KR20200124029A - Battery enclosure that controls the internal temperature with the same air flow function - Google Patents

Abstract

The present invention relates to a battery enclosure for controlling internal temperature by the same blowing function. The battery enclosure includes a cabinet in which an exhaust fan for discharging internal gas and a door through which an administrator enters and exits are installed, and a space is formed to install a battery rack in which a plurality of battery packs are installed; the battery rack in which the plurality of battery packs are installed; a battery management system (BMS) for controlling the battery pack installed in the battery rack; a thermo-hygrostat installed inside the cabinet such that the battery maintains uniform performance by maintaining a constant temperature and humidity inside the cabinet; and an air duct connected to the thermo-hygrostat and installed under the battery rack such that wind can be supplied to the entire interior of the cabinet at the same air volume and wind speed. By maintaining an appropriate internal temperature by the air circulating inside the cabinet, it is possible to mitigate heat accumulation caused by battery heat generation and increase the stability of the overall battery system.

Description

Battery enclosure that controls the internal temperature with the same air flow function}

The present invention relates to a battery enclosure that controls the internal temperature by the same blowing function, and more particularly, in the case of an energy storage system used in connection with solar power generation, a large capacity to store generated power. Regardless of the number of batteries in which the battery is used, it relates to a battery enclosure that controls the internal temperature by the same blowing function to maintain a uniform internal temperature while physically storing the batteries.

In general, the container (container) refers to a box-shaped container used to transport cargo economically. Such containers can be used to store and transport various cargoes such as clothes, electronics, furniture, and agricultural products. In particular, it can be used to load, store, and transport batteries such as secondary batteries.

However, if the temperature of the battery becomes too high during storage and transportation, there is a risk that the battery may explode or malfunction. If the temperature is too low, serious damage to the quality of the battery may occur.

Therefore, there is a need for a container capable of properly maintaining the temperature inside the container in which the battery is loaded.

Of course, if not only the temperature but also the proper humidity or cleanliness can be properly maintained, it can be more helpful in maintaining the excellent performance and quality of the battery.

Among conventional containers, such a container for storage and transport of a battery has a problem in that performance, life, and quality of the battery are not maintained excellently because such appropriate air conditioning cannot be performed.

As a prior document for solving the above problems, the "air-conditioning container" of Republic of Korea No. 2016-0107571 (published on September 19, 2016) refers to a bottom part for placing a battery, a ceiling part facing the floor part, and A body having a side wall portion connecting the bottom portion and the ceiling portion; And an air conditioning unit installed on an inner surface of the ceiling portion and configured to condition air inside the container, wherein the air conditioning unit includes a blower portion configured to inject air toward the floor; And a suction unit configured to suck the air circulated inside the container after being injected from the blowing unit.

The above prior literature is a configuration that maintains a constant temperature by allowing the internal air to be purified inside the container by the air conveying unit, but the internal temperature of the container does not reach the corners of the air supplied by the air conveying unit. There is a problem in that gas generated from the lithium battery located in a region where the temperature is maintained high is generated due to the difference in each region.

As described above, since gas generated from the lithium battery is generated, there is a problem that there is a risk of explosion.

Republic of Korea No. 2016-0107571 (released on September 19, 2016)

The present invention for solving the problem is that in the case of an energy storage system (hereinafter referred to as'ESS') used in connection with solar power generation, a battery with a large capacity is used to store the generated power, As the capacity of the battery increases, it is connected in parallel and in series with each cell to provide a battery enclosure that controls the internal temperature by the same blowing function to solve the problem that the number of cells increases and the size increases. Has a purpose.

The present invention provides a battery enclosure that controls the internal temperature by controlling the internal temperature of the cabinet storing the battery by the same blowing function to maintain the best condition by suppressing the gas generated from the lithium battery as much as possible when the temperature is high. There is a purpose to do.

The present invention can control the internal temperature so that temperature deviation does not occur by keeping the internal temperature constant with a thermo-hygrostat as well as preventing the influence of the external temperature as much as possible through a waterproof design while suppressing the influence on the external air. It is an object of the present invention to provide a battery enclosure that controls the internal temperature by the same blowing function.

The present invention is a battery that controls the internal temperature by the same blowing function to alleviate heat accumulation caused by battery heat generation by maintaining an appropriate internal temperature by air circulating inside the cabinet and to increase the stability of the overall battery system. The purpose is to provide an enclosure.

