting hole 121 protrude to be electrically connected to the cabinet body 201. The handle 304 is located on the other side of the electrochemical cell body 302 away from the electrode 303 .

During use, the handle part 2141 is rotated to open the pressing plate 31 by rotation, then an end of the electrochemical cell 301 having the electrode 303 is inserted into the receiving cavity 14, the insertion position of the electrochemical cell 301 is determined using the limiting member 41 and the restricting groove 42, the electrode 303 protrudes from the connecting hole 121, and the plurality of electrochemical cells 301 are inserted into the accommodating cavity 14 one by one. Then, the handle part 2141 is turned to drive the pressing plate 31 to rotate to press the electrochemical cell 301 against the bottom plate 11, and the limit block 43 and the fastener 44 arranged on the pressing plate 31 act with the Limiting member 41 and first side plate 12 together to secure electrochemical cell 301 in receiving cavity 14 to complete assembly.

In the energy storage system 300 in this application, the electrochemical cell 301 can be used as a minimum unit. When the fixing mechanism 100 fixes the electrochemical cell 301 during plugging and unplugging, the connecting rod component 21 drives the press plate 31 to rotate to fix the electrochemical cell 301 to adjust the position of the electrochemical cell 301 by cooperation with the limiting component 40 to limit. A structure is simple, and recycling and maintenance of the electrochemical cell 301 are convenient. Compared to a manner in which the electrochemical cell is attached using a screw, the attachment time is reduced. Furthermore, when the electrochemical cell 301 is used as a minimum unit, the electrochemical cell 301 is directly coupled to the cabinet body 201 in a pluggable manner. This reduces manufacturing cost of the whole product, can fully use space in the cabinet body 201, and ver improves an energy storage density of the cabinet body 201.

Embodiment 2

8th 12 shows an energy storage system 400 according to Embodiment 2 of this application.

The energy storage system 400 has a same structure as the energy storage system 300 and includes a cabinet body 201, attachment mechanisms 100 and electrochemical cells 301. A major difference from that in FIG 1 The power storage system 300 shown in Embodiment 1 is that a structure of the attachment mechanism 100 is different.

With reference to 9 until 11 The attachment mechanism 100 includes a storage rack 50, a drive module 60, and a press component 70.

The storage rack 50 includes a bottom panel 51, a first side panel 52, a top panel 53 and a bearing panel 54. The first side panel 52 is connected to the bottom panel 51 and the top panel 53. As shown in FIG. The bearing plate 54 is arranged on a side of the bottom plate 51 that is close to the top plate 53 . The bearing plate 54, the top plate 53 and the first side plate 52 form a receiving cavity 55 for receiving the electrochemical cell 301. The electrochemical cell 301 is inserted into the receiving cavity 55. FIG.

The pressing component 70 includes a pressing plate 71 and a baffle plate 72. The pressing plate 71 is movably disposed on a side of the top plate 53 that is close to the bottom plate 51. As shown in FIG. Baffle plate 72 removably covers receiving cavity 55 to cooperate with first side plate 52 to secure electrochemical cell 301 in place.

The drive module 60 includes pressure bars 61, screw tensioning elements 62, a drive rod 63 and drive gears 64. The pressure bar 61 is pushed onto the bearing plate 54 and the pressure plate 71 in a direction perpendicular to an insertion direction of the electrochemical cell 301. The screw tensioning element 62 is arranged on the pressure bar 61 . The screw tightening element 62 can adjust a length of the pressure bar 61 so that the pressure plate 71 is close to the bearing plate 54 . The driving rod 63 is rotatably mounted on the cabinet body 201 or the storage rack 50 . The drive gear 64 is disposed on the drive rod 63 and meshes with the screw tightening member 62 . Rotating the drive rod 63 can drive the drive gear 64 to rotate so that the screw tightening member 62 is adjusted and moves accordingly to tighten the pressure bar 61 to allow the pressure plate 71 to move in a direction of the bearing plate 54 to to press the electrochemical cell 301 accommodated in the accommodation cavity 55 .

In this embodiment, the drive module 60 includes four pressure bars 61, four screw tensioning elements 62 and four drive gears 64. The four pressure bars 61 are successively pushed onto the bearing plate 54 and the pressure plate 71 in the insertion direction of the electrochemical cell 301. The drive gears 64 are arranged on the drive rod 63 to be synchronously adjusted and tightened as the drive rod 63 is rotated.

A rotary part 631 is arranged on a side of the driving rod 63 away from the first side plate 52 . The rotating part 631 is used by an operator to rotate the driving rod 63 to drive the plurality of driving gears 64 to rotate.

The bearing plate 54 and the pressing plate 71 are further provided with guide holes 541 and guide holes 711 . The pressure bar 61 passes through the guide hole 541 and the guide hole 711 to prevent the pressure bar 61 from moving side to side.

The first side plate 52 is provided with connecting holes 521 . The connection hole 521 is used for protruding an electrode 303 of the electrochemical cell 301 accommodated in the accommodating cavity 55 . Limiting grooves 522 are further arranged on the first side plate 52 and are configured to limit a plugging position of the electrochemical cell 301 .

The baffle plate 72 is provided with handle holes 721. The handle hole 721 is used to protrude a handle 304 of the electrochemical cell 301 .

The storage frame 50 further includes elastic members 56. The pressing plate 71 is movably mounted on the top plate 53 by using the elastic member 56. FIG.

The baffle plate 72 is provided with mounting holes 722 . The mounting hole 722 is used to cooperate with a fastener such as a screw to fix the baffle plate 72 to the cabinet body 201 .

