KR100559334B1 - Apparatus for cooling battery and method of the same - Google Patents

Abstract

Disclosed is a battery cooling apparatus and method for an electric vehicle. The battery cooling apparatus of such an electric vehicle includes an air passage for cooling the battery by allowing air to flow therein, and a first cooling fan provided at an inlet side of the air passage to suck outside air; A second cooling fan provided at an outlet side of the air passage to discharge the air in the air passage to the outside, and a controller for sensing the temperature of the battery and controlling the first and second cooling fans to cool the battery; Include.

Battery, electric, car, control, cooling, cooling fan

Description

Battery Cooling System and Method for Electric Vehicles {APPARATUS FOR COOLING BATTERY AND METHOD OF THE SAME}

1 is a side view showing a battery and a cooling device for an electric vehicle according to the prior art.

2 is a side view showing a battery and a cooling device for a vehicle according to a preferred embodiment of the present invention.

3 is a flowchart illustrating a method of cooling a vehicle battery according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10 ... battery 12 ... case

15 .... Air passage 18 ... First cooling fan

20 ... 2nd cooling fan

The present invention relates to a battery cooling device and a method, and more particularly to a battery cooling device and a method that can be efficiently cooled by providing a cooling fan on both sides of the air passage for cooling the battery.

Typically, electric vehicles or hybrid electric vehicles are equipped with a large capacity battery. As such batteries, nickel metal hydride batteries, lithium ion batteries, lithium ion polymer batteries and the like are mainly used.

Among them, lithium ion polymer batteries are in the spotlight as next generation batteries as high output and high density batteries compared to other batteries.

However, these batteries are highly dependent on their performance, especially at high temperatures, resulting in electrolyte degradation, which significantly reduces their lifetime.

Therefore, various methods for preventing such a temperature rise of the battery have been developed, an example of which is shown in FIG.

That is, the battery 1 is provided inside the case 2, and the air passage 3 for cooling the battery 1 is disposed in the case 2. The cooling fan 4 is mounted to the rear II of the air passage 3.

Therefore, when the cooling fan 4 is driven, suction force acts on the inside of the air passage 3 so that air is sucked from the front I of the air passage 3 and flows to the rear II. By means of which the batteries 4 are cooled below a certain temperature.

However, the cooling method of such a structure is limited by reducing the temperature distribution of the battery because the cooling is performed by one cooling fan, and there is a problem that the structure setting cost is high.

 An object of the present invention is to solve the problems as described above, the cooling device for an electric vehicle battery that can efficiently cool the battery by having a cooling fan on each side of the air passage for cooling the battery, respectively And providing a method,

In order to achieve the above object, the present invention includes an air passage provided in the battery adjacent position to cool the battery by flowing air therein; A first cooling fan provided at an inlet side of the air passage to suck outside air; A second cooling fan provided at an outlet of the air passage to discharge the air of the air passage to the outside; And it provides a battery cooling device of an electric vehicle comprising a control unit for cooling the battery by sensing the temperature of the battery to control the first and second cooling fan.

Hereinafter, with reference to the accompanying drawings will be described in detail a cooling apparatus and method for an electric vehicle battery according to a preferred embodiment of the present invention.

As shown in Figures 2 and 3, the cooling device of the battery (10) is appropriately disposed in the case (Case) 12, the air reservoir for flowing air in the upper and lower parts of the case (12) The furnace 15 is arranged.

In addition, the air passage 15 sucks air from the inlet 16 formed at the front I and flows to the outlet 19 formed at the rear II to cool the batteries 10 below a predetermined temperature.

In addition, the inlets 16 and the outlets 19 are provided with cooling fans 18 and 20, respectively, so that the air is sucked in or discharged into the air passage 15.

In more detail, the battery case 12 is formed in the upper and lower portions of the air passage 15 through which air flows, and a first cooling fan installed in the inlet of the air passage 15 to suck air ( 18, a second cooling fan 20 installed at an outlet 19 of the air passage 15 to discharge air, and a temperature of the battery 10 to sense the temperature of the first and second cooling fans ( And a controller (not shown) for appropriately driving 18,20.

