KR101634933B1 - Battery pack for electric car and the control method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery pack for an electric vehicle and a control method thereof, and more particularly, to a battery pack for an electric vehicle capable of detecting an abnormality in a battery pack mounted on an electric vehicle and quickly controlling the battery pack.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery pack for an electric vehicle,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery pack for an electric vehicle and a control method thereof, and more particularly, to a battery pack for an electric vehicle capable of detecting an abnormality in a battery pack mounted on an electric vehicle and quickly controlling the battery pack.

BACKGROUND ART [0002] In recent years, rechargeable secondary batteries have been widely used as energy sources for wireless mobile devices. In addition, secondary batteries are attracting attention as power sources for electric vehicles (EVs) and hybrid electric vehicles (HEVs), which are proposed as solutions for air pollution in conventional gasoline vehicles and diesel vehicles using fossil fuels.

In the case of small mobile devices, one or two or more battery cells are used per device, while a middle- or large-sized battery pack such as an automobile is used for a large-sized battery pack in which a large number of battery cells are electrically connected due to the necessity of a high output large capacity.

Since the middle- or large-sized battery pack is preferably manufactured in a small size and weight, a prismatic battery, a pouch-type battery, and the like, which can be charged with a high degree of integration and have a small weight to capacity, are mainly used as battery cells of a middle- or large-sized battery pack. Particularly, a pouch-shaped battery using an aluminum laminate sheet or the like as an exterior member has recently attracted a great deal of attention due to its advantages such as a small weight and a low manufacturing cost.

Such a middle- or large-sized battery pack (for example, registered patent No. 1305224, registered on Mar. 23, 2013) is used for an electric vehicle and a hybrid electric vehicle.

However, in the conventional cleaning electric vehicle, in order to increase the rated capacity of the battery pack, the number of the battery packs must be increased. However, there is a problem that the accommodation space needs to be redesigned when the battery pack is increased as the narrower accommodation box is installed. Also, conventionally, there has been a problem that when the electric vehicle is overdischarged, or when the vehicle is in trouble due to a high temperature or a short circuit, it is not equipped with any warning means, so that the vehicle suddenly stops during operation.

Also, in the conventional electric vehicle battery pack, there is no method to confirm the internal measurement data such as the temperature and voltage sensing data sensed by the BMS of the battery pack due to a failure or other reasons, .

SUMMARY OF THE INVENTION It is an object of the present invention to provide a battery pack for an electric vehicle capable of promptly responding to a driver by detecting and alerting an abnormality of the battery pack during operation or stop of the electric vehicle, And a control method thereof.

It is another object of the present invention to provide an electric vehicle battery capable of communicating with a terminal (not shown) capable of recording and modifying internal data of a battery pack and installing erasable programs such as a battery pack, a desktop, a notebook computer, a PDA, a netbook, Pack and a control method thereof.

The present invention includes the following embodiments in order to achieve the above object.

A preferred embodiment of the battery pack for an electric vehicle according to the present invention is a battery pack for an electric vehicle that supplies power to an electric vehicle, the battery pack comprising: at least one BMS sensing a voltage and a temperature of one or more unit battery packs fixed to the inside of the housing; A relay for switching a power supply line connected to a power connector of the unit battery pack; A main controller for comparing the detection signal of the temperature and voltage of the unit battery pack applied from the BMS with a setting reference to determine whether there is an abnormality and controlling the relay; And an alarm unit for alerting the user of the abnormality by the control of the main controller, wherein the unit battery pack includes a case for accommodating a battery module to which at least one battery cell is connected, and an upper cover for sealing the upper portion of the case; And at least one elastic member extending longitudinally from an inner edge of the case to elastically support the battery module and the circuit board, wherein the elastic member has elasticity such that the back surface and both side surfaces of the battery module are spaced apart from the inner surface of the case, A first elastic material; And a second elastic member for elastically supporting the front surface of the battery module, wherein the second elastic member comprises: a supporting protrusion protruded to support a front edge of the battery module; The battery pack for an electric vehicle is provided.

