KR102364203B1 - battery system having heater system for heating battery for electric vehicle - Google Patents

Abstract

The battery constituting the power source of the electric vehicle, the heater connected in series with the battery, the contactor installed in the conductor between the battery and the heater and responsible for the switching function, and combined with the battery to control the operation of the battery and to give the contactor a switching signal. Disclosed are a heater system for heating a battery for an electric vehicle and a battery system for an electric vehicle having the same, which is provided with a BMS capable of detecting the battery temperature and a temperature sensor capable of transmitting a related signal to the BMS. Here, when the contactor receives a signal from the BMS and performs switching, the switch-on signal, that is, the signal to close the switch, is made by a pre-prepared program, and the program proceeds according to the temperature detected by the temperature sensor of the battery. In addition, the signal may be in the form of a pulse and the magnitude of the pulse may be transmitted in a manner that adjusts the amount of electricity delivered according to the duty cycle in a constant state.

Description

Battery system for an electric vehicle having a heater system for heating a battery for an electric vehicle {battery system having heater system for heating battery for electric vehicle}

The present invention relates to a heater system for heating an electric vehicle to enable battery operation in a low-temperature environment where battery operation is difficult in an electric vehicle, and a battery for an electric vehicle having the same, and more particularly, to a battery for an electric vehicle having the same, which can simplify the overall configuration and increase safety It relates to a heater system having a configuration and a battery system for an electric vehicle having the same.

Due to the strengthening of international environmental regulations on automobile exhaust gas, the possibility of oil depletion, and the continued high oil price, the global automobile market is turning its eyes from internal combustion engine vehicles to electric vehicles. In particular, pure electric vehicles (EVs) are emerging as an effective global greenhouse gas reduction means and a powerful alternative for a sustainable environment. Meanwhile, sales of electric vehicles (EVs) and hybrid vehicles (HEVs) are increasing significantly as consumers' preference for low-cost fueled vehicles increases due to the burden of rising fuel costs. As a result, advanced countries are strongly promoting electric vehicle supply policies.

Therefore, the capacity and efficiency of the battery, which are key components for operating an electric vehicle, are the most important factors for an electric vehicle, and the drivable distance according to the performance is a big issue. this is rising

Conventionally, lead-acid batteries have been mainly used for electric vehicle batteries, but since lead-acid batteries are used as a vehicle power source, the amount of electricity that can be stored compared to weight and volume, i.e., charge capacity, is low, so lithium, which can increase the charge capacity compared to weight, is a battery for electric vehicles. This series of batteries is mainly used.

A battery is basically a device made to make chemical energy compatible with electrical energy, and the use of a secondary battery capable of charging and discharging together is a basic premise due to the characteristics of a vehicle.

However, the chemical reaction that takes place inside the battery is affected by environmental conditions like general chemical reactions, and in particular, it is greatly affected by temperature. For example, in a high temperature range where self-stability is lowered due to an abnormal reaction and self-damage may occur, the battery itself may be damaged and a vehicle fire may occur.

Conversely, in a low-temperature, cold-weather environment where the chemical reaction is reduced, the battery may not exhibit sufficient efficiency, which may eventually make it difficult to drive the vehicle itself.

Lithium-ion battery packs, the most used for electric vehicles, have poor performance at low temperatures in winter under conditions such as Korea, where the four seasons are distinct, making it difficult to provide sufficient power to the vehicle. and the charging time is increased. For example, even if the temperature is about -6°C, the battery cannot be fully charged due to the increase in resistance when charging, and the output performance is less than 50% due to the output degradation phenomenon. Therefore, there is also a problem of increasing the battery maintenance cost.

This problem becomes more problematic in the winter when the temperature exceeds tens of degrees below zero in high latitude countries such as Russia, Canada, and Northern Europe, and in a car that must be used at any time, this problem can be a fatal disadvantage in terms of availability. .

Accordingly, the electric vehicle uses a means such as a heater for heating the battery as a means for maintaining the battery temperature in a predetermined band in order to cope with the problems of reduced efficiency and inability to drive the vehicle due to a drop in ambient temperature.

Conventionally, in order to increase the temperature of the battery, a heater may be operated using an external power source for a separate heater, or a heat pump system using heat from a battery and an inverter for driving a motor may be used. These methods can be seen as a method of heating the battery indirectly, rather than a method of directly transferring heat by attaching a heater to the battery itself.

The method of operating a heater using an external power source requires a separate power source and requires a space for installing the separate power source, and there is a problem in that the cost for this is also increased.

