KR20220084728A - Chamber for battery temperature test - Google Patents

Abstract

The present invention relates to a battery temperature test chamber, and more particularly, by placing a battery as a test object in a test room and maintaining the temperature of the test room constant for a long time to check the state of the battery at the corresponding temperature, A test room and an air processing room are formed, and the amount of air supplied to the test room is adjusted according to the temperature of the air, and the air not supplied to the test room is circulated to the air processing room to increase the processing efficiency of the air and to increase the processing efficiency of the test room. It relates to a battery temperature test chamber that can keep the temperature of the test room stable by preventing the occurrence of dew condensation.

Description

Chamber for battery temperature test

The present invention relates to a battery temperature test chamber, and more particularly, by placing a battery as a test object in a test room and maintaining the temperature of the test room constant for a long time to check the state of the battery at the corresponding temperature, A test room and an air processing room are formed, and the amount of air supplied to the test room is adjusted according to the temperature of the air, and the air not supplied to the test room is circulated to the air processing room to increase the processing efficiency of the air and to increase the processing efficiency of the test room. It relates to a battery temperature test chamber that can keep the temperature of the test room stable by preventing the occurrence of dew condensation.

In general, in the case of a product that generates heat during operation, such as a battery or semiconductor component, after the manufacturing process is completed, the quality of the product is tested in various environments.

For example, after placing the test object in a predetermined space, the operation may be tested under severe conditions according to temperature change or temperature maintenance, and whether or not explosive by operating at high temperature for a long time may be tested.

As a device used herein, a test chamber for arranging a test object is provided. The test chamber has a test room therein, and a heating device or a cooling device for forming a temperature condition required for the test room is provided.

However, the conventional test chamber has a problem in that condensation occurs on the outer wall of the test room because the temperature difference between the inside and the outside of the test room occurs. There was a difficult problem.

In addition, there is additional heat generated during the operation of the test object placed in the test room. Due to this additional heat, it is difficult to maintain the temperature of the test room at the set temperature. There was a problem that the temperature distribution was non-uniform.

In other words, in order to maintain the temperature of the test room, the temperature of the supplied air is set by controlling the operation of the heating device or cooling device. there was

Republic of Korea Patent Publication No. 10-2013-0000551 (2013.01.03., published) Republic of Korea Patent Registration No. 10-2098564 (2020.04.02., registered)

The present invention has been proposed to solve the above problems, and an outer housing in the form of an enclosure is provided, and an inner housing disposed inside the outer housing is provided, and the inner housing includes a test room in which a test object is disposed, and the An air processing room for processing air to control the temperature of the test room is formed, and the structure of the heat circulation passage connecting the test room and the air processing room is improved to quickly respond to the temperature change in the test room and set for testing. An object of the present invention is to provide a chamber for temperature testing of a battery capable of maintaining the temperature.

In addition, the present invention is provided with an opening/closing module that is disposed between the test room and the air processing room, the opening angle of which is controlled by the moving pressure of the air processed in the air processing room, so that the inlet of the processed air according to the temperature change of the test room An object of the present invention is to provide a chamber for battery temperature test that is easy to control.

In order to achieve the above object, the present invention

Outer housing made of an empty housing shape inside;

A test room disposed inside the outer housing, an entrance through which the test object enters and exits is formed on one side, and an air inlet through which the processed air for testing the test object is introduced on the other side; and the test room an inner housing including an air processing room for processing air and a thermal circulation passage connecting the test room and the air processing room;

air processing means disposed in the air processing room to heat or cool the circulating air while operating by the applied power and signal;

a circulation fan disposed between the test room and the air processing room to deliver the air processed in the air processing room to the test room;

An opening/closing module disposed on one side of the test room to restrict the air delivered by the circulation fan from entering the test room; including,

The opening/closing module is

an opening and closing plate extending in the longitudinal direction and disposed at the air inlet of the test room;

A shaft bar formed in the form of a rod extending in the longitudinal direction, one end in the longitudinal direction is rotatably coupled to the inner housing, and the central portion in the width direction of the opening and closing plate is coupled;

a control box disposed in the outer housing and rotatably coupled to the other end of the shaft in the longitudinal direction;

It is provided in the control box and characterized in that it includes a control means for controlling the rotation of the shaft.