In another embodiment of the present invention, the electric vehicle battery pack further includes an emergency switch for applying an emergency power off command and a communication connector to which a communication cable is connected.

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In another embodiment of the present invention, the unit battery pack is characterized in that a shielding material for shielding electromagnetic waves is adhered to a wall surface and a bottom plate of a case housing a battery module in which at least one battery cell is electrically connected.

According to another embodiment of the present invention, the housing may be formed at an end of a bottom surface so as to be spaced apart from a bottom plate of the unit battery pack.

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The present invention is capable of detecting and alerting an abnormality of a battery pack during operation or stop of an electric vehicle, so that it is possible to promptly respond to a driver.

In addition, since the present invention can communicate with a terminal (not shown) capable of recording and modifying internal data of the battery pack and installing erasable programs such as a battery pack, a desktop, a notebook, a PDA, a netbook, and a PDP, There is an easy effect.

1 is a perspective view showing a preferred embodiment of a battery pack for an electric vehicle according to the present invention,
FIG. 2 is a perspective view of a battery pack for an electric vehicle according to the present invention,
3 is a block diagram of a battery pack for an electric vehicle according to the present invention;
4 is a side sectional view of a battery pack for an electric vehicle according to the present invention,
5 is a perspective view illustrating a unit battery pack in the battery pack for an electric vehicle according to the present invention,
6 is an exploded perspective view of a unit battery pack in an electric vehicle battery pack according to the present invention,
7 is a flowchart showing a control method of a battery pack for an electric vehicle according to the present invention.

Hereinafter, preferred embodiments of a battery pack for an electric vehicle and a control method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing a preferred embodiment of a battery pack for an electric vehicle according to the present invention, FIG. 2 is a perspective view showing a battery pack in an electric vehicle battery pack according to the present invention, FIG. Fig. 4 is a side cross-sectional view of a battery pack for an electric vehicle according to the present invention.

1 to 4, an electric vehicle battery pack according to the present invention includes at least one unit battery pack 400 or 400 'to which at least one battery cell is connected, and at least one unit battery pack 400 or 400' A cover 100 for sealing the housing 200 and a main controller 310 for detecting and controlling abnormality by integrating the one or more unit battery packs 400 and 400 ' And an electric field panel (300).

The one or more unit battery packs 400 and 400 'may include a battery module 450 in which one or more battery cells are connected in series or in parallel to a case 410 and the temperature and voltage of the battery module 450 are sensed (Battery Management System) 350, 350 '. That is, in the one or more unit battery packs 400 and 400 ', the first unit battery pack 400 includes a first BMS 350 and the second unit battery pack 400' (BMS) 350 '. A more detailed description of the unit battery packs 400 and 400 'will be described later.

The housing 200 is formed with a bottom surface 213 and a side wall 211 to house one or more unit battery packs 400 and 400 ' A handle 220 fixed to the upright side wall 211 and a handle 220 connected to the unit battery pack 400 and 400 ' A power terminal 230 and a bent end 214 bent at the upper end of the side wall 211 and having a plurality of screw holes 214a for fixing the cover 100 and the electric panel 300. [

The bending end 214 is formed with a plurality of screw holes 214a which coincide with the screw hole 130 formed in the electric field panel 300 and the cover 100. The screw hole 214a is screwed with the screw that communicates the electric field panel 300 with the cover 100.

The handles 220 are a pair that are fixed at mutually opposed positions on both side walls of the housing 200.

The spacing step 212 separates the bottom plate 440 of the unit battery pack 400 or 400 'from the bottom surface 213 of the housing 200. The separation terminals 212 are designed to prevent vibrations or shocks applied from the bottom surface 213 of the housing 200 from being transmitted to the unit battery packs 400 and 400 '.