The method of using a heat pump also requires a separate configuration for the heat pump, and moreover, there is not much heat generated from the battery and inverter. There is a bad problem.

Republic of Korea Patent Registration No. 10-1943536

An object of the present invention is to provide a means for efficiently solving problems in which a battery for an electric vehicle deteriorates in performance and efficiency in a low-temperature environment.

The present invention provides a heater system for heating to maintain a temperature range suitable for battery operation, and a battery system for an electric vehicle having the same, but having a configuration that can reduce the hassle and cost of installation, maintenance and operation, and having the same An object of the present invention is to provide a battery system for an electric vehicle.

A heater system for heating a battery for an electric vehicle of the present invention for achieving the above object,

The battery constituting the power source of the electric vehicle, the heater electrically connected in series with the battery, the contactor installed in the conductor between the battery and the heater and responsible for the switching function, the contactor that controls the operation of the battery in combination with the battery and provides a switching signal to the contactor A battery management system (BMS) capable of detecting the battery temperature is provided with a temperature sensor capable of transmitting a related signal to the BMS.

The heater system of the present invention may further include a thermal protector that detects overheating of the heater and blocks the heater operation.

In the present invention, it may further include a current sensor installed on a portion of the wire between the battery and the heater to transmit a signal according to the amount of current to the BMS.

In the present invention, the contactor may be connected to a low voltage through a voltage change in the battery or may be driven by a separate low voltage auxiliary battery. The BMS can keep the contactor closed, and when a certain temperature is exceeded, the bimetal switch can be opened to cause the BMS to switch the contactor to the open state.

In the present invention, the contactor may be provided with a solenoid switch mechanically operated by receiving an electrical signal.

In the present invention, when the contactor receives a signal from the BMS and performs switching, a switch-on signal, that is, a signal for putting the switch in a closed state, may be made by a program prepared in advance. In this case, the program may be performed according to the temperature detected by the temperature sensor of the battery. At this time, when the current transmitted from the battery to the heater is controlled in proportion to the signal, the signal is in the form of a pulse and the magnitude of the pulse is constant. A method of controlling the amount of electricity delivered according to the duty cycle may be transmitted to

The battery system for an electric vehicle of the present invention is characterized by comprising the heater system of the present invention.

In the battery system for an electric vehicle of the present invention, a heat sink is disposed between a plurality of pouch-type or prismatic battery cells having a large area compared to the thickness so that at least one surface of the battery cell is in contact with the heat conduction plate, and each heat conduction plate At least a portion of the heater block may include a battery module configured to transfer the heat of the heater to the battery cells in contact with the heater, and the heater is a heater block or It may be formed in the form of a heater plate (heat plate).

At this time, the heat plate may have a form in which a heater heating wire is installed on a linear portion in contact with the heat conduction plate, and a silicon heat conduction film or plate as a heat conductor as a medium for adhesion to the surface in contact with the heat conduction plate may be installed on the hot plate.

An insulating material, such as urethane foam, which blocks heat conduction may be installed on the surface opposite to the surface in contact with the heat conduction plate of the hot plate.

According to the present invention, the configuration of the heater system can be simplified by attaching an electric DC heater operated by the power of the battery itself, which provides power to the electric vehicle, directly to the battery, and high voltage can be used to generate a lot of heat in a short time. Therefore, it is possible to shorten the heating time of the battery and increase user convenience.

According to the present invention, the user can use the battery efficiently for a longer period of time by heating the battery within the guarantee temperature for use by applying the electric heater and then operating the electric vehicle in a normal state, thereby preventing deterioration of lithium-ion battery performance and lifespan and reduced efficiency. and battery replacement cost can be reduced.

1 is a schematic configuration diagram showing the main configuration of a heater system according to an embodiment of the present invention;
2 is an exemplary configuration conceptual diagram showing an embodiment of a heater system blocking configuration by a thermal protector in the present invention;
3 is an exploded perspective view showing an exemplary configuration of a battery system for an electric vehicle having a heater system of the present invention;
4 is an exemplary view of the heater configuration of the battery as shown in FIG. 3 viewed from various directions.
5 is a flowchart illustrating an example of a method for operating a heater according to the present invention.

Hereinafter, the present invention will be described in more detail through specific examples with reference to the drawings.

1 is a box diagram conceptually illustrating a heater system according to an embodiment of the present invention.