During use, the rotary member 631 is rotated to allow the pressing plate 71 to move in a direction away from the to move support plate 54, then an end of the electrochemical cell 301 having the electrode 303 is inserted into the receiving cavity 55, the insertion position of the electrochemical cell 301 is restricted using the restricting groove 522, the electrode 303 protrudes from the connecting hole 521, and the plurality of electrochemical cells 301 are inserted into the receiving cavity 55 one at a time. Then, the rotary member 631 is rotated to drive the driving rod 63 to rotate to tighten the pressing bar 61 , drive the pressing plate 71 to move toward the bearing plate 54 , and press the electrochemical cell 301 . Then the baffle plate 72 covers the mounting cavity 55 and a fastener such as a screw passes through the mounting hole 722 to secure the baffle plate 72 and secure the electrochemical cell 301 in the receiving cavity 55 to complete the mounting.

In the energy storage system 400 in this application, the electrochemical cell 301 can be used as a minimum unit. When the fastening mechanism 100 fastens the electrochemical cell 301 during plugging and unplugging, the pressure bar 61 is arranged to cooperate with the screw tensioning element 62 such that rotation of the drive rod 63 drives the screw tensioning element 62 to move to tighten the pressure bar and to fix the electrochemical cell 301 by cooperation between the pressing plate 71 and the bearing plate 54 . Therefore, fixing time is reduced, maintenance is easy, and costs are low.

An embodiment of this application further provides an electric vehicle, and the electric vehicle provides electrical energy by using the energy storage system 400 above.

The electric vehicle can be a regular electric vehicle/electric vehicle (EV), a pure electric vehicle/battery electric vehicle (PEV/BEV), a hybrid electric vehicle (HEV), an extended range electric vehicle (EREV), a plug-in hybrid electric vehicle (PHEV), a vehicle a new energy (new energy vehicle), an electric bus, an electric motorcycle, or the like.

The electric vehicle includes the energy storage system 400, wheels, and a powertrain. Energy storage system 400 provides electrical energy to the powertrain. The drive train is connected to the wheels to drive the wheels to rotate.

It should be understood that the electric vehicle provided in this embodiment further includes general electric vehicle components such as a vehicle body and a vehicle door. Details are not described herein.

The above descriptions are only specific implementations of this application, but are not intended to limit the scope of protection of this application. Any variation or substitution within the technical scope disclosed in this application shall fall within the scope of protection of this application.

Claims (13)

An energy storage system comprising a cabinet and electrochemical cells, the cabinet comprising a cabinet body and fastening mechanisms, the fastening mechanisms each comprising a storage rack, a drive module and a pressing component, the storage rack is arranged in the cabinet body, the electrochemical cell is arranged in the storage rack in a pluggable manner, the drive module is arranged on the storage rack, the press component is connected to the drive module, the drive module is able to drive the press component to rotate between a first position and a second position and when the press component is at the first position , the pressing component exerts a fastening force to fasten the plurality of electrochemical cells in the storage rack. energy storage system claim 1 , wherein the storage rack comprises a bottom plate, a first side plate and second side plates, the bottom plate, the first side plate and the second side plates form a receiving cavity for receiving the electrochemical cell, the drive module is rotatably arranged on the second side plates and is driven by the drive module, the pressing component is able to move towards the bottom plate to press the electrochemical cell in the receiving cavity. energy storage system claim 2 wherein the drive module comprises tie rod components, the pressing component comprises pressing plates, the tie rod components each comprise a tie rod base, a pressing rod, an adjustment rod and a driving rod, the tie rod base is arranged on the second side plate, the pressing rod and the adjustment rod are rotatably arranged on the tie rod base The end of the press rod is also connected to the press plate den and the drive rod is rotatably connected to the press rod and the adjustment rod. energy storage system claim 3 wherein the drive module further comprises synchronizing rods, the synchronizing rods each comprising a connecting part and at least two synchronizing parts, the connecting part connecting the synchronizing parts and the synchronizing parts each being rotatably arranged on one of the drive rods. energy storage system claim 3 , wherein two sides of the press plate are each connected to one of the press rods. energy storage system claim 3 wherein the attachment mechanisms each further comprise a restraining component, the restraining component comprising restraining members and restraining blocks, the restraining member being disposed on the bottom plate, and the restraining block being disposed on the squeeze plate. energy storage system claim 6 wherein the restraining component further comprises a fastener and restraining grooves disposed on the first side plate, and the fastener is disposed on a press plate away from the first side plate. energy storage system claim 1 , wherein the storage rack comprises a bottom panel, a first side panel, a top panel and a bearing panel, the first side panel is connected to the bottom panel and the top panel, the bearing panel is arranged on a side of the bottom panel that is close to the top panel, and the first Side plate, the top plate and the bearing plate form a receiving cavity for receiving the electrochemical cell. energy storage system claim 8 , wherein the pressing component comprises a pressing plate, the pressing plate is movably arranged on a side of the top plate that is close to the bottom plate, the drive module comprises pressing bars, screw tensioning elements, a drive rod and drive gears, the pressing bar is arranged on the bearing plate and pushed onto the pressing plate , the screw tensioning element is arranged on the pressure bar, the drive rod is arranged rotatably on the bearing frame and the drive gear wheel is arranged on the drive rod and meshes with the screw tensioning element. energy storage system claim 9 wherein the storage rack further comprises elastic members, and the pressing plate is movably arranged on the top plate by using the elastic member. energy storage system claim 9 wherein the stamping component further comprises a baffle, and the baffle removably covers the receiving cavity to cooperate with the first side plate to secure the electrochemical cell. energy storage system claim 1 , wherein the energy storage system further comprises a battery management system, and the battery management system is electrically connected to the electrochemical cell. An electric vehicle comprising: a powertrain; an energy storage system configured to provide electrical energy to the powertrain, wherein the energy storage system is the energy storage system according to any one of Claims 1 until 12 is; and wheels connected to the drive train.

Images