The power terminal 230 is supported on one side wall of the housing 200 by a fixing bracket 231 and is connected to the electric panel 300. The power terminal 230 transfers power output from the unit battery packs 400 and 400 'to the power connector 120.

The cover 100 includes a control panel 110 on an upper surface thereof, a power connector 120 connected to the power terminal 230 to connect a cable or a wire extending from a load (not shown) of the electric vehicle, A connector support groove 140 for supporting the connector 120 and at least one screw hole 130 coinciding with the screw hole 214a formed in the bent end 214 of the housing 200. [

The connector support groove 140 defines an area in which the power connector 120 is located by a frame 141 extending in the transverse and / or longitudinal direction as an inwardly recessed groove.

The power supply connector 120 is positioned one by one in the space defined by the connector support grooves 140 defined by the frame 141 extending in the lateral and longitudinal directions in the cover 100, And is electrically connected. In addition, the power connector 120 is connected to a load of an electric vehicle with a power cable or a wire to supply power output from the unit battery packs 400 and 400 '.

The operation panel 110 includes a power switch 111 for applying a power output command to the one or more unit battery packs 400 and 400 ', an emergency switch 112 for applying a power off command, (Not shown), and an alarm unit 114 that alerts the user of an error with the light and / or sound signal.

The power switch 111 applies a power output command. When the power switch 111 is turned on in a state where the battery pack is connected to a load by a cable or a power line connected to the power connector 120 after the battery pack is installed in the electric vehicle, Of the load.

The emergency switch 112 applies a power off command. For example, when the user turns on the emergency switch 112 after recognizing an alarm signal (for example, light emission or alarm sound) of the alarm section 114, the power output of the power connector 120 is cut off .

The communication connector 113 is a connector to which a communication cable of another terminal (not shown) is connected. For example, when a user connects a communication cable to the communication connector 113 connected to a terminal (not shown) capable of CAN communication, the main controller and the terminal (not shown) Communication) is possible.

The alarm unit 114 outputs an abnormality of the battery pack as an emission signal or an acoustic signal under the control of a main controller 310, which will be described later. For this, the alarm unit 114 includes at least one of a lamp for outputting a light emission signal or a buzzer for outputting an alarm sound.

The power switch 111 to the alarm unit 114 interlock with the main controller 310 of the electric panel 300 described below. A more detailed description will be given later with the main controller 310 of the electric field panel 300.

The electric field panel 300 includes a connector 320 connected to a first BMS 350 and a second BMS 350 'respectively installed in the unit battery pack, The first unit battery pack 400 and the second unit battery pack 400 'applied from the first BMS 350 and the second BMS 350' The main controller 310 controls the main controller 310 to detect the temperature and the voltage of the first unit battery pack 400 and the second unit battery pack 400 ' A relay 330 is provided for switching the power supply.

The connector 320 connects the first BMS 350 of the first unit battery pack 400 and the second BMS 350 'of the second unit battery pack 400' So that a temperature and voltage sensing signal is applied to the main controller 310.

The output unit 340 is connected between the first unit battery pack 400 and the second unit battery pack 400 'and the power terminal 230 to connect the first unit battery pack 400' And the second unit battery pack 400 'are connected in series or in parallel.

The main controller 310 controls the relay 330 to turn on the first unit battery pack 400 and the second unit unit 400 when the power on / off command is applied from the power switch 111 and the emergency switch 112, The power supply line connected to the output unit 340 in the battery pack 400 'is turned off.

In addition, the main controller 310 receives the voltage sensing and temperature sensing signals of the first BMS 350 and the second BMS 350 ', and outputs the sensed temperature and voltage level (charging rate) The alarm unit 114 is controlled and alarmed.

Also, the main controller 310 stores the voltage and temperature sensing data sensed by the first BMS 350 and the second BMS 350 'in its own memory, 113 on the request of another terminal (not shown) connected thereto. In addition, the main controller 310 may control the relay 330 and the alarm unit 114 according to a control command of another terminal (not shown) connected to the communication connector 113. The main controller 310 stores log information such as connection time and file name of transmission / reception data when another terminal (not shown) is connected to the communication connector 113.