Here, the heater system is a location where the heater system is installed and is a target of heating the battery 10, the BMS 103 that controls the battery, the heater 100, a temperature sensor (not shown), and a thermal protector which is one of the temperature breaker 105 , a contactor 102 , a current sensor 104 , and a fuse 101 .

The heater 100 is directly connected to an electrical terminal of a battery to be heated, and receives direct electrical energy to generate heat. In the wire connecting the heater 100 and the battery in series, there is a fuse 101 that is blown when an overcurrent flows, a current sensor 104 that checks the amount of current flowing in the wire, and a contactor 102 that acts as a kind of switch that regulates the wire ) is installed. The BMS 103 may be viewed as integral with the battery, but is displayed separately here, and may signal to be responsible for the operation and control of the battery. The BMS and, in this regard, the signal can operate at a different low voltage than the high voltage of the battery itself.

The BMS 103 is connected to the contactor 102 to give an opening/closing signal to the contactor, and receives information about the battery temperature from a temperature sensor (not shown) attached to the cell of the battery and sends it to other elements of the heater system. It can send the necessary action signals.

According to this configuration, the temperature level detected by the temperature sensor installed on the battery can be checked through the display device installed on the vehicle dashboard, and on the premise that the vehicle user recognizes that the battery is below the appropriate temperature and operates the heater system, first When the heater system start button is pressed, the BMS heats the battery cells by flowing current from the battery to the heater. Normally, when the key of the car is turned on (on), the heater operation is automatically performed by recognizing the temperature of the cell.

In this case, the BMS may give a signal so that the contactor is in a closed state so that a current flows through the wire connected to the heater. When the contactor is in the closed state, current flows and the heater generates heat through resistance wires such as nichrome wire embedded in the heater plate to heat the cell.

In this embodiment, the switch-on operation of the contactor may be performed by a signal given through a program built into the BMS itself. This signal may be a constant signal of a certain magnitude, but may also be a periodic pulse type signal. For example, the BMS knows the current temperature through the temperature sensor installed in the battery, calculates the difference from the proper temperature of the battery, derives the amount of heat to be applied to the battery to compensate for the difference, and uses a heater to supply this amount of heat. You can send the required signal by calculating the current and time to send.

Assuming that the current is set constant by the hardware configuration of the battery and heater system, it is enough to calculate the time appropriate for this current. If the BMS signal is a periodic pulse type signal, the pulse signal can be sent to the contactor by setting the supply time of one pulse, the pulse period, and the duration of the periodic pulse supply.

Of course, not all current or electrical energy is used to increase the temperature of the battery, and some of it leaks to the outside. You can set the amount of electricity. If the period for which the periodic pulse supply is extended increases the amount of heat leaked between them, more electrical energy must be supplied in consideration of this. There may be problems with cells, etc. Of course, since the cell temperature by the BMS is constantly monitored, the heater operation is usually stopped when it is determined that the cell is overheated.

In some cases, it is desirable to quickly increase the low battery temperature at first, and since the possibility of damage to the battery is low at low temperatures, it is necessary to set the supply period from the beginning and the supply time of one pulse to be constant for the duration of the pulse supply period. As a whole, the supply time decreases as the battery temperature increases, and accordingly, the current supply type can be designed through a program so that the amount of electricity supplied per hour decreases.

On the other hand, the supply of current from the battery to the heater may be interrupted by devices such as an ammeter and a fuse. In this case, they can be one of multiple safeguards to prevent heater overheating.

For example, there is an ammeter among the series connection wires connecting the heater and the battery. When the ammeter detects an abnormal current such as overcurrent, the signal of the ammeter is transmitted to the BMS, and when the BMS receives this signal, it sends a signal to the contactor The fuse can block the overcurrent by directly generating heat when an overcurrent flows through the series-connected conductors, melting itself and breaking the conductors.

In addition, in this embodiment, a thermal protector is installed in the heater to check whether the temperature of the heater itself is not overheated while electricity is supplied to the battery. For example, in the case of a bimetal type thermal protector, when the heater overheats and exceeds a certain temperature, the bimetal inside the thermal protector constituting the overheat prevention circuit is deformed to open the bimetal switch, and the current flowing through the overheat protection circuit is cut off. .

This overheat protection circuit can activate the contactor's current blocking function either directly or via the BMS. For example, a current cutoff by a bimetal switch in the overheat protection circuit is sensed by the BMS, and then the BMS may signal a contactor to cut off the electrical energy transferred from the battery to the heater.

