KR20210114119A - A Testing System Of Apparatus For Cooling Battery - Google Patents

Abstract

The present invention relates to a testing apparatus for a battery cooling device, by which a leakage test of the battery cooling device can be simply performed. The testing apparatus for a battery cooling device comprises: a test main body (110) which serves as a frame; a test unit which is installed in the test main body (110) and configured to supply air to a battery cooling device (10) to be tested so as to perform a pressing test; a code printing unit (171) on which a management code (B) is to be printed; a transfer attachment unit (130) which is installed in the test main body (110) and configured to attach the management code (B) printed on the code printing unit (171) to the battery cooling device (10) and read the attached management code (B); and a display unit (173) on which information about the management code read at the transfer attachment unit (130) is displayed. The test unit includes: a cooling device seating unit (140) which is installed on the test main body (110) so as to move in the front/rear directions and in which the battery cooling device to be tested is seated; a seating unit driving unit (160) which moves the cooling device seating unit (140) in the front/rear directions; and a pressing connection unit (190) connected to ports so as to block one port of the battery cooling device (10) seated on the cooling device seating unit (140) and supply air through the other port.

Description

A Testing System Of Apparatus For Cooling Battery

The present invention relates to an inspection device for a battery cooling device, and more particularly, to a battery cooling device testing device to which a leak test for a battery cooling mechanism and a management code are automatically attached.

Recently, as interest in environmental protection increases, the need for electric vehicles and hybrid vehicles that use electricity as a power source to replace conventional vehicles using fossil fuels is increasing, and production and demand are also increasing. These electric and hybrid vehicles (hereinafter referred to as 'electric vehicles') are equipped with batteries for storing and using electricity, and due to the characteristics of electric vehicles that cannot be frequently charged, a large-capacity battery (aka 'secondary battery') is required. . In general, a battery generates a large amount of heat during charging and discharging. In particular, in the case of a large-capacity battery, it accompanies more heat according to an increase in the amount of current during charging and discharging, and when the generated heat is not sufficiently removed, the performance of the battery is deteriorated, and furthermore, it may cause ignition or explosion.

Accordingly, in order to maintain and improve the performance of the battery, efficient cooling of the battery is required, and a water cooling method is adopted.

As shown in FIG. 1 , the battery cooling mechanism 10 is in contact with the lower surface of a battery (not shown) installed in an electric vehicle to absorb heat generated during charging and discharging of the battery, and is in contact with the battery. A heat exchange unit 11 is provided, which is a plate-shaped body that absorbs heat. The cooling water flows through a cooling water passage (not shown) formed in the heat exchange unit 11 . The heat exchange unit 11 is made of a material having excellent thermal conductivity, such as aluminum alloy or copper, so as to efficiently absorb heat generated from the battery.

The battery cooling mechanism 10 includes ports 13 and 15 which are pipes connected to communicate with the internal flow path of the heat exchange unit 11 . The ports 13 and 15 are provided to communicate with the internal flow path of the heat exchange unit 11 at a position that does not overlap the battery, so that the cooling water flows into the cooling water flow path of the heat exchange unit 11 through any one of the ports 13 and 15 . It flows in, circulates inside, and then flows out through another port. Ports through which the coolant flows in and out may be provided at various locations depending on the design of the vehicle.

The battery cooling mechanism 10 as described above has a structure in which the cooling water introduced through the inlet port circulates in the flow path inside the heat exchange unit 11 and is discharged through the outlet port, and the heat exchange unit 11 itself or the heat exchange unit 11 Cooling water leakage should not occur even at a pressure higher than a certain pressure in the connection parts of the and ports 13 and 15.

Conventionally, a test device for checking the leakage of the battery cooling mechanism 10 was not properly prepared, and it was managed in a manual manner according to the test results, so that the distinction between defective products and good products was not clearly made.

Korean Patent Laid-Open No. 10-2013-0112117

The present invention has been proposed to solve the problems of the prior art as described above, and the leakage test of the battery cooling mechanism is made simple, and a management code according to the leakage test result is attached, so that management is possible until after shipment, An object of the present invention is to provide an inspection device for a battery cooling device in which damage to the battery cooling mechanism is prevented during the test process and reliable results can be obtained.