Therefore, when the first and second cooling fans 18 and 20 are driven, suction force acts on the inside of the air passage 15 so that air is sucked from the front (I) of the air passage 15 and the rear (II). As a result, the battery 10 is cooled to a temperature below a predetermined temperature by flowing air.

At this time, the first and second cooling fans (18, 20) has a structure capable of controlling the acceleration and deceleration of the first and second stages can efficiently flow air according to the temperature conditions.

On the other hand, each part of the battery 10 is provided with at least one temperature sensor (T1 to T6) for sensing the temperature of the battery 10, these temperature sensors (T1 to T6) are connected to the control unit (not shown) do.

Accordingly, the controller 19 recognizes the temperature of each part of the battery 10 by receiving a signal from the temperature sensors T1 to T6, and the first and second cooling fans 18, By driving 20, the air flow amount of the air passage 15 can be adjusted to efficiently cool the battery 10.

That is, when the temperature of the temperature sensors T1 and T2 installed on the front side I of the air passage 15 is higher than the rear side II, the control unit (not shown) signals the first cooling fan 18. The first cooling fan 18 is rotated faster by outputting. Thus, the battery 10 in this zone is cooled by increasing the air inflow amount on the front side I.

On the other hand, when the temperature of the temperature sensors T5 and T6 installed on the rear side II of the air passage 15 is higher than the front side I, the control unit (not shown) is connected to the second cooling fan 20. By outputting a signal, the second cooling fan 20 is rotated more quickly.

Thus, the battery 10 in this zone is cooled by increasing the air inflow amount at the rear side II.

In addition, when the temperature of the front and rear sides I and II is uniform, the controller (not shown) operates the first and second cooling fans 18 and 20 uniformly so that the front of the battery 10 is maintained. The rear part is allowed to cool evenly.

Hereinafter, a cooling method of a battery cooling apparatus of an electric vehicle according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 and 3, in the case of cooling the battery 10 by the battery cooling apparatus proposed by the present invention, first, the controller (not shown) is the battery 10 through the temperature sensors (T1 to T6) It will detect the temperature of each part of (S100).

As a result of the detection, it is determined whether the following equation is satisfied (S110).

T1〉 T2〉 T3〉 T4〉 T5〉 T6 ------ Equation 1

That is, when it is determined that the temperature of the T1 region is the highest and gradually decreases so that the temperature of T6 is the lowest, it is determined whether the following conditions are satisfied (S120).

(T1 + T2)-(T5 + T6) ｜> 2 * const1 ----- Equation 2 (const1: 5)

If the condition is satisfied, the T1 portion of the battery 10 means the highest temperature, so the controller (not shown) sends a control signal to drive the first cooling fan 18 in a two-stage state (S124). ).

As such, when the first cooling fan 18 is driven in two stages, the flow rate of the air on the front side I of the air passage 15 increases, so that the temperature of the region decreases, causing the battery 10 to overheat. Can be prevented.

If the conditional expression 2 does not correspond to the control to drive the first cooling fan in the first stage (S122).

On the other hand, if it does not correspond to the conditional formula 1, it is determined whether the following conditions are satisfied (S130).

T1 <T2 <T3 <T4 <T5 <T6 ------ Equation 3

That is, it is determined whether the temperature of the rear side (II) is the highest, and if it satisfies this condition, it is again determined whether it corresponds to the following conditional expression (S140).

(T1 + T2)-(T5 + T6) ｜> 2 * const1 ----- Equation 4

When the conditional expression is satisfied, that is, when the temperature of the rear side II of the air passage 15 rises, the second cooling fan 20 is controlled to be driven in two stages (S144).

If the conditional expression does not correspond, that is, the temperature is low compared to the above-described step S144, the second cooling fan 20 is controlled to be driven in the first stage (S142).

In addition, in the case where the conditional expression 3 does not correspond, it is determined whether the following conditions are met (S150).

T1 <T3 & T6 <T4 ----- Equation 5

When the condition is satisfied, that is, when the temperature of the middle portion of the battery 10 is higher than both ends, it is determined whether the following conditions are met (S160).

T1-T3 |> const2 & | T6-T4 |> const2 ----- Equation 6

If this condition is satisfied, the first cooling fan 18 is controlled in the first stage, and time delay is performed for a predetermined time (S164).