Alternatively, as shown in FIG. 2 , the overheat prevention circuit may directly cause the switching of the contactor 202 irrespective of the BMS. In this case, current supply and cut-off by switching the contactor is not made simply by the BMS signal by the program built into the BMS as described above, but a separate means related to the overheat prevention circuit, such as the contactor operating coil ( 201) For example, it can be achieved by means such as a solenoid coil switch.

In this case, the contactor has a switch part that is physically and mechanically switched by the electromagnetic force generated from the solenoid coil, and when the current flowing in the overheat prevention circuit is blocked by the thermal protector 205 such as a bimetal, the electromagnetic force of the solenoid coil disappears, As the switch portion is deformed by the action of, for example, elasticity, it may be in an open state, and current from the battery to the heater 200 may be cut off.

3 is an exploded perspective view illustrating an example of a battery for an electric vehicle having a heater system of the present invention, and exemplarily shows a more specific configuration of the battery and parts constituting the heater system.

Here, as in the general form, individual pouch cells are combined to form a battery module, and the battery modules form one battery pack or subpack.

In general, the smallest structural unit capable of charging and discharging having energy for manufacturing a battery is expressed as a cell, and a battery of a desired specification, that is, a battery pack, is made by combining these cells. Here, a battery pack is made by connecting several pouch cells, a type of lithium ion polymer secondary battery, in series and in parallel.

To form the battery module, the thin periphery or sealing part of the individual pouch cells is sandwiched between the left and right subframes forming one individual frame in the form of a quadrilateral frame, so that the individual frames form a pouch assembly together with the pouch cells. do. In this case, in the pouch assembly, both large-area surfaces of the pouch cell are exposed, and the electrode terminals of the pouch cell are exposed through the gap between the left and right subframes in front and rear of the pouch cell.

A heat sink made of an aluminum plate having excellent thermal conductivity is positioned between the two pouch assemblies, and the heat sink can exchange heat by contacting the pouch large area surfaces (left and right side surfaces) of the two adjacent pouch assemblies. The front end of the aluminum plate is exposed to the front through a gap between two adjacent individual frames and has an enlarged portion with an enlarged area to increase heat exchange efficiency with the heater.

The enlarged part can be made in a T-shape or L-shape in a plan view viewed from above or a flat cross-section cut horizontally, and the enlarged part is formed by bending a part of the aluminum plate in contact with the pouch, or when the aluminum plate is injection molded, such a shape is created from the beginning. It can be formed to have

In a state in which a plurality of pouch assemblies are arranged and overlapped left and right so that the large-area faces face each other, and a plurality of individual frames of the pouch assembly are also arranged in the left and right sides, the individual frames have through holes penetrating the individual frames in the left and right directions. installed, a single long bolt penetrates these holes and a nut is filled at the end of the bolt, so that a plurality of pouch assemblies form a battery module as indicated by the first arrow on the right in FIG. 3 .

Here, a plate-shaped protection panel is installed at the left and right ends of the plurality of arranged pouch assemblies to protect the battery module. The protective panel also has through-holes aligned with the through-holes of the individual frames, so that they can be coupled together with a plurality of pouch assemblies using bolts and nuts.

Although the electrode terminal of the pouch cell is not clearly shown here, it is connected to the circuit part for the battery module, which is a connector with the BMS and largely forms a part of the BMS through a general wire or FPCB-type wire. The circuit unit for the battery module may be installed on a cover plate that covers the plurality of pouch assemblies in whole or in part at an upper portion of the battery module.

On the front surface of the battery module, enlarged portions of a plurality of heat sinks 300 (aluminum plates) exposed between individual frames in a plurality of pouch assemblies are positioned side by side, and a thermal pad 301 is coupled thereto.

The two battery modules formed in this way are put in a container-shaped case as indicated by the second arrow on the left of FIG. 3 in a state in which the thermal pad 301 is coupled, or a separate protective or fixing bracket, panel, or frame to form an exterior. combined to form a battery pack. In the process, as is well known, the electrode terminals of the battery are collectively connected in series and parallel to the electrical terminals for external supply of the battery pack, the electrical terminals of the BMS, and also to the heater through the electrical terminals.

In the process of forming the battery pack, a heater, more specifically, a heater plate 302 including a heating element constituting a heater system, may be coupled to the front surface of the battery module to which the thermal pad is coupled so as to be in close contact.