The unit battery packs 400 and 400 'will be described in detail with reference to the first unit battery packs shown in FIGS. FIG. 5 is a perspective view showing a unit battery pack in an electric vehicle battery pack according to the present invention, and FIG. 6 is an exploded perspective view of a unit battery pack in the electric vehicle battery pack according to the present invention.

5 and 6, the unit battery pack 400 includes a front plate 420 which forms an upright wall on a top surface of a bottom plate 440 on which a battery module 450, to which one or more battery cells are connected, An upper cover 410 for sealing the upper portion of the case 450 and a case 450 for sealing the upper portion of the case 450, (BMS) that senses the temperature and voltage of the battery.

The battery module 450 includes a circuit board 452 that connects one or more battery cells in series or electrically and connects each battery cell in series or in parallel, And a connector 453 to which a cable connected from the BMS is connected.

The upper cover 410 includes a handle 4110 which is seated in a groove 411a which is inwardly inward from the upper surface and which is rotated in a vertical direction and a fixing table 412 which is spaced apart from the rear surface to form a space for accommodating the BMS, .

The handle 411 is held in a state of being buried in the groove 411a by rotating the holder 411 in a state where the handle 411 is embedded in the groove 411a and rotating the holder 411 in an opposite direction after being used.

The fixing table 412 is fixed at the back surface of the upper cover 410 to accommodate the BMS 350. The BMS 350 is connected to the connector 453 of the circuit board 452. The connection structure between the BMS 350 and the battery module 450 is generally known, so that the description thereof is omitted.

The bottom plate 440 is extended in a plane so that the both side plates 430 are fixed to the front plate 420 and the back plate 480 in an upright manner, And a fixing tab 441 on which the fixing tab 441a is formed. The fixing tab 441 is in close contact with the bottom plate 440 and the screw 442 is communicated from the bottom plate 440 to the bottom surface 213 of the housing 200 through the screw hole 441a Thereby fixing the unit battery pack 400.

The bottom plate 440 of the unit battery pack 400 is separated from the bottom surface 213 of the housing 200 by the spacing step 212 of the housing 200.

The front plate 420 is formed with a through hole 421 through which the cable extending from the pole 451 and the BMS penetrates. In addition, it is preferable that the through-hole 421 is provided with a polarized-state display portion for displaying polarity as a character or a symbol.

The unit battery pack 400 includes an elastic member 470 for supporting the battery module 450 with an elastic force to prevent the battery module 450 from being damaged by external vibration or impact, And a shielding material 460 adhered to the both side plates 430 and the rear plate 480 so as to block electromagnetic waves.

The elastic members 470 extend in the longitudinal direction so as to be installed at the respective corners. The elastic material 470 includes a first resilient material 471 provided at each corner between the back plate 480 and the side plates 430 and a second resilient material 471 disposed between the both side plates 430, And a second elastic material 472 installed at an edge between the plates 420.

The first resilient member 471 is formed in an 'a' shape and extends in the longitudinal direction. The first elastic material 471 is installed at an edge between the back plate 480 and the one side plate 430 and at corners between the back plate 480 and the other side plate 430, The back side edge is elastically supported. The first elastic member 471 is elastically supported such that the back surface and both side surfaces of the battery module 450 are spaced apart from the back plate 480 and the both side plates 430 of the case.

The second elastic member 472 includes a support protrusion 472a protruding to support a front side edge of the battery module 450 and a second protrusion 472b protruded from both sides of the circuit board 452 installed on the battery module 450, Respectively. The second elastic material 472 is positioned at the corner between the one side plate 430 and the front plate and at the corner between the other side plate 430 and the front plate 420, Are elastically supported so as to be spaced apart from both side plates 430 of the case, thereby preventing the circuit board 452 from being damaged.

