KR101878807B1 - Battery experiment apparatus - Google Patents

Abstract

The present invention provides a liquid crystal display device comprising a first cell plate having a plurality of openings passing through one side surface and another side surface and a second cell plate having openings at positions corresponding to the plurality of openings of the first cell plate, A case in which a plurality of cell plates are disposed inside, a case in which a plurality of cell plates are provided in a number corresponding to the number of openings formed in each of the plurality of cell plates, And a bar heater of the battery.

Description

[0001] The present invention relates to a battery experiment apparatus,

The present invention relates to a battery testing apparatus. Specifically, in order to test the performance of a cooling plate for cooling an exothermic battery, it is an apparatus for simulating the exothermic characteristics of an actual battery.

There is a battery that supplies electricity. Particularly, a battery using a high voltage such as a battery of an electric vehicle has a high heat generating characteristic.

When using a battery with such a high heat characteristic, it is necessary to use a cooler that cools it.

When experimenting with the cooling performance of a cooler for a high voltage battery, using a real battery can lead to safety accidents such as battery exploding or an electric shock to the experimenter.

Further, it is difficult to predict the precise heat generation condition of the battery, and there are various limitations in the process of transporting the battery, so that it is difficult to use the actual battery for the cooling test of the battery.

Accordingly, a battery test apparatus simulating a heat generation characteristic similar to an actual battery is being studied.

SUMMARY OF THE INVENTION An object of the present invention is to provide a battery test apparatus for simulating the heat generation characteristics of an experimental sample battery.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a battery testing apparatus according to an embodiment of the present invention may include at least one cell plate corresponding to a battery cell included in an experimental sample battery and a case in which the at least one cell plate is disposed , The arrangement of the at least one cell plate in the case may correspond to the arrangement of at least one battery cell present in the experimental sampled battery.

The details of other embodiments are included in the detailed description and drawings.

According to an embodiment of the present invention, there is one or more of the following effects.

First, there is an effect that the heat characteristic of the actual battery can be judged without using the actual battery.

Secondly, since the battery testing device simulates only the heating characteristics of an actual battery, it can prevent a safety accident that may occur when the battery is actually used.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a view for explaining an experimental sample battery and a plurality of battery cells included therein.
2 is a side view showing a case where an experimental sample battery is disposed on a cooling plate.
3 is a diagram for explaining the temperature unbalance that occurs in the test specimen battery.
4A is a view for explaining a cell plate corresponding to a battery cell included in an experimental sample battery.
4B is a view for explaining a bar heater inserted in a cell plate.
5 and 6 are views for explaining the arrangement of the case and the cell plate constituting the battery testing apparatus according to the present invention.
FIG. 7 is a diagram for explaining an experimental result in which a battery testing apparatus according to the present invention simulates a heating state of an experimental sample battery.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role. In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be blurred. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. , ≪ / RTI > equivalents, and alternatives.

Terms including ordinals, such as first, second, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The singular expressions include plural expressions unless the context clearly dictates otherwise.

In the present application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

The battery test apparatus according to the present invention is an apparatus for simulating the actual heat generation state of a battery in order to confirm the performance of a cooling plate for cooling the battery. The cooling plate is a device that is attached to a specific portion of the battery to cool the battery.

When testing the performance of the cooling plate, there are various limitations when using real batteries. For example, if the actual battery is a battery of an electric vehicle using a high voltage, there is a risk of electric shock, fire, and explosion. According to an embodiment of the present invention, when an apparatus for simulating the actual state of the battery is used instead of an actual battery, the above-described accident can be prevented.

The actual battery may have non-uniform heat generation characteristics due to the internal structure and the characteristics of the components. For example, in an actual battery, the temperature at a portion where an electrode for supplying electrical energy is present may be higher than the temperature at another portion. Also, depending on the internal structure of the battery, the temperature of the portion where the circuit is dense may be relatively high.

The battery test apparatus according to the present invention can simulate the non-uniform heat generation characteristics of an actual battery. Accordingly, it is possible to test the cooling performance of the cooling plate by attaching the battery testing device to the cooling plate instead of the actual battery.

In one embodiment of the present invention, the actual battery is referred to as an experimental sample battery. The test specimen battery according to the present invention may be an apparatus that converts chemical energy into electric energy to supply electricity. The test specimen battery may be a secondary battery capable of charging and discharging several times. The test specimen battery may be a high voltage battery used in automobiles, electric vehicles, and hybrid vehicles.

The test specimen battery may include at least one battery cell. The battery cell may be one secondary battery. The battery cell may have non-uniform heat generation characteristics. The battery cell itself may also be a high voltage battery. In this case, the test specimen battery may be a high voltage battery to which a plurality of high voltage batteries are connected.