In relation to the use of the thermal pad 301, usually the heater plate 302 is made of a thermally conductive rigid body including a heating element that converts battery current into Joule heat to generate heat, and the enlarged part of the aluminum plate constituting the heat sink is also a rigid body. , If both contact surfaces are not very even, it is easy to create a floating part when contacting, and a fine air layer is formed in this part, which reduces the heat conduction efficiency.

Therefore, it is preferable to use a soft thermal pad that guarantees adhesion between the enlarged part and the heater plate so that it partially deforms when a slight pressure is applied and fills the gap to facilitate heat conduction between the two. As the thermal pad, a silicon pad having excellent thermal conductivity may be generally used. Here, the silicon pad has adhesiveness so that it can be well coupled to the heater plate and the enlarged part without a separate means.

The thermal pad also acts to prevent thermal runaway. That is, if the heater does not come into contact with the heat transfer material (heat sink), the heater itself causes a risk due to thermal runaway. prevent thermal runaway.

The rear side of the battery module may also have the same configuration as the front side and connected to the heater, and in case the battery requires cooling rather than heating, a separate thermal conductor cooling plate is installed instead of the heater plate and is connected through a heat sink and a thermal pad. can make it The cooling plate forms a part of the cooling system and may be connected to a radiator device to increase cooling efficiency, and may be directly cooled by cooling wind by a cooling fan or by circulating cooling water.

Referring to Figure 4, one side of the heater plate becomes the heating element attachment surface 400 that generates heat, and on the opposite surface (opposite surface of the heating element attachment surface: 401), urethane foam such as a sponge for preventing heat transfer and preventing damage due to vibration, etc. of synthetic resin foam layer is installed. On the opposite side, a wire connector for power supply and a thermal protector 403 are installed. At this time, since the silicone material is already covered where the thermal protector is installed, the synthetic resin foam is not installed. The heater plate is provided with a power wire for connecting the heater power supply battery to the heater heating element, and a signal wire 402 connected to the thermal protector 403 .

Herein, the operation method of the heater system will be described more by way of example. The heater is a DC resistance heater having a fixed resistance value, and the heater power is variable according to the battery power (battery voltage * current flowing in the battery) applied to the resistor. do. Heater power is determined according to user requirements and characteristics of the battery used.

For example, the user may require a specific amount of time it takes to heat the battery to the minimum temperature required for the desired battery output.

In the method of directly transferring heat by attaching a heater to the battery, there is a risk of a battery fire due to thermal runaway of the heater. Therefore, the configuration of electric parts that can control the heater and the role of the BMS (Battery Management System) control circuit are important.

It is also important to design and apply a product that can effectively transfer the heat of the heater to the battery without loss.

Accordingly, the heater system as described with reference to FIGS. 1 and 2 of the present invention can be applied, and if the operation method is described in a different aspect from the previous description through this embodiment, the heater system uses battery power Electric direct current heater (heater plate) to increase the temperature of the heater, switching element (contactor) to control the heater, current sensing element (current sensor) to sense the heater current, thermal pad and thermoelectric to increase the heat transfer efficiency of the heater It is composed of a heat sink, which is an aluminum plate made of a cermet, a temperature sensor that senses the temperature of the cell, which is the smallest unit constituting the battery, and a BMS (Battery Management System) that controls the operation and stop of the heater through the temperature sensor. .

In addition, the heater itself has a built-in temperature control element called a thermal protector that blocks the operation of the heater when the temperature exceeds a certain level.

The BMS 103 is operated when the key of the vehicle is turned on, and thereafter, it diagnoses all states of the battery and prepares to proceed with the user's request. At this time, the temperature of all cells constituting the battery is also monitored by the BMS in real time.

And if there is a cell below the cell manufacturer's guaranteed temperature among all the cells, BMS operates the heater and stops the heater when all the cells reach the guaranteed temperature.

The heater has a line that supplies operating power (power wire) and a thermal protector line (overheat prevention circuit line, part of signal wire) that shuts off when a certain temperature is reached and controls the temperature. A line supplying power is connected and disconnected using a heater driving switch or contactor 102, which is controlled by the BMS.

The thermal protector line is connected to the contactor driving coil 201 of the contactor, which is a switch for driving the heater, to block the operation when the temperature of the heater is physically higher than the limit temperature even in the BMS failure state. In addition, the BMS constantly monitors the current input to the heater power line through the current measuring sensor 104, and stops the heater operation when the limit condition is exceeded. In addition, since there is a separate DC fuse 101 in the heater power line, it is possible to physically stop the heater operation when the BMS does not function properly. The heater operation sequence will be described in more detail below.