The first elastic member 471 and the second elastic member 472 are installed at the corners of the unit battery pack 400 to absorb vibrations or shocks externally applied thereto, It is possible to prevent damage to the base 452. That is, since the unit battery pack of the present invention is supported by the elastic force of the first elastic member 471 and the second elastic member 472, the unit battery pack is safe from vibration or impact generated during operation of the electric vehicle.

In addition, the unit battery pack can shield the electromagnetic waves as the shielding material 460, which can shield electromagnetic waves, is adhered to the inner side of the bottom plate 440, the side plates 430, and the front plate 420.

As described above, the battery pack for an electric vehicle according to the present invention is used as a power source of an electric vehicle by connecting one or more unit battery packs as described above in series or in parallel. The assembling process of such an electric vehicle battery pack will be described below.

The operator places the first unit battery pack 400 and the second unit battery pack 400 'on the inner side of the housing 200 and inserts the screw holes 441a of the fixing tab 441, A screw 442 is inserted into the housing 200 and fixed to the spacing end 212 of the housing 200. At this time, the first unit battery pack 400 and the second unit battery pack 400 'are fixed to the bottom surface 213 of the housing 200 by the spacing 212.

Then, the operator fixes the electric panel 300 on the upper side of the first unit battery pack 400 and the second unit battery pack 400 '. The worker can move the first unit cell pack 400 and the second unit cell pack 400 'through the through holes 421 of the first unit battery pack 400 and the second unit cell pack 400' (BMS) 350 and the second BMS 350 'are connected to the connector 320.

The operator also connects the pole 451 of the first unit battery pack 400 and the second unit battery pack 400 'to the relay 330 installed in the electric panel 300. The relay 330 is connected between the first unit battery pack 400 and the output unit 340 of the second unit battery pack 400 ' And the power supply terminal 230.

Therefore, the first unit battery pack 400 and the second unit battery pack 400 'are connected to the power terminal 230 of the housing 200 in series or in parallel by the output unit 340.

Then, the operator fixes the cover 100 on the upper portion of the housing 200 after fixing the electric panel 300. At this time, the operator connects electric wires respectively connected to the operation panel 110 installed on the cover 100 to the main controller 310.

The operator connects the power connector 120 of the cover 100 to the power terminal 230 and connects the cable connected to the load of the electric car to the power connector 120. Although the connection structure between the power terminal 230 and the power connector 120 is shown in FIG. 4, a detailed description of the connection structure between the power terminal 230 and the power connector 120 will be omitted.

When the assembly of the battery pack is completed, the operator installs the battery pack in the receptacle of the electric vehicle using the handle 220, and turns on the power switch 111 to start supplying power to the load of the electric battery from the battery pack. Hereinafter, the main controller 310 controls the operation of the first unit battery pack 400 and the second unit battery 400, which are respectively applied through the first BMS 350 and the second BMS 350 ' It is determined through the temperature of the pack 400 'and the voltage detection signal whether or not an abnormal situation such as over discharge, high temperature and short of the battery pack occurs.

A method of controlling an electric vehicle battery pack under the control of the main controller 310 will be described with reference to FIG. 7 is a flowchart showing a control method of a battery pack for an electric vehicle according to the present invention.

Referring to FIG. 7, a control method of an electric vehicle battery pack includes a power on step S11 for supplying power to the unit packs 400 and 400 ' An abnormality determination step (S13) of determining an abnormality through the temperature and voltage sensing signal sensed in the sensing step (S12); and an abnormality determination step (S13) when an abnormality occurs in the abnormality determination step (S13) (S15) for determining whether the emergency switch (112) is turned on or not when the emergency switch (112) is turned on in the emergency switch on determination step (S15) A communication connector connection judgment step S17 for judging whether or not a communication terminal is connected to the communication connector 113 and is connected to the communication terminal 113; (Not shown) to transmit and receive data, Includes (S18) and a terminal (not shown), a log-information storage step (S19) for storing the log information according to the communication connection with.