The battery cooling device inspection device according to the present invention comprises a test body serving as a frame, a test section installed in the test body and performing a pressure test by supplying air to the battery cooling mechanism to be tested, and a code printing section on which a management code is printed; , It is installed in the test body and attaches the management code printed by the code printing unit to the battery cooling mechanism and includes a transfer attachment unit that reads the attached management code, and a display unit on which the management code information read from the transfer attachment unit is displayed. ;

The test unit is installed movably in the front-rear direction on the test body and includes a cooling mechanism seating part on which the battery cooling mechanism to be tested is seated, a seating part driving part for moving the cooling mechanism seating part in the front-back direction, and the cooling mechanism seating part One port of the seated battery cooling mechanism is blocked and provides a test device for a battery cooling device, characterized in that it includes a pressurized connection connected to the port to supply air to the other port.

In the above, the cooling mechanism seating portion is guided along the seating guide installed in the test body to move forward and backward, and spaced apart in the width direction to form seating jaws on which both sides of the heat exchange part of the battery cooling mechanism are supported, and the battery cooling mechanism is formed between the seating jaws. A port hole into which the port is inserted is formed, and the bottom surface on which the port hole is formed is spaced apart from the heat exchange unit; A seating portion concave portion is formed at the front end in a form in which the bottom portion is removed, and a heat exchange portion of the battery cooling mechanism seated in the cooling mechanism seating portion is formed to cover the seating portion concave portion.

In the above, the test body is formed with a test body hole; The pressure connection part includes a connection body installed to be movable up and down through the test body hole, a pressure connection driving part for moving the connection body up and down, and a connection pipe which is provided spaced apart from the upper surface of the connection body and is a tube opened upwards; , It is connected to one of the connecting pipe and the other side includes a connecting pipe connected to the air supply means;

The connection body is raised by the driving of the pressurized connection driving part, and the ports protruding downward through the port holes are respectively inserted into the connection pipe, and the air supplied from the air supply means is supplied through the connection pipe on one side, so that the battery cooling mechanism is operated. It is characterized in that it is pressurized.

In the above, a plate-shaped seating part support part that is spaced upward from the test body is further included, and when the cooling mechanism seating part advances by the operation of the seating part driving part, it is located on the lower surface of the seating part support part, and when the battery cooling mechanism is pressurized from the bottom It is characterized in that the upper part is supported by the lower surface of the seat support part,

In the above, a seating support recess is formed at the front end of the seating part support part, and when the cooling mechanism seating part advances due to the operation of the seating part driving part, it is seated on the cooling mechanism seating part and advances together with the heat exchange part of the battery cooling mechanism the front end is exposed through the seating support recess; The management code transferred by the transfer attachment part is characterized in that it is attached to the exposed heat exchange part through the seating support recess.

In the above, the cooling mechanism seating part includes a plate-shaped metal seating member provided with a moving block capable of moving forward and backward along the seating guide at the lower portion, and a plate-shaped seating part body made of synthetic resin provided on the upper surface of the seating member. includes; The seating jaw portion and the bottom surface, which is a surface spaced downward from the seating jaw portion, is formed in the seating part body, and the port hole is formed through the seating member and the seating part body.

In the above, the transfer attachment part is provided in the test body and includes a transfer frame extending from the upper part of the code printing part past the upper part of the test part, a movable member provided movably in the longitudinal direction of the transfer frame, and the movable member a code reader, a code transfer attachment part provided on the movable member on one side of the code reader and installed movably in the vertical direction by an attachment driving part, and a code transfer driving part for moving the movable member along the transfer frame; A code attachment part is provided at the lower end of the code transfer attachment part, and the code transfer attachment part moved to the upper part of the code printing part along the transfer frame descends by the driving of the attachment driving part and is printed by the code printing part on the code attachment part provided at the bottom. A managed code is attached and separated from the paper; It is characterized in that it moves to the upper part of the test part while ascending by the operation of the attachment driving part and the cord transfer driving part.