In addition, the control means, a pair of protrusions formed symmetrically on the outer circumferential surface of the shaft, and a pair of guides arranged symmetrically in the interior of the control housing and having one side open and the other side closed, and the guide A pair of elastic springs inserted and one end coupled to the protrusion and the other end abutting against the closed end of the guide to form a tensile force pulling the protrusion toward the guide, and a pair disposed symmetrically inside the control housing It is characterized in that it includes a rotation limiting projection of.

In addition, the opening/closing plate is characterized in that a buffer plate bent to one side is formed on the upper end, the lower end, or both.

Furthermore, the heat circulation passage is formed in the interior of the inner housing to be isolated from the outside, a hot air supply passage through which the air processed in the air processing room moves to the test room, and the air that has passed through the test room is the It is characterized in that it includes a hot air passage that moves to the air processing room, and a circulation path in which air that has not been moved to the test room among the air processed in the air processing room returns to the air processing room.

In addition, the test room includes an upper plate made of a porous plate, a lower plate made of a porous plate and arranged to be spaced downward with respect to the upper plate, and a plurality of side plates made of a flat plate and disposed on the edges of the upper plate and the lower plate, It characterized in that it includes an opening and closing door for opening and closing the entrance.

The present invention, made as described above, maintains the inside of the test room at a uniform temperature so that an accurate test for a temperature change or operation at a high temperature of a test object is possible, and an air processing room for processing the air supplied to the test room. It has the effect of improving the accuracy of the test by providing stable processed air through the

In addition, according to the present invention, the opening angle of the opening/closing plate disposed on one side of the test room is controlled according to the moving pressure of the air processed in the air processing room, so that it is possible to quickly respond to temperature changes, thereby increasing the accuracy of the test,

Furthermore, the structure of the thermal circulation passage connecting the air processing room and the test room is improved, and in particular, the thermal circulation passage is formed around the outside of the test room to minimize the occurrence of condensation due to the temperature difference between the inside and the outside of the test room, enabling stable testing. It works.

1 is an exemplary view showing a battery temperature test chamber according to the present invention.
Figure 2 is an exploded view showing a state in which a part of the battery temperature test chamber according to the present invention is disassembled.
Figure 3 is a schematic view showing the inside of the chamber for a battery temperature test according to the present invention.
Figure 4 is a schematic view showing a state in which the air processed in the battery temperature test chamber according to the present invention moves.
5 is an exemplary view showing an opening/closing module according to the present invention.
6 and 7 are exemplary views showing the operating state of the opening/closing module according to the present invention.
8 is an exemplary view showing an angle maintaining means according to the present invention.

Hereinafter, in addition to the above object, other objects and features of the present invention will become apparent through the description of the embodiments with reference to the accompanying drawings.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, a preferred embodiment of the battery temperature test chamber according to the present invention will be described with reference to the accompanying drawings.

The battery temperature test chamber 1 according to the present invention, as shown in FIGS. 1 and 2, has an outer housing 10 in the form of an empty housing, and is disposed inside the outer housing 10, A test room 21 having an entrance 214 through which the test object B enters and exits is formed on one side and an air inlet 218 through which the processed air for testing of the test object B is introduced on the other side. , an inner housing including an air processing room 22 for processing the air supplied to the test room 21, and a heat circulation passage 23 connecting the test room 21 and the air processing room 22 ( 20), an air processing means 30 disposed in the air processing room 22 to heat or cool circulating air while operating by the applied power and signal, and the test room 21 and the air processing room ( 22) disposed between the circulation fan 40 for delivering the air processed in the air processing room 22 to the test room 21 side, and the circulation fan 40 disposed on one side of the test room 21 ) to include an opening/closing module 50 that restricts the introduction of air into the test room 21, and after placing the test object in the test room, the air processed by the air processing room is transferred to the test room. However, the amount of processed air supplied to the test room through the opening/closing means is controlled so that the inside of the test room can be maintained at a uniform temperature.

Looking at this in detail, the outer housing 10 is formed in the form of an empty housing, and the form of the outer housing 10 is variously changeable and is not limited to the form shown in the drawings.

In addition, the outer housing 10 is made of a material having low thermal conductivity or a material having low thermal conductivity in order to minimize heat generated during the test in the test room 21 formed in the inner housing 20 to be described later from being discharged to the outside. may be coupled to the inner wall constituting the outer housing 10 .