Hereinafter, an experimental sample battery 200 simulated by the battery testing apparatus 100 according to the present invention will be described first, and then the battery testing apparatus 100 will be described.

1 to 3 are views for explaining an experimental sample battery 200. FIG.

1 is a view for explaining an experimental sampled battery 200 and a plurality of battery cells 210 included therein.

The test specimen battery 200 may be a battery capable of supplying actual electricity. The test specimen battery 200 may be a rectangular parallelepiped. Alternatively, the shape of the test specimen battery may be various shapes such as a cube, a cylinder, a sphere, and a cone.

The test specimen battery 200 may be a plurality of battery cells connected in series. The test specimen battery 200 may include a plurality of battery cells 210a to 210e. Unlike the drawing, the experimental sample battery 200 may include one battery cell.

The plurality of battery cells 210a to 210e may be fixed by the battery cell case 240. [ A plurality of battery cells 210a to 210e may be disposed in the battery cell case 240. [ For example, the plurality of battery cells 210a to 210e may be arranged in a line at regular intervals. In addition, the plurality of battery cells 210a to 210e may be disposed in close contact with each other or may be arranged in various forms. The battery cell case 240 can provide an appearance of the test specimen battery 200.

The shape of the battery cell may vary. For example, the plurality of battery cells 210a through 210e may be in the form of a rectangular plate. The plurality of battery cells 210a to 210e may be in the form of a cube, a cylinder, a sphere, or the like.

For example, the battery cell may be a unit comprising a positive electrode plate and a negative electrode plate group in an electrolyte solution. The battery cell may be composed of a positive electrode and a negative electrode plate covered with an electrolytic solution. For example, the battery cell may be a secondary battery utilizing lithium ion, lithium polymer, nickel hydrogen, nickel cadmium, and the like.

For example, one battery cell included in an experimental sampler battery can generate a voltage of about 2 volts. For example, an experimental specimen battery that generates 12 volts may have a structure in which six battery cells are connected in series.

2 is a side view showing a case where an experimental sample battery is disposed on a cooling plate.

The test specimen battery 200 may be attached to the cooling plate 220. A thermal pad 221 may be provided between the cooling plate 220 and the test specimen battery 200 to attach the specimen battery 200 to the cooling plate 220. [ The thermal pad 221 can attach the cooling plate and the test specimen battery 200 to each other. The thermal pad 221 may be a double-sided tape type thermal conductive tape. For example, the thermal pad 221 may attach the lower end of the experimental sam- ple battery 200 and the upper end of the cooling plate 220. In this case, the lower end of the battery cell 210 and the upper end of the cooling plate 220 can be attached. Unlike the drawing, the cooling plate 220 may be attached to the other side of the battery cell or may be attached to two or more sides. In addition, the cooling plate 220 may be configured to surround the battery cell 210.

The battery cell 210 may include a positive electrode 250a and a negative electrode 250b. The battery cell 210 receives and stores electric energy through the positive electrode 250a and the negative electrode 250b and discharges the stored electric energy through the positive electrode 250a and the negative electrode 250b have. When the battery cell 210 is discharged or charged, the temperature of the battery cell 210 can be raised. In this case, the exothermic temperature near the electrode may be relatively higher than the temperature of the remaining portion. Accordingly, a temperature variation of the battery cell 210 may occur.

The battery cell 210 may include a plurality of temperature sensors for measuring temperature. For example, the battery cell 210 includes a first temperature sensor 230a, a second temperature sensor 230b, a third temperature sensor 230c, a fourth temperature sensor 230d, a fifth temperature sensor 230e, And a sixth temperature sensor 230f.

 The point where the plurality of temperature sensors 230a to 230f are arranged on the battery cell 210 can be called a temperature measurement point. The temperature measurement point 260 may be the position of the temperature sensor 230 since it is the point at which the temperature sensor 230 measures the temperature. Referring to FIG. 2, on the battery cell 210, a first temperature measurement point where the first temperature sensor 230a is disposed, a second temperature measurement point where the second temperature sensor 230b is disposed, A fourth temperature measurement point where the fourth temperature sensor 230d is disposed, a fifth temperature measurement point where the fifth temperature sensor 230e is disposed, a sixth temperature sensor 230f, There may be a sixth temperature measurement point disposed.

The temperature measurement point may be a point for checking the heat generation temperature deviation of the battery cell 210. For example, temperature measurement points may be present on the upper, lower, right, and left sides of the battery cell 210, respectively. For example, the temperature measurement point may be on the right, middle, left side of the upper end of the battery cell 210, and may also be on the lower right side, middle, left side.