In the battery cooling device inspection device according to the present invention, the leakage test of the battery cooling mechanism is simple, damage to the battery cooling mechanism is prevented during the test process, reliable results can be obtained, and the management code according to the leakage test result is attached, so it has the effect of being able to manage it until after shipment.

1 is a perspective view schematically showing an example of a battery cooling mechanism;
2 is a schematic plan view of an inspection device of a battery cooling device according to the present invention,
Figure 3 is a schematic partial front view shown in the "A" direction of Figure 2,
4 is a schematic plan view showing a cooling mechanism seating part provided in the inspection device of the battery cooling device of the present invention,
5 is a schematic front view showing a part of the cord transfer attachment part provided in the inspection device of the battery cooling device of the present invention,
6 is a schematic plan view showing a pressurized connection unit provided in the test device of the battery cooling device of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the inspection apparatus of the battery cooling device according to the present invention.

2 is a schematic plan view of an inspection device for a battery cooling device according to the present invention, FIG. 3 is a schematic partial front view taken in the direction “A” of FIG. 2 , and FIG. 4 is an inspection device for a battery cooling device of the present invention. It is a schematic plan view showing a cooling mechanism seating part provided, and FIG. 5 is a schematic front view showing a part of a cord transfer attachment part provided in the inspection device of the battery cooling device of the present invention, and FIG. 6 is an inspection of the battery cooling device of the present invention. It is a schematic plan view showing a pressure connection unit provided in the device.

In the following description, the vertical direction of FIG. 2 is the front-back direction, the horizontal direction is the width direction, and the vertical direction of FIG. 5 is the up-down direction.

As shown in FIG. 2 , the battery cooling mechanism testing apparatus 100 according to the present invention includes a test body 110 , a test part, a transfer attachment part 130 , a code printing part 171 , and a display part 173 . is done by The test unit, the transfer attachment unit 130 , the code printing unit 171 , and the display unit 173 of the battery cooling device testing apparatus 100 are connected to and controlled by a control unit.

The test body 110 becomes a frame. The test part, the transfer attachment part 130 , the code printing part 171 , and the display part 173 are installed in the test body 110 . A horizontal frame 120 spaced upward and extending in the width direction may be further provided on the upper portion of the test body 110 .

A plurality of mounting guides 101 are provided on the upper portion of the test body 110, which are spaced apart in the width direction, extend in the front-rear direction, and are parallel to each other. The seating guide 101 is provided with two seating guide 101 as a pair. One or more test units are provided in the battery cooling device testing apparatus 100 , and a pair of mounting guides 101 are installed in one test unit. The seating guide 101 serves to guide the cooling mechanism seating part 140 when it moves forward and backward.

A test body hole 113 is formed in the test body 110 . The test body hole 113 is formed between the two seating guides 101 forming a pair, and the cooling mechanism seating part 140 of the test part moves forward at the lower part of the cooling mechanism seating part 140 . is formed with

The test unit is installed in the test body (110). In the test unit, air is supplied to and pressurized to the battery cooling mechanism 10 to be tested. One or more test units are installed, and are spaced apart from each other in the width direction. The test part includes a cooling mechanism seating part 140 , a seating part driving part 160 , a seating part support part 150 , and a pressure connection part 190 .

As shown in FIGS. 3 and 4 , the cooling mechanism seating part 140 is guided by a seating part guide 101 installed on the test body 110 and is installed to be movable in the front-rear direction. The battery cooling mechanism 10 to be tested is seated on the cooling mechanism seating part 140 .

The cooling mechanism seating part 140 is provided in a plate shape. The cooling mechanism seating portion 140 is formed with a bent portion bent concavely upward. Seating jaws 141 are formed in the bent portion to be spaced apart in the width direction to support both sides of the heat exchange portion 11 of the battery cooling mechanism 10 . A bottom surface 143 spaced downward from the seating jaw part 141 is provided between the seating jaw parts 141 . A port hole 145 into which the ports 13 and 15 of the battery cooling mechanism 10 are respectively inserted between the seating jaws 141 is formed in the bottom surface 143 . The bottom surface 143 is spaced apart from the heat exchange unit 11 seated on the cooling mechanism seating unit 140 .