On the other hand, the external housing 10 may be provided with a control panel and a display for controlling the operation state of the test room 21 and confirming the operation state from the outside, and since these control panels and displays are known, detailed illustration and description are to be omitted.

The inner housing 20 is disposed inside the outer housing 10 to provide a test room 21 for testing the test object B and an air processing room for providing processed air to the test room 21 . Including (22), the test room 21 has an entrance 214 through which the test object (B) enters and exits on one side, and air through which air is introduced for testing of the test object (B) on the other side An inlet 218 is provided.

In addition, the air processing room 22 is for processing the air supplied to the test room 21, and an air processing means 30 to be described later is disposed therein.

Then, the test room 21 and the air processing room 22 are connected through a heat circulation passage 23, and the heat circulation passage 23 is a hot air supply passage through which the processed air moves to the test room 21 ( 231 ), a hot air passage 232 in which the air passing through the test room 21 moves to the air processing room 22 , and the test room 21 in the air processed in the air processing room 22 . ) includes a circulation path 233 in which the air that has not moved to the air processing room returns.

In the test room 21, the test object (B) is placed and the processed air is introduced to perform a test on the test object (B).

As shown in FIG. 2, the test room 21 includes an upper plate 211 made of a porous plate, a lower plate 212 formed of a porous plate and disposed at a position spaced downward with respect to the upper plate 211, and the It is vertically disposed to connect the edges of the upper plate 211 and the lower plate 212 and includes a plurality of side plates 213 in the form of a flat plate.

Here, the upper plate 211 and the lower plate 212 are made of a porous plate having a plurality of holes, as shown, so that the inlet and outlet of the processed air is made through the holes.

On the other hand, in the test room 21, the upper plate 211 and the lower plate 212 can be divided between the upper plate 211 and the lower plate 212 to be configured in multiple layers. shown) so as not to impede the movement of processed air.

In addition, although the shape of the test room 21 is shown in the drawing as a rectangular enclosure shape with one side open, this is an example and the cross-section can be changed to various shapes such as a circle or a polygon, of course.

And the doorway 214 formed on one side of the test room 21 is further provided with an opening/closing door 215 disposed in a rotating or sliding form, and the opening/closing door 215 can check the inside of the test room 21 from the outside. It is preferable that a transparent window be provided or made of a transparent material.

Subsequently, in the test room 21, a plurality of temperature sensors 216 and pressure sensors 217 for sensing internal pressure are further provided in order to detect the internal temperature. It is placed in a separate location to detect the internal temperature of the test room in real time and transmits the detected value to the control panel.

In addition, the pressure sensor 217 is for detecting a changed pressure in the test room when an explosion or a fire of the test object occurs during the test, and transmits the detected value to the control panel.

The air processing room 22 is formed in a position spaced apart from the test room 21 in the inner housing 20, and as shown in FIGS. 2 and 3, the air processing room 22 is the inner housing ( 20), it is partitioned through the partition plate 221, and the upper and lower ends are opened, respectively, so that the processed air is discharged through the upper end, and the circulated air is introduced through the lower end.

An air processing means 30 to be described later is disposed in the air processing room 22 made as described above, and a circulation fan 40 to be described later is disposed at the opened upper end.

The heat circulation passage 23 is composed of a hot air supply passage 231, a hot air transfer passage 232, and a circulation passage 233 as described above. Looking at this in detail,

The hot air supply path 231 is a path through which the air processed by the air processing means 30 is introduced into the test room 21 , and as shown in FIG. 3 , the upper side of the upper plate 211 of the test room 21 . is formed in

At this time, an opening/closing module 50 to be described later is disposed at one end of the hot air supply path 231 to limit the movement of air, which will be described in detail in the description of the opening/closing module 50 to be described later.

The hot air passage 232 is formed on the lower side of the lower plate 212 of the test room 21 as shown in FIG. 3 and the air passing through the test room 21 moves to the air processing room 22 . is the path

In addition, the circulation path 233 is a path through which the processed air whose movement to the test room 21 is blocked by the opening/closing module 50 moves to the air processing room 22 .

That is, the hot air passage 232 is a path through which the air passing through the test room 21 moves to the air processing room 22 , and the circulation path 233 is a path through which the air that has passed through the test room 21 moves. is the path to

This heat circulation passage 23 minimizes the loss of the air processed in the air processing room 22 to the outside of the inner housing 20 to increase the efficiency of the air processing means 30 and drive the air processing means 30 . You can reduce the cost of doing it.