The plurality of temperature measurement points may include at least one point that is within a first set distance from the electrode 250 of the battery cell 210 and at least one point that is at least a second set distance from the electrode 250 have. The first set distance may be less than the second set distance.

Thus, at least one point within the first set distance from the electrode 250 may be closer to the electrode 250 than at least one point away from the electrode 250 by a second predetermined distance or more. The first set distance and the second set distance may be values determined by experiments.

When the battery cell 210 performs charging or discharging, relatively high heat may be generated in the electrode 250. The temperature of the temperature measurement point existing within the first set distance from the electrode 250 among the plurality of temperature measurement points may be higher than the temperature of the temperature measurement point separated from the electrode 250 by a second set distance or more.

Referring to FIG. 2, the first temperature measurement point and the fourth temperature measurement point may be temperature measurement points existing within a first set distance from the electrode 250. The second, third, fifth, and sixth temperature measurement points may be temperature measurement points that are separated from the electrode 250 by a second set distance or more. Because the first and fourth temperature measurement points are relatively closer to the electrode 250 than the second, third, fifth, and sixth temperature measurement points, the temperatures of the first and fourth temperature measurement points are second, third, fifth, 6 Temperature may be higher than the temperature of the measuring point.

Accordingly, the temperature deviation due to the electrode 250 can be confirmed on the battery cell 210. The arrangement of the openings formed in the cell plate 110 to be described later corresponds to the arrangement of the temperature measuring points so that the temperature deviation due to the electrodes 250 of the battery cell 210 can be also confirmed in the cell plate 110.

The plurality of temperature measurement points may include at least one point that is within a third set distance from the cold plate 220 and at least one point that is at least a fourth set distance from the cold plate 220. The third set distance may be less than the fourth set distance.

Accordingly, at least one point within the third predetermined distance from the cooling plate 220 can be located closer to the cooling plate 220 than at least one point that is at least a fourth predetermined distance from the cooling plate 220 have. The third set distance and the fourth set distance may be values determined by experiments.

Relatively low heat may be generated around the cooling plate 220 when the battery cell 210 is attached to the cooling plate 220 performing the cooling function. The temperature of the temperature measurement point existing within the third set distance from the cooling plate 220 among the plurality of temperature measurement points may be lower than the temperature of the temperature measurement point away from the cooling plate 220 by a fourth set distance or more have.

Referring to FIG. 2, the fourth, fifth, and sixth temperature measurement points may be temperature measurement points that are within a third predetermined distance from the cooling plate 220. The first, second, and third temperature measurement points may be temperature measurement points that are separated from the cooling plate 220 by a fourth set distance or more. Since the temperatures of the fourth, fifth, and sixth temperature measurement points are relatively close to the cold plate 220 relative to the first, second, and third temperature measurement points, the temperature of the fourth, fifth, 2, and 3 temperature measurement points.

Accordingly, the temperature variation due to the cooling plate 220 on the battery cell 210 can be confirmed. The arrangement of the openings formed in the cell plate 110 to be described later corresponds to the arrangement of the temperature measurement points, so that the temperature deviation due to the cooling plate 220 can be also confirmed in the cell plate 110.

3 is a diagram for explaining the temperature unbalance that occurs in the test specimen battery.

The battery cell 210 includes a first temperature measurement point 260a corresponding to the first temperature sensor 230a, a second temperature measurement point 260b corresponding to the second temperature sensor 230b, A third temperature measurement point 260c corresponding to the fourth temperature sensor 230c, a fourth temperature measurement point 260d corresponding to the fourth temperature sensor 230d, a fifth temperature measurement point 260e corresponding to the fifth temperature sensor 230e, And a sixth temperature measurement point 260f corresponding to the sixth temperature sensor 230f. In Fig. 3, the numbers in the circles representing the plurality of temperature measurement points 260a to 260f are the temperatures measured by the temperature sensors corresponding to the temperature measurement points.

When the cooling plate 220 is attached to the lower end of the battery cell 210 and the battery cell 210 supplies electric energy, the temperature generated in the battery cell 210 may be uneven.

The temperature sensed through the first temperature sensor 230a and the fourth temperature sensor 230d which are relatively close to the electrodes 250a and 250b are electrically discharged through the electrodes 250a and 250b of the battery cell 210, May be higher than the temperature sensed through the remaining temperature sensors 250b, 250c, 250e, and 250f. In this case, the closer to the left of the battery cell 210 where the electrodes 250a and 250b exist, the higher the sensed temperature may be.