In the present invention, the wind injected from the thermo-hygrostat is distributed through an air duct installed under the battery rack, and a guide panel is configured to adjust each wind speed as uniformly as possible, and the air volume is mutually It is an object of the present invention to provide a battery enclosure that controls the internal temperature by the same blowing function so that the internal temperature can be controlled by applying differently.

The present invention for solving the above problems

A cabinet in which an exhaust fan for discharging internal gas and a door through which an administrator enters and exits are installed, and a space is formed to install a battery rack in which a plurality of battery packs are installed; A battery rack in which a plurality of battery packs are installed and installed inside the cabinet 100; A BMS (battery management system) for controlling the battery pack installed in the battery rack; A thermo-hygrostat installed inside the cabinet so that the battery can maintain uniform performance by maintaining a constant temperature and humidity inside the cabinet; Provides a battery enclosure that controls the internal temperature by the same blowing function, characterized in that it includes an air duct connected to a thermo-hygrostat and installed under the battery rack so that wind can be supplied at the same air volume and wind speed throughout the cabinet. do.

The cabinet of the present invention is characterized in that a solenoid valve is further configured to release the pressure when the internal pressure exceeds a predetermined pressure.

The air duct of the present invention includes a main duct connected to a thermo-hygrostat so as to supply wind; A branch duct branched from the main duct and installed at least one under the battery rack so that wind is supplied from the bottom side of the cabinet to the top side; It is characterized in that it comprises an exhaust duct installed in the upper inside the cabinet so that it is installed on the upper part of the cabinet to circulate the wind containing heat or gas by a thermo-hygrostat or to discharge it to the outside of the cabinet.

The branch duct of the present invention includes a blower hole in which a plurality of branch ducts are formed at predetermined intervals so that wind can be discharged; It is characterized in that it comprises a guide panel that is formed differently in length based on a distance from the thermo-hygrostat so that wind having an air density can be supplied by the same air volume and wind speed.

The supply of wind with uniform air density according to the air volume and wind speed of the present invention,

이며,

Is,

이고,

ego,

으로 이루어진 수학식에 의해 송풍홀의 크기가 설정되는 것을 특징으로 한다.

It characterized in that the size of the blowing hole is set by the equation consisting of.

The present invention is manufactured integrally with a thermo-hygrostat that prevents battery temperature from rising in order to prevent battery accidents, so that the performance of the battery is always maintained constant by controlling the internal temperature.

In addition, the present invention suppresses an increase in battery temperature by lowering the external temperature of the battery through temperature control by a thermo-hygrostat, and if gas is discharged due to an abnormal temperature increase, the internal gas is first discharged to the exhaust fan, and if a certain pressure is exceeded By opening the solenoid valve to reduce the internal pressure to prevent pressure explosion, there is an effect of minimizing the damage caused by the accident by suppressing fire and explosion accidents of the battery to the maximum.

In addition, the present invention increases the length of the guide panel installed in the air duct as the distance from the thermo-hygrostat from which the wind is supplied increases, so that the wind speed and the amount of air supplied into the air duct are equally discharged through the ventilation hole. There is an effect of preventing an increase in internal temperature and pressure by evenly supplying wind to the entire interior.

1 is a view showing the configuration of a battery enclosure for controlling the internal temperature by the same blowing function according to the present invention,
2 is a view showing a state in which gas is discharged from the battery enclosure shown in FIG. 1,
3 is a view showing a state in which air is circulated during cooling or heating in the battery enclosure shown in FIG. 1,
Figure 4 is a cross-sectional view showing the configuration of the air supply duct installed in the battery enclosure shown in Figure 1,
5 is a configuration diagram showing the shape of the air outlet shown in FIG. 4,
6 is a view showing a state in which wind is discharged through the air outlet shown in FIG. 4.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in the following description and the accompanying drawings, detailed descriptions of known functions or configurations that may obscure the subject matter of the present invention will be omitted. In addition, it should be noted that the same components throughout the drawings are indicated by the same reference numerals as much as possible.

The terms or words used in the present specification and claims described below should not be construed as being limited to a conventional or dictionary meaning, and the inventor is appropriate as a concept of terms for describing his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention on the basis of the principle that it can be defined.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, and thus various equivalents that can replace them at the time of filing It should be understood that there may be water and variations.

Hereinafter, a battery enclosure for controlling the internal temperature by the same blowing function according to the present invention will be described in detail.