In addition, as shown in the figure, the hot air passage 232 and the circulation passage 233 of the thermal circulation passage 23 are formed to surround the test room 21, so that the difference between the temperature inside the test room 21 and the temperature outside It is possible to minimize the occurrence of condensation due to

The air processing means 30 is disposed in the air processing room 22 and processes the air while operating by the applied power and signal, wherein the processing of air refers to raising or lowering the temperature of the air.

The air processing means 30 is spaced apart from the heating means 31 disposed in the air processing room 22 and heating the air while operating by power and a signal applied through the control panel, and the heating means 31 . and a cooling means 32 for lowering the temperature of the air while operating by power and signals applied through the control panel.

At this time, a heater may be used as the heating means 31 and an evaporator may be used as the cooling means 32 , but the present invention is not limited thereto. Of course, it is not limited to the form shown in the drawings as it can be changed according to the

The circulation fan 40 sucks in the air processed in the air processing room 22 and discharges it to the test room 21 side, and a coupling body 41 provided at the upper end of the air processing room 22 . and is coupled to the driving motor M that operates according to power and a signal applied through the control panel.

The coupling body 41 has an air inlet 42 communicating with the air processing room 22 in the center, and an opening 43 through which air is discharged on one side facing the test room 21. , the circulation fan 40 is disposed. This coupling body 41 prevents the circulation fan 40 from being displaced by vibration and shock generated during the stable arrangement and operation of the circulation fan 40, thereby stably moving the processed air and discharging it to the same position at the same time.

And the circulation fan 40 is operated by the control panel, that is, receives the sensed value of the temperature of the test room 21 from the control panel, and adjusts the rotational speed of the circulation fan 40 according to the received sensed value. Change the amount of air supplied by changing, and at the same time change the speed of movement of the supplied air.

As the opening angle of the opening/closing plate 51 is changed according to the changed air movement speed, the amount of air supplied to the test room 21 is also changed.

That is, the rotation speed of the circulation fan 40 according to the present invention is controlled according to the temperature of the test room, and the opening/closing plate 51 constituting the opening/closing module 50 to be described later is opened according to the rotation speed of the circulation fan. is adjusted, so that it not only responds quickly to temperature changes in the test room, but also does not require a flow control means such as a valve in supplying processed air to the test room 21, so that the structure is simple and quick response is possible.

The opening/closing module 50 is disposed on one side of the test room 21 to limit the air delivered by the circulation fan 40 from entering the test room 21. For this purpose, the opening/closing module ( 50) is made in the form of an opening and closing plate 51 extending in the longitudinal direction and disposed at the air inlet 218 of the test room 21, and a rod extending in the longitudinal direction, and one end of the inner housing 20 in the longitudinal direction ) is rotatably coupled to the shaft rod 52 to which the central portion of the width direction of the opening and closing plate 51 is coupled, and the other end of the shaft rod 52 disposed in the outer housing 10 in the longitudinal direction is rotatably coupled It includes a control box (53) and a control means (54) provided in the control box (53) to control the rotation of the shaft rod (52).

The opening/closing plate 51 is disposed in the air inlet 218 of the test room 21 formed in the form of a plate extending in the longitudinal direction as shown in FIG. 2 .

At this time, a buffer plate 511 bent to one side is further formed at the upper end and lower end of the opening and closing plate 51, and the buffer plate 511 has an air inlet 218 at the upper end and lower end in the process of the opening and closing plate 51 rotating. This is to minimize damage in contact with the upper plate 211 , the lower plate 212 or the side plate 213 constituting the .

That is, as shown in Fig. 6, when the opening/closing plate 51 rotates in the closed direction from the open state, it urgently rotates by the restoring force of the elastic spring 543 constituting the control means 54, then the upper end or The lower end may be damaged by contact with the upper plate, lower plate, or side plate constituting the inner housing, and by buffering the shock generated when abutting through the buffer plate 511, the shape deformation or damage of the opening and closing plate 51 is minimized. .

The shaft rod 52 is formed in the form of a rod extending in the longitudinal direction, so that one end in the longitudinal direction is rotatably coupled to the inner housing 20, and the other end in the longitudinal direction is rotatably coupled to the control housing 53, and the opening and closing plate ( 51) is coupled to the central portion in the vertical direction to rotatably support the opening/closing plate 51.