The cooling plate 220 is attached to the lower end of the battery cell 210 so that the temperature sensed through the temperature sensor disposed at the lower end of the battery cell 210 is relatively lower than the temperature sensed through the temperature sensor disposed at the upper end Can be low. For example, the temperature detected through the fourth temperature sensor 230d may be lower than the temperature sensed through the first temperature sensor 230a. The temperature detected through the fifth temperature sensor 230e may be lower than the temperature sensed through the second temperature sensor 230b. The temperature sensed through the sixth temperature sensor 230f may be lower than the temperature sensed through the third temperature sensor 230c.

The temperature distribution on the battery cell 210 may vary depending on the attachment position of the cooling plate 220 and the battery cell 210 or the position of the electrodes 250a and 250b on the battery cell 210. [

Depending on the size and shape of the battery cell 210, the number and position of the temperature sensors disposed in the battery cell 210 may be different. Accordingly, the temperature measurement point of the battery cell 210 can be changed. As the battery cell 210 is larger, the number of temperature sensors disposed in the battery cell 210 may increase. For example, when the battery cell 210 is in the form of a horizontally elongated shape, the number of temperature sensors arranged horizontally in the battery cell 210 may increase.

Hereinafter, a battery testing apparatus 100 according to the present invention will be described with reference to FIGS. 4 to 6. FIG. 4 to 6 are views for explaining a battery testing apparatus 100 according to the present invention.

The battery test apparatus 100 according to the present invention may include at least one cell plate 110.

4A is a view for explaining a cell plate 110 corresponding to a battery cell 210 included in the experimental sampled battery 200. As shown in FIG.

The cell plate 110 may correspond to the battery cell 210 included in the experimental sample battery 200. The battery testing device 100 may include a cell plate 110 that simulates the heating characteristics of the battery 200 because it is a device that simulates the heating characteristics of the battery 200.

The thermal conductivity, shape, and size of the cell plate 110 may correspond to the thermal conductivity, shape, and size of the battery cell 210.

For example, the shape of the cell plate 110 may be a thin rectangular parallelepiped such as the shape of the battery cell 210. [ For example, the size of the cell plate 110 may correspond to the size of the battery cell 210. The size of the cell plate 110 may be the same as the size of the battery cell 210 within a predetermined error range.

For example, the thermal conductivity of the battery cell 210 may be 25 W / mK. In this case, the thermal conductivity of the cell plate 110 may be a value within a predetermined error range from 25 W / mK. For example, the thermal conductivity of the cell plate 110 may be 20-30 W / mK. For example, when the thermal conductivity of stainless steel is 24 W / mK, the cell plate 110 may be made of stainless steel. A material having a thermal conductivity in the range of 20-30 W / mK may be implemented as the cell plate 110.

The material that can be implemented in the cell plate 110 should be a material that does not dissolve at the maximum temperature that occurs in the battery cell 210.

The cell plate 110 may include a plurality of openings 160 into which one bar heater (not shown) may be inserted. For example, the cell plate 110 may include six openings 160a to 160f. The opening 160 may be a hole formed in the cell plate 110. The opening 160 may be in the form of a circle or a polygon. For example, the cell plate 110 may include six circular openings 160a through 160f. The shape of the opening 160 may vary depending on the shape of the bar heater to be inserted into the opening 160. The opening 160 may be formed in a shape and size such that a bar heater can be inserted.

The arrangement of the plurality of openings 160 formed in the cell plate 110 may correspond to the arrangement of a plurality of temperature measurement points existing on the battery cell 210. [

The temperature measurement point 260 existing on the battery cell 210 may be a point at which the temperature is measured by the temperature sensor disposed in the battery cell 210. [ For example, when six temperature sensors 230a to 230f are disposed in the battery cell 210, six temperature measurement points 260a to 260f may exist on the battery cell 210. [

The plurality of temperature measurement points may be positions for confirming a temperature variation occurring on the battery cell 210. [ For example, when the cooling plate 220 is attached to one side of the battery cell 210, a temperature deviation may occur on the side opposite to the side to which the cooling plate 220 is attached. In addition, when the electrode 250 is present on one side of the battery cell 210, a temperature difference may occur between the side opposite to the side where the electrode 250 is present.

When the cooling plate 220 is attached to the lower end of the battery cell 210 and the battery cell 210 is charged or discharged, the temperature of the first temperature measurement point 260a is 47.1 degrees Celsius, The temperature of the fourth temperature measurement point 260b is 42.4 degrees Celsius, the temperature of the third temperature measurement point 260c is 39.6 degrees Celsius, the temperature of the fourth temperature measurement point 260d is 43.1 degrees Celsius, The temperature of the sixth temperature measurement point 260f may be 36.6 degrees Celsius.