In the present invention, the battery enclosure that controls the internal temperature by the same blowing function is an energy storage system that is used in connection with solar power generation, and a large capacity battery is used to store the generated power. Battery heats up by maintaining an appropriate internal temperature by air circulating inside the cabinet to solve the problem that the temperature cannot be uniformly maintained due to an increase in the number and size by connecting each cell in parallel and series as the capacity increases. It is characterized in that the internal temperature is controlled by blowing air to alleviate the heat accumulation phenomenon caused by and increase the stability of the overall system.

A battery enclosure for controlling the internal temperature by the same blowing function according to the present invention having the above characteristics will be described in detail with reference to the accompanying drawings.

1 is a view showing the configuration of a battery enclosure that controls the internal temperature by the same blowing function according to the present invention, Figure 2 is a view showing a state in which gas is discharged from the battery enclosure shown in Figure 1, Figure 3 1 is a view showing a state in which air is circulated during cooling or heating in the battery enclosure shown in FIG. 1, and FIG. 4 is a cross-sectional view showing the configuration of an air supply vent installed in the battery enclosure shown in FIG. 1, and FIG. It is a configuration diagram showing the shape of the air outlet shown, Figure 6 is a view showing a state in which wind is discharged through the air outlet shown in FIG.

When described in detail with reference to FIGS. 1 to 6, the battery enclosure for controlling the internal temperature by the same blowing function according to the present invention includes an exhaust fan 110 for discharging internal gas and a door for entering and exiting the manager. A cabinet 100 in which a space is formed to install the battery rack 200 in which a plurality of battery packs 210 are installed, and a battery rack installed inside the cabinet 100 by installing a plurality of battery packs 210 200) and a BMS (battery management system) 300 that controls the battery pack 210 installed in the battery rack 200, and the battery is maintained by maintaining a constant temperature and humidity inside the cabinet 100. The thermo-hygrostat 400 installed inside the cabinet 100 to maintain uniform performance and the thermo-hygrostat 400 are connected to the thermo-hygrostat so that wind can be supplied to the entire interior of the cabinet 100 at the same air volume and wind speed. It is configured to include an air duct 500 installed at the bottom.

The cabinet 100 is formed in a square shape, and a door (not shown) is configured so that an administrator can manage and check the state of the battery pack 210 installed in the battery rack 200 through the BMS 300. , An exhaust fan 110 is provided to discharge the gas generated inside, and a solenoid valve 120 for releasing the pressure to prevent explosion and fire accidents caused by the increase of the internal pressure by the gas is provided. Is composed.

Although the solenoid valve 120 is illustrated as being installed in one place in FIGS. 1 to 3, the position is not limited, and the number of the solenoid valve 120 is not limited. That is, according to the size of the cabinet 100, a plurality of solenoid valves 120 are distributed and installed in various locations so that the internal pressure can be momentarily reduced.

In addition, the solenoid valve 120 is not configured only in the portion where the exhaust fan 110 is positioned as shown in the drawing, but is preferably configured together under the cabinet 100.

In addition, the solenoid valve 120 installed under the cabinet 100 is connected to the vacuum tank 130 and installed under the cabinet 100 to prevent explosion of the battery by moving gas generated by the battery.

The vacuum tank 130 is installed at the bottom of the cabinet 100 in a vacuum state after installing the solenoid valve 120 by either manufacturing the cabinet 100 together or by purchasing a commercially available product, The shape can be manufactured in various shapes, such as a square or a circle. In addition, although not shown in the drawing, the vacuum tank 130 may be configured as a vacuum tank 130 in the entire lower portion of the cabinet 100.

Installing so that the gas inside the cabinet 100 flows into the vacuum tank 130 while the solenoid valve 120 is installed in the vacuum tank 130 can be easily installed by a skilled person. Description is omitted.

The vacuum tank 130 is controlled by a controller (not shown) installed in the BMS 300, and the controller checks the pressure through a signal from the sensor to see if it is above the set pressure and if it is above the set pressure, the explosion The solenoid valve 120 is controlled by determining whether it is a dangerous pressure.

The gas generated from the battery flows into the vacuum tank 130 due to the difference in atmospheric pressure, thereby lowering the pressure inside the cabinet so that it can escape from the risk of explosion.