Here, the shaft rod 52 is shown as one circular rod extending in the longitudinal direction in the drawings, but after being formed into a pair, one end of each is coupled to the opening/closing plate 51 and the other end is the inner housing 20 and the control box. (53) may be of a form rotatably coupled to each.

The control housing 53 is disposed in the outer housing 10 and the other longitudinal end of the shaft rod 52 is rotatably coupled, and the interior is made in the form of an empty housing to rotate the shaft rod 52 inside. A limiting control means 54 is provided.

Here, an angle maintaining means 531 capable of maintaining the rotation angle of the shaft rod 52 is further provided on the outside of the control housing 53 , and the angle maintaining means 531 is located on the outer surface of the control housing 53 . A plurality of fitting holes 532 formed at regular intervals from each other, an angle retaining tool 533 to which the end of the shaft rod 52 is coupled, and the angle maintaining tool 533 are formed in the fitting hole 532 It includes a coupling protrusion 534 that is detachably coupled.

The angle maintaining means 531 made as described above restricts the rotation of the shaft rod 52 that rotatably supports the opening and closing plate 51 so that the opening and closing plate 51 maintains a set position. That is, when a predetermined amount of processed air needs to be continuously supplied to the test room 21 , the opening/closing plate 51 is rotated while maintaining a predetermined angle and the rotated position is fixed. Through this, even if the rotation speed of the circulation fan 40 is rotated at a relatively low speed, the processed air can be supplied, so that stable temperature control is possible.

The plurality of fitting holes 532 are each formed at a position spaced apart from each other, and they are arranged in an arc shape, and the number and distance between each other shown in the drawings are one embodiment, and the number and distance between them are can be changed in various ways.

The angle maintenance tool 533 is to be rotated after the user grips the angle of the opening and closing plate 51 can be adjusted, one end of the shaft rod (52) is coupled.

And the coupling protrusion 534 formed on the angle maintaining member 533 is formed in a push-pull shape to protrude outward or inward of the angle maintaining member 533 according to a user's manipulation, and when protruding outward, the fitting The angle of the opening/closing plate 51 is fixed by being inserted into the ball 532 and fixing the position of the angle maintaining tool 533 .

Afterwards, when the user wants to change the angle of the angle retaining tool 533, the coupling protrusion 534 is arranged inside the angle maintaining tool 533 and separated from the fitting hole 532, and then the angle of the angle maintaining tool is changed. will be.

On the other hand, the control housing 53 is provided with a control means 54 for limiting the rotation of the shaft rod 52, the control means 54 prevents the opening and closing plate 51 from being opened at a predetermined angle or more and at the same time This is to quickly return to the original position in the open state.

To this end, the control means 54 includes a pair of protrusions 541 formed symmetrically on the outer circumferential surface of the shaft rod 52, and symmetrically disposed inside the control box 53, one side is opened and the other side is A pair of closed guides 542, inserted into the guide 542, one end coupled to the protrusion 541, and the other end contacting the closed end of the guide 542 to guide the protrusion 541 It includes a pair of elastic springs 543 that form a pulling force to the 542 side, and a pair of rotation limiting protrusions 544 arranged symmetrically in the inside of the control housing 53 .

The pair of protrusions 541 protrude from the outer circumferential surface of the shaft rod 52 in mutually symmetrical directions.

The guide 542 is disposed symmetrically within the control housing 53, one side is open and the other side is closed, and the protrusion 541 is disposed to abut against the opened side. Here, the state in which the protrusion 541 is in contact with the open side of the guide 542 is a state in which the opening/closing plate 51 closes the air inlet 218 .

The elastic spring 543 is disposed on the guide 542, one end is coupled to the protrusion 541, the other end is disposed in contact with the closed end of the guide, and the protrusion 541 is directed toward the opening of the guide 542. Creates a pulling tension.

That is, the elastic spring 543 forms a force pulling the opening and closing plate 51 in a direction to close the air inlet 218 while the opening and closing plate 51 rotates to open the air inlet 218 .

The rotation limiting protrusion 544 is for limiting the maximum opening angle of the opening and closing plate 51, and when the shaft rod 52 rotates at the same time as the opening and closing plate 51 rotates, the protrusion 541 abuts. It is possible to limit the rotation of the shaft rod 52 and limit the opening angle of the opening and closing plate 51 through this.