The power on step S11 is a step of controlling the main controller 310 to switch on the relay 330 to supply power when the power switch 111 is turned on and a power on command is applied. Here, the operator turns on the power switch 111 of the operation panel 110 provided on the cover 100. Accordingly, when the power switch 111 is turned on and the power on command is applied, the main controller 310 controls the relay unit 330 so that the first unit battery pack 400 and the second unit battery pack 400 ' The power supply line connected to the power supply terminal 230 is switched on.

At this time, the first unit battery pack 400 and the second unit battery pack 400 'are connected in series or in parallel through the output unit 340. Accordingly, the power connector 120 outputs the power supplied from the first unit battery pack 400 and the second unit battery pack 400 'to a load of the electric vehicle through a connected cable. In the present invention, as described above, one or more unit battery packs are connected in series or in parallel to supply electric power to a load of an electric vehicle, so that it is possible to control the capacity required in an electric vehicle load. That is, according to the present invention, the numbers of the unit battery packs 400 and 400 'are increased or decreased, and the unit battery packs 400 and 400' are connected in series or in parallel, .

The sensing step S12 is a step in which the main controller 310 receives the temperature and voltage sensing signals of the unit battery packs 400 and 400 '. The first BMS 350 detects the temperature and voltage of the first unit battery pack 400 and applies the sensed temperature and voltage to the main controller 310 through the connector 320. Similarly, the second BMS 350 'senses the temperature and voltage of the second unit battery pack 400' and applies the sensed temperature and voltage to the main controller 310 through the connector 320.

Here, the electric vehicle may be subjected to vibration or impact during operation. However, the first elastic material 471 and the second elastic material 471 installed in the first unit battery pack 400 and the second unit battery pack 400 ' The battery pack 472 absorbs the vibration and impact, thereby preventing the battery pack from being damaged. In addition, the first unit battery pack 400 and the second unit battery pack 400 'may generate electromagnetic waves during power supply, but the electromagnetic wave generated from the battery module may be shielded by the shielding material 460 It does not affect the electronic equipment of the surrounding and / or electric car because it is not output to the outside.

The abnormality determination step S13 may be performed when the main controller 310 receives the temperature and voltage sensing signals respectively applied from the first BMS 350 and the second BMS 350 ' To determine whether or not an abnormality has occurred. The setting criteria include at least one of a temperature at which a fire is generated and a battery module 450 is damaged, a charging rate for preventing over discharge, and an abnormal voltage due to a short circuit. In addition, (Temperature and voltage (or current)) can be set in consideration of all the abnormal situations that can give an abnormality of the temperature.

If the main controller 310 determines in the abnormality determination step S13 that any abnormality such as high temperature, overdischarge, or short is detected, the alarming step S14 controls the alarming unit 114 And issuing an alarm. The alarm unit 114 outputs a light emission signal and / or an alarm sound under the control of the main controller 310 to alert the driver of an abnormal situation.

The emergency switch on determination step S15 is a step of determining whether the emergency switch 112 is turned on by the main controller 310. [ The driver of the electric vehicle can turn off the power supply of the battery pack by turning on the emergency switch 112 to prevent over discharge of the battery pack or a fire hazard when an alarm is issued in the alarm step. Therefore, the main controller 310 determines whether the emergency switch 112 is turned on after the alarm step S14.

Although the emergency switch-on determination step S15 has been described after the warning step S14, the emergency switch 112 may be turned on according to the driver's selection.

In the blocking step S16, the main controller 310 controls the relay 330 to shut off the power supply of the battery pack. When the emergency switch 112 is turned on in the emergency switch-on determination step S15, the main controller 310 controls the relay 330 so that the first unit battery pack 400 and the second unit battery pack 400 The power supply line connected to the pole 451 of the power supply 400 'is turned off to cut off the power supply. That is, the present invention can prevent damage due to over discharge of the battery pack or fire due to the emergency measure.