Then, the second cooling fan 20 is controlled to be driven in a first stage and time delay is performed for a predetermined time (S166).

 On the other hand, if it does not correspond to the condition of Equation 6 is controlled to drive the first cooling fan 18 in a two-stage state and time delay for a predetermined time (S162).

Then, the second cooling fan 20 is controlled to be driven in a two-stage state and a time delay is made for a predetermined time (S163).

In addition, even if the equation 5 does not correspond (S150), as described above, the first cooling fan 18 is controlled in a first stage and time delay is performed for a predetermined time (S164).

Then, the second cooling fan 20 is controlled to be driven in a first stage and time delay is performed for a predetermined time (S166).

As described above, the controller (not shown) controls the first and second cooling fans 18 and 20 appropriately according to the temperature conditions, thereby efficiently cooling each part of the battery 10.

The apparatus and method for cooling an electric vehicle battery according to the present invention as described above efficiently installs a cooling fan on both sides of an air passage for cooling the battery, thereby supplying more air to the battery zone in which the temperature rises. There is an advantage that can be cooled.

In addition, since the battery can be efficiently cooled, the range of available energy can be widened and the life of the battery can be extended.

The present invention has been described above with reference to the embodiments shown in the drawings. However, the present invention is not limited thereto, and various modifications or other embodiments falling within the scope equivalent to the present invention are possible by those skilled in the art. Therefore, the true scope of protection of the present invention should be defined by the following claims.

Claims (8)

delete delete delete A first step of sensing a battery temperature when power is supplied; A second step of determining whether the temperatures of the front and the rear of the battery correspond to the following conditions as a result of the temperature sensing; T1〉 T2〉 T3〉 T4〉 T5〉 T6 ------ Equation 1 (T1: front, T6: rear) A third step of driving the first cooling fan to increase the air flow rate (front) in the T1 portion of the air passage when the second step is satisfied; A fourth step of determining whether the temperatures of the front and the rear of the battery correspond to the following conditions when the second step does not correspond; T1 <T2 <T3 <T4 <T5 <T6 ------ Equation 2 A fifth step of driving the second cooling fan to increase the air flow rate (rear) to the T6 portion of the air passage when the fourth step is satisfied; And If it does not correspond to the fourth step, the electric vehicle comprising a sixth step of driving the first and second cooling fans in a two-stage state by determining that the intermediate part of the battery is higher than the front and rear How to cool your battery. 5. The method of claim 4, further comprising: a seventh step of determining whether the temperature condition satisfies the following condition; (T1 + T2)-(T5 + T6) ｜> 2 * const1 ----- Equation 3 (const1: 5) An eighth step of controlling the first cooling fan to be driven in a two-stage state when it is determined that the temperature deviation is large; And a ninth step of controlling the driving of the first cooling fan to the first stage by determining that the temperature deviation is smaller than the eighth step if the seventh step does not correspond to the seventh step. 5. The method of claim 4, further comprising: a tenth step of determining whether the temperature condition satisfies the following condition; | (T1 + T2)-(T5 + T6) ｜> 2 * const1 ----- Equation 4 (const1: 5) An eleventh step of controlling the second cooling fan to be driven in a two-stage state when it corresponds to the tenth step; And If not in the tenth step, the battery cooling method of an electric vehicle comprising a twelfth step of controlling to drive the second cooling fan in the first stage. The method of claim 4, wherein the sixth step comprises: a thirteenth step of determining whether a condition of T1 &lt; T3 & T6 &lt; T4 is satisfied; When the condition corresponds to the thirteenth step, a fourteenth step of determining whether the following condition is true; | T1-T3 |> const2 & | T6-T4 |> const2 ----- Equation 5 (const2: 3) A fifteenth step of driving the first cooling fan to a first stage and performing time delay when the fourteenth step is satisfied; And And a sixteenth step of driving the second cooling fan in a first stage and performing a time delay when the second cooling fan does not correspond to the fourteenth step. The battery cooling method of an electric vehicle according to claim 7, wherein the fifteenth and sixteenth steps are executed when the thirteenth step does not correspond to a condition of T1 &lt; T3 & T6 &lt; T4.

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