The control means 54 configured as described above forms a tensile force so that the opening/closing plate 51 maintains the normally closed state of the air inlet 218 , and the opening and closing plate 51 rotates to open the air inlet 218 . Even in one state, the opening/closing plate 51 forms a pulling force in the direction to close the air inlet 218 to prevent the opening/closing plate 51 from being opened more than necessary by the moving pressure of the processed air.

And when the opening/closing plate 51 is rotated to return, that is, to close the air inlet 218, it is made to return quickly through the tensile force of the elastic spring 543, thereby preventing unnecessary processing of air from being supplied to the test room. You can get test results.

As described above, in the present invention, specific matters such as specific components, etc., and limited embodiments and drawings have been described, but these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

1: Chamber for battery temperature test
10: outer housing
20: inner housing
21: test room 22: air processing room
23: thermal circulation passage
231: hot air supply path 232: hot air transfer path
233: circuit
30: air processing means
31: heating means 32: cooling means
40: circulation fan
41: body for coupling 42: air intake hole
43: opening
50: opening/closing module
51: opening and closing plate 52: shaft rod
53: control box 54: control means
511: buffer plate
531: angle maintaining means 532: fitting hole
533: angle maintenance tool 534: coupling projection
541: protrusion 542: guide
543: elastic spring 544: rotation limiting projection

Claims (5)

The outer housing (10) made of an empty housing shape inside;
It is disposed inside the outer housing 10, the entrance 214 through which the test object (B) enters and exits is formed on one side, and the air inlet through which the processed air for the test of the test object (B) is introduced on the other side. The test room 21 equipped with 218 is connected to the air processing room 22 that processes the air supplied to the test room 21, and the test room 21 and the air processing room 22 are connected. an inner housing 20 including a thermal circulation passage 23;
an air processing means 30 disposed in the air processing room 22 to heat or cool the circulating air while operating by the applied power and signal;
a circulation fan 40 disposed between the test room 21 and the air processing room 22 to deliver the air processed in the air processing room 22 to the test room 21 side;
an opening/closing module 50 disposed on one side of the test room 21 to restrict the air delivered by the circulation fan 40 from entering the test room 21;
The opening/closing module 50,
an opening/closing plate 51 extending in the longitudinal direction and disposed at the air inlet 218 of the test room 21;
A shaft rod 52 made in the form of a rod extending in the longitudinal direction, one end in the longitudinal direction is rotatably coupled to the inner housing 20, and the central portion in the width direction of the opening and closing plate 51 is coupled;
a control box 53 disposed in the outer housing 10 and rotatably coupled to the other longitudinal end of the shaft rod 52;
Battery temperature test chamber, characterized in that it is provided in the control box (53) including a control means (54) for controlling the rotation of the shaft (52). The method according to claim 1, The control means (54),
A pair of protrusions 541 formed symmetrically on the outer circumferential surface of the shaft rod 52,
A pair of guides 542 arranged symmetrically inside the control box 53 and having one side open and the other side closed;
A pair inserted into the guide 542 , one end coupled to the protrusion 541 , and the other end in contact with the closed end of the guide 542 to form a tensile force pulling the protrusion 541 toward the guide 542 . of the elastic spring (543) and,
Battery temperature test chamber, characterized in that it includes a pair of rotation limiting projections (544) arranged symmetrically within the control box (53). The method according to claim 1, wherein the opening and closing plate (51)
A battery temperature test chamber, characterized in that the buffer plate 511 bent to one side is formed on the top or the bottom or both. The method according to any one of claims 1 to 3, wherein the thermal circulation passage (23),
Doedoe formed in isolation from the outside from the inside of the inner housing (20),
a hot air supply path 231 through which the air processed in the air processing room 22 moves to the test room 21;
a hot air passage 232 through which the air that has passed through the test room 21 moves to the air processing room 22;
The chamber for battery temperature test, characterized in that it includes a circulation path (233) through which air that has not been moved to the test room (21) among the air processed in the air processing room (22) returns to the air processing room (233). The method according to any one of claims 1 to 3, wherein the test room (21),
An upper plate 211 made of a porous plate, and
A lower plate 212 made of a porous plate and spaced downwardly with respect to the upper plate 211;
A plurality of side plates 213 made of a flat plate and disposed on the edges of the upper plate 211 and the lower plate 212;
Battery temperature test chamber, characterized in that it includes an opening/closing door (215) for opening and closing the entrance (214).

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