The communication connector connection determination step S17 is a step in which the main controller 310 determines whether there is a communication request to another communication terminal (not shown) connected to the communication connector 113. [ A driver or an administrator connects a communication cable, which is connected to a terminal (not shown) having a program and a device capable of communicating with the battery pack, to the communication connector 113. Therefore, the communication connector 113 applies the connection signal to the main controller 310.

The data transmitting and receiving step S18 is a step in which the main controller 310 receives the data stored by the control command applied through the communication connector 113 or the data transmitted from the terminal (not shown). The operator operates his / her terminal (not shown) through the communication connector 113 to compare the program and data (for example, temperature and voltage setting reference) of the main controller 310 with the first ratio The operating program of the MS (BMS) 350 and the second BMS 350 'may be modified.

The log information storing step S19 is a step of storing the log information having the time and date at which the main controller 310 is connected to the communication connector 113 with the terminal (not shown) and the operation contents (name of the transmission / reception data and file type) And storing the information in its own memory. The log information may be provided by the administrator in the data transmission / reception step for maintenance of the battery pack.

Although it has been described that the communication connector connection determination step S17 to the log information storage step S19 are performed after the sensing step S12, it is possible that the communication connector connection determination step S17 may be performed after the blocking step S16, It is possible to be performed at any time from step S11 to step S16.

The present invention can generate and supply the rated capacity necessary for the load of the electric vehicle by connecting the electric vehicle battery pack to one or more unit battery packs in series or in parallel so that the output capacity of the battery pack Can be adjusted. In addition, the unit battery pack can be protected from impact or vibration, and can shield electromagnetic waves, so that the unit battery pack does not affect sensitive electronic equipment of an electric car or the surroundings.

That is, the present invention can provide a battery pack for an electric vehicle having a configuration and an action optimized for an electric vehicle.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

100: Cover 110: Operation panel
111: Power switch 112: Emergency switch
113: communication connector 114:
120: power connector 130, 213a, 441a:
200: housing 220: handle
230: power terminal 300: full length panel
310: main controller 320:
330: Relay 340: Output section
350, 350 ': BMS 400, 400': Unit battery pack
410: upper cover 411: handle
420: front plate 421: through hole
430: side plate 440: bottom plate
450: Battery module 451: Polar
452: circuit board 453: connector
460: Shielding material 470: Elastic material
471: first elastic material 472: second elastic material
480: rear plate

Claims (7)

1. An electric vehicle battery pack for supplying electric power to an electric vehicle,
At least one BMS sensing a voltage and a temperature of the one or more unit battery packs fixed to the inside of the housing;
A relay for switching a power supply line connected to a power connector of the unit battery pack;
A main controller for comparing the detection signal of the temperature and voltage of the unit battery pack applied from the BMS with a setting reference to determine whether there is an abnormality and controlling the relay; And
And an alarm unit for alarming an abnormality by the control of the main controller,
The unit battery pack
A case for accommodating a battery module to which at least one battery cell is connected, and an upper cover for sealing an upper portion of the case; And
And one or more elastic members extending longitudinally from an inner edge of the case to elastically support the battery module and the circuit board,
The elastic material
A first elastic member elastically supporting the back surface and both side surfaces of the battery module so as to be spaced apart from the inner surface of the case; And
And a second elastic member for elastically supporting the front surface of the battery module, the second elastic member including an insertion groove which is inserted inward to insert a rim of the circuit board installed in the battery module, The battery pack comprising:
The battery pack according to claim 1, wherein the battery pack
An emergency switch for applying an emergency power off command; And
And a communication connector to which a communication cable is connected.
delete The battery pack according to claim 1,
Wherein a shielding material for shielding electromagnetic waves is adhered to a wall surface and a bottom plate of a case for accommodating the battery module to which at least one battery cell is electrically connected.
2. The apparatus of claim 1, wherein the housing
Wherein the battery pack is formed so as to be spaced apart from the bottom plate of the unit battery pack.
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