BMS stops the heater operation when the temperature of even one cell among all the cells becomes 20°C or higher. This prevents the heater from continuously operating due to temperature imbalance of the battery. BMS stops the heater operation when the current input to the heater exceeds the limit value. BMS stops the heater operation when the heater operation time exceeds the limit value. The heater is automatically operated by the BMS internal algorithm or program.

5 is a flowchart illustrating a process or algorithm serving as a reference for operation of a heater system. Here, it starts from the step S500 of determining whether a connector for external power input for driving the heater is connected and a command message to operate the heater is received. However, this step is an option used only when an external power source is used, and is not necessary when using the battery's own power as in the present application.

In the next step, the temperature of all the cells constituting the battery is sensed, and it is determined whether the heater operation condition is satisfied (S501).

And if the heater operation condition is satisfied, the power switch (contactor) for driving the heater is turned on to operate the heater (S502).

Thereafter, it is determined whether the current input to the heater through the current sensor exceeds a limit value (S503).

If the current is within the normal range, it is determined whether the cell temperatures of all batteries have reached the heater operation release condition (S504), and if the condition is reached, the heater operation is stopped (S505). Of course, if the current is out of the normal range, the cell temperature It is possible to block and control the current flow in the BMS without judgment.

In the above, the present invention has been described with reference to the limited examples, but the present invention is not limited to these specific examples.

Accordingly, those of ordinary skill in the art to which the present invention pertains will be able to make various changes or application examples based on the present invention, and it is natural that such modifications or application examples belong to the appended claims.

10: battery
100, 200: heater
101: fuse
102, 202: contactor (switch)
103: BMS (Battery Management System)
104: current sensor (current measuring sensor)
105, 205, 403: thermal protector
201: contactor operation coil (solenoid coil)
300: heat conduction plate (Heat sink)
301: thermal pad (Thermal pad)
302: heater (heater plate)
400: Heater heating surface (Aluminum foil)
401: Heater heating opposite side (Sponge)
402: wire

Claims (9)

A battery comprising a battery module in which a heat conduction plate is disposed between a plurality of pouch cells, and at least a portion of the heat conduction plate is in contact with a heater to transfer the heat of the heater to the pouch cells;
the heater electrically connected in series with the battery;
a contactor installed in a wire between the battery and the heater to perform a switching function;
BMS (battery management system) that is combined with the battery to control the operation of the battery and give a switching signal to the contactor;
and a heater system for heating a battery for an electric vehicle comprising a temperature sensor capable of detecting a temperature in the battery and transmitting a temperature signal to the BMS,
The heater is made in the form of a heater plate (hot plate) to which a plurality of the heat conduction plates installed side by side while overlapping a plurality of pouch cells can come into contact with each other,
A silicon heat conductive film or plate, which is a heat conductor, is installed on the heater plate as a thermal pad as a medium for adhesion to the surface in contact with the heat conductive plate,
The battery system for an electric vehicle, characterized in that the heating plate is provided with an insulating layer to prevent heat dissipation to the outside on a surface opposite to the surface in contact with the heat conduction plate. 2. The method of claim 1
A battery system for an electric vehicle further comprising a thermal protector that detects overheating of the heater and blocks the operation of the heater. The method of claim 1,
A battery system for an electric vehicle further comprising a current sensor and a fuse installed in a part of a conducting wire between the battery and the heater to transmit a signal according to an amount of current to the BMS in series. 3. The method of claim 2,
The contactor is a temperature controller installed in the heater and is configured so that the bimetal switch is normally closed below a certain temperature,
A current signal passing through the bimetal switch directly switches the contactor, or
A battery system for an electric vehicle, characterized in that the BMS maintains the contactor in a closed state by flowing the current signal, and when a predetermined temperature is exceeded, the bimetal switch is opened so that the BMS switches the contactor to an open state . 5. The method of claim 4,
In order to directly switch the contactor, the contactor is provided with a solenoid coil switch mechanically operated by receiving the current signal. The method of claim 1,
When the contactor receives a signal from the BMS and switches the current from the battery to the heater
The switching signal is made by a program built into the BMS,
The program is a battery system for an electric vehicle, characterized in that the progress according to the temperature sensed by the temperature sensor. 7. The method of claim 6,
The switching signal is made in the form of pulses of the same magnitude and is made to control the amount of electricity delivered according to a duty cycle (use rate).
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