A vacuum tank is attached to the bottom of the battery enclosure, and the vacuum tank and the inside of the enclosure are connected with a solenoid valve. When the battery gas is discharged and the air pressure rises, it starts to be discharged through the fan of the upper duct first, and the internal pressure does not decrease even with the discharge of the fan, and when the pressure rises continuously and exceeds a certain pressure, the attached internal The sensor detects this, and the controller opens the solenoid valve based on the signal received from the sensor to distribute the gas to the lower tank at a difference between the pressure of the tank and the pressure of the enclosure, thereby reducing the pressure of the enclosure instantly.

The battery rack 200 includes a plurality of compartments in which a plurality of battery packs 210 can be placed. In addition, the battery installed in the battery rack 200 is electrically connected to the BMS 300 that controls charging or discharging.

The BMS 300 monitors the battery pack 210 installed in the battery rack 200 and controls it to maintain an optimal state. Monitoring of the battery pack 210 checks voltage, current, temperature, etc. in real time. In addition, the BMS 300 includes an algorithm for checking and managing the voltage, current, and temperature of the battery.

In addition, the BMS 300 further includes a sensor (not shown) that checks the pressure inside the cabinet, and a controller (not shown) to control the exhaust fan 110 and the solenoid valve 120 by receiving a signal from the sensor. It is included, and the control unit is preferably manufactured and installed in a separate PCB form.

The thermo-hygrostat 400 is characterized in that it is a multifunctional air conditioner that adjusts the air condition so that various equipment or devices affected by indoor air can be operated in the best condition.

The thermo-hygrostat 400 is connected to an external outdoor unit 410 to adjust the temperature and humidity inside the cabinet 100, and is set to be supplied to the inside of the cabinet 100 in a state in which heat exchange is performed through the outdoor unit 410. It is connected to the air duct 500 so as to supply wind of temperature.

The thermo-hygrostat 400 performs the function of an air conditioner because the temperature inside the cabinet 100 is increased together with the external temperature and heat generated from the battery pack 210 in summer, and the internal heat is transferred to the outside in winter. In order to prevent the performance of the battery from deteriorating due to the subtraction of the internal temperature, it performs the function of a hot air fan to maintain the set temperature.

The air duct 500 includes a main duct 510, a branch duct 520, and an exhaust duct 530 so as to be connected to the thermo-hygrostat 400 to supply wind.

The main duct 510 is connected to the thermo-hygrostat 400 to supply the supplied wind to the branch duct 520 and at the same time, a main air outlet 511 is formed to supply wind to the front of the main duct 510 together. .

The branch duct 520 is connected to the main duct 510 to supply wind supplied from the thermo-hygrostat 400 to the inside of the cabinet 100 at a constant wind speed and air volume.

Although not shown in the drawing, at least one branch duct 520 is preferably installed. In addition, the number of branch ducts 520 may be different according to the internal area of the cabinet 100.

In addition, the branch duct 520 includes a plurality of blowing holes 521 formed at predetermined intervals so that wind can be discharged, and a thermo-hygrostat 400 so that wind having an air density can be supplied by the same air volume and wind speed. ) Is formed with a guide panel 522 having different lengths based on the distance.

The guide panel 522 is preferably formed to have a longer length as the distance from the thermo-hygrostat 400 increases.

Since the length of the guide panel 522 is formed differently, the air volume and wind speed of the wind supplied from the thermo-hygrostat 400 are equally discharged to the blowing hole 521 formed in a plurality, so that the same air volume and wind speed throughout the cabinet 100 The same wind is supplied.

The length of the guide panel 522 and the size of the blowing hole 521 are set through the amount of wind and wind speed of the discharged wind, and math for setting the length of the guide panel 522 and the size of the blowing hole 521 The equation is

<Equation 1>

Wind speed,

으로 이루어진 수학식에 의해 산출된다.

It is calculated by the equation consisting of.

In Equation 1, A is the cross-sectional area, ρ is the air density, v is the wind speed, and m is the mass.

When the wind discharged through the blowing hole 521 is distributed and discharged, the air density inside the exhaust duct 530 decreases. Therefore, the width (cross-sectional area) of the blowing hole 521 through which wind is discharged is designed differently to It is desirable to match the wind speed. Adjusting the wind speed as described above can be inferred by inducing the kinetic energy of the wind as shown in Equation 1.

<Equation 2>

In Equation 2, p is the air density.

The air density decreases as the wind passes through each of the ventilation holes 521 along the main duct 510.