For example, the cell plate 110 includes a first opening portion 160a corresponding to the first temperature measurement point 260a, a second opening portion 160b corresponding to the second temperature measurement point 260b, A third opening 160c corresponding to the measuring point 260c, a fourth opening 160d corresponding to the fourth temperature measuring point 260d, a fifth opening 160e corresponding to the fifth temperature measuring point 260e, And a sixth opening 160f corresponding to the sixth temperature measurement point 260f.

The plurality of temperature measurement points may include at least one point that is within a first set distance from the electrode 250 of the battery cell 210 and at least one point that is at least a second set distance from the electrode 250 have. At least one point within the first set distance from the electrode 250 may be closer to the electrode 250 than at least one point away from the electrode 250 by a second set distance or more.

When the battery cell 210 performs charging or discharging, relatively high heat may be generated in the electrode 250. The temperature of the temperature measurement point existing within the first set distance from the electrode 250 among the plurality of temperature measurement points may be higher than the temperature of the temperature measurement point separated from the electrode 250 by a second set distance or more. Accordingly, the temperature deviation due to the electrode 250 can be confirmed on the battery cell 210.

Since the arrangement of the openings formed in the cell plate 110 corresponds to the arrangement of the temperature measurement points, the temperature measured at the first opening portion 160a and the fourth opening portion 160d and the temperature measured at the remaining opening portion in the cell plate 110 The temperature variation due to the electrode 250 of the battery cell 210 can be checked.

The plurality of temperature measurement points may include at least one point that is within a third set distance from the cold plate 220 and at least one point that is at least a fourth set distance from the cold plate 220. At least one point within the third set distance from the cold plate 220 may be located closer to the cold plate 220 than at least one point that is no less than the fourth set distance from the cold plate 220.

Relatively low heat may be generated around the cooling plate 220 when the battery cell 210 is attached to the cooling plate 220 performing the cooling function. The temperature of the temperature measurement point existing within the third set distance from the cooling plate 220 among the plurality of temperature measurement points may be lower than the temperature of the temperature measurement point away from the cooling plate 220 by a fourth set distance or more have. Accordingly, the temperature variation due to the cooling plate 220 on the battery cell 210 can be confirmed.

Since the arrangement of the openings formed in the cell plate 110 corresponds to the arrangement of the temperature measurement points, the temperature measured at the fourth, fifth, and sixth openings 160d, 160e, and 160f and the remaining openings The temperature deviation due to the cooling plate 220 can be confirmed.

The battery testing apparatus 100 may further include a plurality of temperature sensors. The plurality of temperature sensors are arranged so as to correspond to each of the plurality of openings, and the temperature can be measured. For example, the battery test apparatus 100 may include six temperature sensors 130a to 130f. The six temperature sensors 130a to 130f may be disposed at positions corresponding to the six openings 160a to 160f formed in the cell plate 110. [ The position corresponding to the specific opening may be a predetermined distance from the specific opening. For example, the positions of the plurality of temperature sensors disposed in the cell plate 110 may correspond to the positions of the plurality of temperature sensors disposed in the battery cell 210.

The plurality of temperature sensors 130 can measure the temperature at a predetermined distance from the corresponding opening 160, respectively. For example, the first temperature sensor 130a can measure the temperature around the first opening 160a. And the second temperature sensor 130b can measure the temperature around the second opening 160b. And the third temperature sensor 130c can measure the temperature around the third opening 160c. And the fourth temperature sensor 130d can measure the temperature around the fourth opening 160d. The fifth temperature sensor 130e can measure the temperature around the fifth opening 160e. The sixth temperature sensor 130f can measure the temperature around the sixth opening 160f.

4B is a view for explaining a bar heater inserted in a cell plate.

The battery testing apparatus 100 may further include a plurality of bar heaters. The plurality of bar heaters can be inserted into each of the plurality of openings one by one. For example, when the cell plate 110 includes six openings 160a to 160f, one bar heater may be inserted for each opening. The shape and size of the bar heater may correspond to the shape and size of the opening. For example, if the opening is circular, the bar heater may be circular. Also, the bar heater may be of a size that can be inserted into the opening.

The bar heater may be a device that generates heat corresponding to the temperature value input by the user. For example, a bar heater may generate heat of 50 degrees Celsius entered by the user. When there are a plurality of bar heaters, the plurality of bar heaters can individually generate heat corresponding to the temperature value inputted by the user. For example, the first bar heater may generate a heat of 45 degrees Celsius entered by the user, and the second bar heater may generate heat of 50 degrees Celsius entered by the user.