When the first air density discharged through the exhaust duct 530 is ρ ₁ , the second discharged air density is ρ ₂ and is 3/4 of ρ ₁ . The third discharged air density is called ρ ₃ and is 1/2 of ρ ₁ . The final discharged air density is called ρ ₄ and is 1/4 of ρ ₁ . Each air density can be summarized as in Equation 2 based on ρ ₁ .

<Equation 3>

이며,

Is,

이고,

ego,

이며, 상기 수학식 3에서 A는 단면적, ρ는 공기밀도 v는 풍속이다.

In Equation 3, A is the cross-sectional area, ρ is the air density, v is the wind speed.

Equation 3 aims to make the wind speed and air volume (wind energy) of the wind discharged through all the blowing holes 521 installed in the branch duct 520 equal. Here, the cross-sectional area A is applied to Equation 3 by deriving a value using Equation 1.

In Equation 3, A ₁ is the area of the first blowing hole 521, A ₂ is the second, A ₃ is the third, A ₄ is the area of the last blowing hole 521, and the blowing hole 521 ) Is preferably formed equal to the width of the guide panel 522.

As described above, the size of the blowing hole 521 and the size of the guide panel 522 through Equations 1 to 3 are as shown in the embodiment in FIG. 6.

The operation of the battery enclosure for controlling the internal temperature by the same blowing function according to the present invention configured as described above will be described.

In the present invention, in a state in which the battery pack 210 is installed in the battery rack 200 in the cabinet 100 in connection with solar power generation, the internal temperature and humidity, and charging and discharging are controlled by the BMS 300.

As described above, when the temperature of the cabinet 100 rises in a state controlled by the BMS 300, gas is generated and leaked, and the generated gas is the exhaust fan 110 installed in the cabinet as shown in FIG. ), and when the pressure of the gas rises excessively, the risk of explosion of the battery pack 210 increases, so that the solenoid valve 120 is opened to instantly reduce the pressure.

In more detail, the gas generated by the battery

The pressure is checked through a sensor installed inside the cabinet, and the checked pressure is lowered by first operating the exhaust fan 110 under the control of a controller (not shown) installed inside the BMS (300). Make it possible.

When the discharge of gas through the exhaust fan 110 does not have a discharge power enough to lower the pressure, the solenoid valve 120 installed at the lower part of the cabinet 100 is installed to prevent the battery from being exploded. It is operated by the control unit so that the gas flows into the vacuum tank 130 to reduce the pressure.

In addition, when the pressure rises directly to the explosion, the solenoid 120 and the exhaust fan 110 installed at the bottom and the top of the cabinet 100 are simultaneously operated so that the excessively elevated pressure can be momentarily lowered. Prevent car accidents.

In addition, when the solenoid 120 is opened, the charging/discharging function of the battery is stopped to prevent further gas discharge.

In addition, through temperature control by the thermo-hygrostat 400, the external temperature of the battery is lowered to suppress an increase in battery temperature, and if gas is discharged due to an abnormal temperature increase, the internal gas is primarily discharged to the exhaust fan 110, and If the pressure is exceeded, the internal pressure is reduced by opening the solenoid valve 120 to prevent pressure explosion, thereby minimizing the damage caused by the accident by suppressing fire and explosion accidents of the battery to the maximum.

And when the temperature rises, such as in summer, when the temperature rises inside the cabinet 100, the thermo-hygrostat 400 is operated to supply wind so that the set temperature can be maintained. At this time, the thermo-hygrostat 400 is the main The wind is supplied to the duct 510, and the main duct 510 again supplies the wind to the branch duct 520 to supply the air to the upper inner side of the cabinet 100 through the blowing hole 521 to provide the exhaust duct 530. By driving the exhaust fan 110 so that the exhaust is achieved through, the elevated temperature can be lowered.

However, when the temperature goes down to sub-zero temperatures, such as in winter, the thermo-hygrostat 400 is operated to supply wind to the branch duct 520 through the main duct 510 to maintain the set temperature. In this case, the exhaust duct 530 The exhaust fan 110 is maintained in a stopped state so that warm wind cannot be discharged.

As described above, the wind supplied through the exhaust duct 530 is discharged to the guide door ventilation hole 521 by the guide panel 522. At this time, since the size of the guide panel 522 and the ventilation hole 521 are the same, And since the wind is discharged equally, the heat generated by the battery pack 210 is moved to the upper side of the cabinet 100 because the wind is evenly supplied to the entire cabinet, and the exhaust duct 530 and the exhaust fan 110 It is easy to discharge, so it is easy to maintain the set temperature.