For example, the battery test apparatus 100 may include six bar heaters 161a to 161f. The six bar heaters 161a to 161f may be inserted into six openings 160a to 160f, respectively. For example, the first bar heater 161a may be inserted into the first opening 160a. And the second bar heater 161b may be inserted into the second opening portion 160b. And the third bar heater 161c may be inserted into the third opening 160c. And the fourth bar heater 161d may be inserted into the fourth opening 160d. And the fifth bar heater 161e may be inserted into the fifth opening 160e. And the sixth bar heater 161f may be inserted into the sixth opening 160f. The six bar heaters 161a to 161f can generate heat corresponding to the temperature value inputted by the user, respectively.

The battery testing apparatus 100 may further include a heater control unit (not shown) for controlling the plurality of bar heaters 161. The heater control unit can control the heat generation of the plurality of bar heaters 161 based on the temperature distribution appearing in the battery cell 210 during the specific operation of the experimental sample battery 200. [

The heater control section is electrically connected to the plurality of bar heaters 161 to control the plurality of bar heaters 161. The heater control unit may include a separate input device (not shown) for receiving user inputs to the plurality of bar heaters 161. [ In this case, the heater control section can control the plurality of bar heaters 161 based on the temperature value input by the user through the input device. For example, on the basis of the user's input, the heater control section may control the temperature of the first bar heater 161a by 45 degrees Celsius, the second bar heater 161b by 38 degrees Celsius, and the third bar heater 161c The temperature can be controlled to be 32 degrees Celsius, 45 degrees Celsius for the fourth bar heater 161d, 38 degrees Celsius for the fifth bar heater 161e, and 32 degrees Celsius for the sixth bar heater 161f.

The heater control unit may include a memory (not shown) storing data on a temperature distribution appearing in the battery cell 210 during a specific operation of the experimental sampled battery 200. The temperature distribution appearing in the battery cell 210 during a specific operation of the test specimen battery 200 may be determined by experiments. For example, when the experimental sample battery 200 is rapidly charged, the temperature distribution in the battery cell 210 may be as high as it is closer to the electrode 250, and as low as it is far from the electrode 250. The heater control unit may store data on the temperature distribution based on at least one of temperature data measured by the temperature sensor 230 disposed in the battery cell 210, data transmitted by the external device, and data input by the user Generated and stored.

The heater control section can control the heat generation of the plurality of bar heaters 161 based on the temperature distribution of the battery cell 210 described above. 4A and 4B, the heater control unit controls the temperature of the first bar heater 161a so that the first bar heater 161a generates heat at the temperature of the first temperature measuring point 260a in accordance with the temperature distribution of the battery cell 210, The fourth bar heater 161d is heated to the temperature of the second temperature measuring point 260b so that the third bar heater 161c is heated to the temperature of the third temperature measuring point 260c so that the fourth bar heater 161b is heated to the temperature of the second temperature measuring point 260b, The sixth bar heater 161f is positioned at the sixth temperature measuring point 260f so that the fifth bar heater 161e is heated to the temperature of the fifth temperature measuring point 260e so as to generate heat at the temperature measuring point 260d, The heat can be controlled to be generated at a temperature of < RTI ID =

The heater control unit may be implemented as an application specific integrated circuit (ASIC), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), processors, ), Micro-controllers, microprocessors, and other electronic units for performing other functions.

5 and 6 are views for explaining the arrangement of the case and the cell plate constituting the battery testing apparatus according to the present invention.

The battery testing apparatus 100 may include a case 140 in which at least one cell plate 110 is disposed. The arrangement of the at least one cell plate 110 in the case 140 may correspond to the arrangement of the at least one battery cell 210 present in the experimental sampled battery 200.

The battery testing apparatus 100 according to the present invention is a device that simulates a heating state of an experimental sample battery 200. The battery test apparatus 100 may include an internal structure corresponding to the test specimen battery 200 to simulate the exothermic state of the test specimen battery 200. [

Referring to FIG. 5, the internal structure of the experimental sample battery 200 may be a structure in which a plurality of battery cells 210a to 210h are arranged in a row. Correspondingly, the internal structure of the battery test apparatus 100 may be a structure in which a plurality of cell plates 110a to 110h are arranged in a row. The intervals of the plurality of cell plates 110 may correspond to the intervals of the plurality of battery cells 210a to 210h.

The plurality of cell plates 110a to 110h may be fixed inside the case 140. [ The plurality of cell plates 110a to 110h fixed to the case 140 can be attached to the cooling plate 220. [ The battery test apparatus 100 is an apparatus for experimentally controlling the heat generation of the test specimen battery 200 by the cooling plate 220. Therefore, The shape may be the same as the attachment form of the plurality of battery cells 210a to 210h and the cooling plate 220. [

Referring to FIG. 6, when a plurality of cell plates 110a to 110h are arranged in a row, one bar heater may be inserted into the openings of the plurality of cell plates 110a to 110h. 6 bar heaters 161a to 161f are inserted into the openings of the plurality of cell plates 110a to 110h and six bar heaters 161a to 161f are installed in the openings of the cell plates 110a to 110h based on the temperature distribution of the battery cells 210 The plurality of cell plates 110a to 110h may be in an exothermic state corresponding to the temperature distribution of the battery cells 210. [ Accordingly, the battery testing apparatus 100 can be in a heat generation state corresponding to the heat generation state of the experimental sample battery 200. [

FIG. 7 is a diagram for explaining an experimental result in which a battery testing apparatus according to the present invention simulates a heating state of an experimental sample battery.

Referring to FIG. 7, the first to fourth battery cells 210a to 210d generate heat and the first to fourth cell plates 110a to 110d generate heat.

It is assumed that the cooling plate 220 is attached to the lower ends of the first to fourth battery cells 210a to 210d and that the cooling plate 220 is also attached to the lower ends of the first to fourth cell plates 110a to 110d do.

It is assumed that six rod heaters are inserted into the first to fourth cell plates 110a to 110d and the six rod heaters are connected to the first to fourth battery cells 210a to 210d ≪ / RTI > temperature distribution of the heat source.

The temperature of the first temperature measurement point of the first battery cell 210a is 41.5 degrees Celsius, the temperature of the fourth temperature measurement point is 38.5 degrees Celsius, and the temperature deviation between the two points is 3 degrees.

The temperature corresponding to the first opening of the first cell plate 110a corresponding to the first battery cell 210a is 43.6 degrees Celsius and the temperature corresponding to the fourth opening is 39.1 degrees Celsius, 4.5 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the first battery cell 210a corresponds to the temperature difference shown in the first cell plate 110a.

 The temperature of the first temperature measurement point of the first battery cell 210a is 41.5 degrees Celsius, the temperature of the third temperature measurement point is 36.8 degrees Celsius, and the temperature deviation between the two points is 4.7 degrees.

The temperature corresponding to the first opening of the first cell plate 110a corresponding to the first battery cell 210a is 43.6 degrees Celsius and the temperature corresponding to the third opening is 36.8 degrees Celsius, 6.8 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the first battery cell 210a corresponds to the temperature difference shown in the first cell plate 110a.

The temperature deviation indicated in the first battery cell 210a corresponds to the temperature difference indicated in the first cell plate 110a so that the first cell plate 110a determines that the first battery cell 210a simulates the heat generation state of the first battery cell 210a .

The temperature of the first temperature measurement point of the second battery cell 210b is 44.4 degrees Celsius, the temperature of the fourth temperature measurement point is 40.2 degrees Celsius, and the temperature deviation between the two points is 4.2 degrees.

The temperature corresponding to the first opening of the second cell plate 110b corresponding to the second battery cell 210b is 43.8 degrees Celsius and the temperature corresponding to the fourth opening is 40.3 degrees Celsius, 3.5 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the second battery cell 210b corresponds to the temperature difference shown in the second cell plate 110b.

 The temperature of the first temperature measurement point of the second battery cell 210b is 44.4 degrees Celsius, the temperature of the third temperature measurement point is 36.4 degrees Celsius, and the temperature deviation between the two points is 8 degrees.

The temperature corresponding to the first opening of the second cell plate 110b corresponding to the second battery cell 210b is 43.8 degrees Celsius and the temperature corresponding to the third opening is 35.7 degrees Celsius, 8.1 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the second battery cell 210b corresponds to the temperature difference shown in the second cell plate 110b.

Since the temperature deviation shown in the second battery cell 210b corresponds to the temperature difference shown in the second cell plate 110b, the second cell plate 110b determines that the second battery cell 210b simulates the heat generation state of the second battery cell 210b .

The temperature of the first temperature measurement point of the third battery cell 210c is 45.8 degrees Celsius, the temperature of the fourth temperature measurement point is 40.8 degrees Celsius, and the temperature deviation between the two points is 5 degrees.

The temperature corresponding to the first opening of the third cell plate 110c corresponding to the third battery cell 210c is 43.2 degrees Celsius and the temperature corresponding to the fourth opening is 39.9 degrees Celsius, 3.6 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the third battery cell 210c corresponds to the temperature difference shown in the third cell plate 110c.

 The temperature of the first temperature measurement point of the third battery cell 210c is 45.8 degrees Celsius, the temperature of the third temperature measurement point is 38.1 degrees Celsius, and the temperature deviation between the two points is 7.7 degrees.