As described above, the present invention increases the length of the guide panel 522 installed in the air duct 500 as the distance from the thermo-hygrostat 400 to which wind is supplied increases, and is supplied into the air duct 500. Since the wind speed and air volume of the wind are equally discharged through the blowing hole 521, there is an advantage of preventing an increase in internal temperature and pressure by evenly supplying wind to the entire interior of the cabinet 100.

In addition, in order to prevent battery accidents, it is manufactured integrally with the thermo-hygrostat 400 that prevents an increase in battery temperature, and there is an advantage in that the performance of the battery is always maintained constant by controlling the internal temperature.

While this specification includes details of a number of specific implementations, these should not be construed as limiting to the scope of any invention or claim, but rather as a description of features that may be peculiar to a particular embodiment of a particular invention. It must be understood. Certain features described herein in the context of separate embodiments may be implemented in combination in a single embodiment. Conversely, various features described in the context of a single embodiment can also be implemented in a plurality of embodiments individually or in any suitable sub-combination. Furthermore, although features operate in a particular combination and may be initially described as so claimed, one or more features from a claimed combination may in some cases be excluded from the combination, and the claimed combination may be a subcombination. Or sub-combination variations.

On the other hand, the embodiments of the present invention disclosed in the specification and drawings are only presented specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is apparent to those of ordinary skill in the art that other modified examples based on the technical idea of the present invention may be implemented.

100: cabinet 110: exhaust fan
120: solenoid valve 130: vacuum tank
200: battery rack 210: battery pack
300: BMS 400: thermo-hygrostat
410: outdoor unit 500: air duct
510: main duct 511: main air outlet
520: branch duct 521: ventilation hole
522: guide panel 530: exhaust duct

Claims (6)

A cabinet 100 in which an exhaust fan 110 for discharging gas and a door through which the administrator enters and exits are installed, and a space is formed to install a battery rack 200 in which a plurality of battery packs 210 are installed;
A battery rack 200 in which a plurality of battery packs 210 are installed and installed inside the cabinet 100;
A BMS (battery management system) 300 for controlling the battery pack 210 installed in the battery rack 200;
A thermo-hygrostat 400 installed inside the cabinet 100 so that the battery can maintain a uniform performance by maintaining a constant temperature and humidity inside the cabinet 100;
An air duct 500 connected to the thermo-hygrostat 400 and installed under the battery rack 200 so that air having a uniform air density can be supplied to the entire interior of the cabinet 100 by the same air volume and wind speed;
The battery enclosure for controlling the internal temperature by the same blowing function, characterized in that it comprises a.
The method of claim 1,
The cabinet 100,
If the internal pressure exceeds a certain pressure, the solenoid valve 120 is further configured to release the pressure, characterized in that the battery enclosure for controlling the internal temperature by the same blowing function.
The method of claim 1,
The air duct 500,
A main duct 510 connected to a thermo-hygrostat so as to supply wind;
A branch duct 520 branched from the main duct 510 and installed at least one under the battery rack so that wind is supplied from the bottom side of the cabinet 100 to the top side;
An exhaust duct 530 installed on the inside of the cabinet 100 so as to be installed on the top of the cabinet 100 to circulate the wind containing heat or gas by the thermo-hygrostat 400 or to discharge it to the outside of the cabinet 100 );
The battery enclosure for controlling the internal temperature by the same blowing function, characterized in that it comprises a.
The method of claim 2,
The branch duct 520,
A blowing hole 521 formed at a predetermined interval so that wind can be discharged;
Guide panels 522 having different lengths based on the distance around the thermo-hygrostat 400 so that wind having an air density can be supplied by the same air volume and wind speed;
The battery enclosure for controlling the internal temperature by the same blowing function, characterized in that it comprises a.
The method of claim 1,
The wind speed is,

It is calculated by the equation consisting of, A is the cross-sectional area, p is the air density, v is the wind speed, characterized in that the battery enclosure for controlling the internal temperature by the same blowing function.
The method of claim 1,
The supply of wind with uniform air density according to the air volume and wind speed,

Is,

ego,

The battery enclosure for controlling the internal temperature by the same blowing function, characterized in that the size of the blowing hole is set by the equation consisting of.

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