The temperature corresponding to the first opening of the third cell plate 110c corresponding to the third battery cell 210c is 43.2 degrees Celsius and the temperature corresponding to the third opening is 35.9 degrees Celsius, 7.3 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the third battery cell 210c corresponds to the temperature difference shown in the third cell plate 110c.

Since the temperature deviation shown in the third battery cell 210c corresponds to the temperature difference shown in the third cell plate 110c, the third cell plate 110c determines that the third battery cell 210c simulates the heat generation state of the third battery cell 210c .

The temperature of the first temperature measurement point of the fourth battery cell 210d is 42.2 degrees Celsius, the temperature of the fourth temperature measurement point is 37.7 degrees Celsius, and the temperature deviation between the two points is 4.5 degrees.

The temperature corresponding to the first opening of the fourth cell plate 110d corresponding to the fourth battery cell 210d is 44.6 degrees Celsius and the temperature corresponding to the fourth opening is 37.2 degrees Celsius, 7.4 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the fourth battery cell 210d corresponds to the temperature difference shown in the fourth cell plate 110d.

 The temperature of the first temperature measurement point of the fourth battery cell 210d is 42.2 degrees Celsius, the temperature of the third temperature measurement point is 36 degrees Celsius, and the temperature deviation between the two points is 6.2 degrees.

The temperature corresponding to the first opening of the fourth cell plate 110d corresponding to the fourth battery cell 210d is 44.6 degrees Celsius and the temperature corresponding to the third opening is 37.3 degrees Celsius, 7.3 degrees. When the error range is plus or minus three degrees, it can be seen that the temperature deviation shown in the fourth battery cell 210d corresponds to the temperature difference shown in the fourth cell plate 110d.

Since the temperature deviation indicated by the fourth battery cell 210d corresponds to the temperature difference indicated by the fourth cell plate 110d, the fourth cell plate 110d determines that the fourth battery cell 210d simulates the heat generated by the fourth battery cell 210d .

The heat generation state and the temperature variation of the first to fourth battery cells 210a to 210d when the test specimen battery 200 is attached to the cooling plate 220 and the temperature difference and temperature difference between the first to fourth battery cells 210a to 210d when the battery experiment apparatus 100 is attached to the cooling plate 220 And the temperature of the first to fourth cell plates 110a to 110d corresponds to the temperature of the first to fourth cell plates 110a to 110d and the temperature deviation of the first to fourth cell plates 110a to 110d.

Accordingly, the user can perform the performance test of the test specimen battery 200 and the performance of the cooling plate 220 using only the battery test apparatus 100 without using the test specimen battery 200 .

The foregoing detailed description should not be construed in all aspects as limiting and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

100: Battery experiment device
200: Experimental Sample Battery

Claims (9)

A first cell plate having a plurality of openings penetrating one side surface and the other side surface and a second cell plate having an opening formed at a position corresponding to each of the plurality of openings of the first cell plate, plate;
A case in which the plurality of cell plates are disposed inside; And
And a plurality of bar heaters passing through the openings at positions corresponding to the plurality of cell plates and provided in a quantity corresponding to the number of openings formed in each of the plurality of cell plates. The method according to claim 1,
The thermal conductivity, shape, and size of the plurality of cell plates may be determined,
Wherein the plurality of cell plates correspond to the thermal conductivity, shape, and size of battery cells to be simulated. delete 3. The method of claim 2,
Wherein the arrangement of the plurality of openings corresponds to the arrangement of a plurality of temperature measurement points existing on the battery cell. delete 3. The method of claim 2,
Further comprising a heater control section for controlling the plurality of bar heaters,
The heater control unit,
And controlling the heat generation of the plurality of bar heaters based on a temperature distribution appearing in the battery cell during a specific operation of the experimental sampled battery including the battery cell. 3. The method of claim 2,
Further comprising a plurality of temperature sensors,
Wherein the plurality of temperature sensors are disposed so as to correspond to each of the plurality of openings, and measure the temperature. 5. The method of claim 4,
The arrangement of the plurality of openings may be such that,
The at least one temperature measurement point corresponding to an arrangement of the plurality of temperature measurement points including at least one point located within a first set distance from an electrode of the battery cell and at least one point located at least a second set distance from the electrode,
Wherein the first set distance is less than the second set distance. 5. The method of claim 4,
Further comprising a first cooling plate for cooling the plurality of cell plates,
The arrangement of the plurality of openings may be such that,
At least one point located within a third set distance from the second cold plate when the battery cell is attached to the second cold plate and at least one point located at least a fourth set distance from the cold plate, Corresponds to the arrangement of the plurality of temperature measurement points,
And the third set distance is less than the fourth set distance.

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