A seating part concave part 147 is formed at the front end of the cooling mechanism seating part 140 in a form in which the bottom part 143 is removed. The cooling mechanism seating part 140 is formed in such a size that the heat exchange part 11 of the battery cooling mechanism 10 seated on the cooling mechanism seating part 140 covers the seating part concave part 147 . When the battery cooling mechanism 10 is operated in a state in which the seating part recessed part 147 is formed, the test sensor 105 cannot sense the seating part recessed part 147 penetrating up and down, such as an alarm, etc. may cause a warning, and the test will not proceed any further, so that the operation is safe.

The cooling mechanism seating part 140 includes a seating member 140-1 and a seating part main body 140-3.

The seating member 140-1 is made of a plate-shaped metal in which a guide block 103 that enables forward and backward movement along the seating guide 101 is installed at the lower portion.

The seating part body 140-3 is provided on the upper surface of the seating member 140-1. The seating part body 140-3 is provided in a plate shape made of synthetic resin.

The seating jaw part 141 and the bottom surface 143, which is a surface spaced downward from the seating jaw part 141, is formed in the seating part main body 140-3, and the port hole 145 is formed with the seating member 140-1 and It is formed through the seating part body (140-3). The seating part main body 140-3 may be provided by being coupled to the upper surface of the seating member 140-1 by fastening a bolt or the like.

The cooling mechanism seating part 140 is composed of a metal seating member 140-1 and a synthetic resin seating part body 140-3 provided on an upper surface thereof, and the battery cooling mechanism 10 is mounted on the seating part body 140. -3) prevents contact deformation or impact occurring in the battery cooling mechanism 10 during the test process, thereby preventing defects that may occur during the test.

In addition, since the seating part body 140-3 is made of synthetic resin, the deformation of the battery cooling mechanism 10 is minimized even when the battery cooling mechanism 10 is press-fitted and inserted between the inner surfaces of both sides of the seating jaws 141 facing each other. As a result, a sufficient degree of interference fit design is possible.

The cooling mechanism seating part 140 may further include a seating part connecting member 140-5 on one side of the seating part main body 140-3 on the upper surface of the seating member 140-1. The seating part connecting member 140-5 is fixed to the seating member 140-1 by being coupled with bolts or screws. The seating part connecting member 140-5 extends in the width direction, and the seating part driving part 160 is coupled to the lower part, so that the cooling mechanism seating part 140 moves forward and backward by the operation of the seating part driving part 160 .

The cooling mechanism seating part 140 may be provided in which the seating member 140-1 extends in the width direction instead of the seating part connecting member 140-5, and the seating part driving part 160 is coupled to the lower part.

The seating part driving part 160 is provided on one side of the seating part guide 101 . The seating part driving unit 160 is installed on the test body 110 and serves to move the cooling mechanism seating part 140 in the front-rear direction. Examples of the seating part driving unit 160 include a cylinder, a ball screw, and the like. As shown in FIG. 2 , a part of the seating part driving part 160 and the seating part guide 101 protruding to the rear of the horizontal frame 120 is covered with a protective cover 180 for the safety of workers. can be provided.

The seating part support part 150 is provided to be spaced upward from the test body 110 . The seating part support part 150 is provided in a plate shape. The seating part support part 150 is fixedly provided with a part of the upper surface coupled to the horizontal frame 120 .

The cooling mechanism seating part 140 is operated by the seating part driving part 160 . When moving forward, it is positioned as the lower surface of the seating portion support 150 . At this time, the seating part support part 150 serves to support the upper part of the battery cooling mechanism 10 when the battery cooling mechanism 10 seated on the cooling mechanism seating part 140 is pressurized from the bottom by the pressurizing connection part 190 . do

A seating support concave part 155 and a support part through-hole 151 are formed in the seating part support part 150 .

The seating support concave part 155 is formed by removing a part of the front end of the seating part support part 150 . By the operation of the seating part driving unit (160) When the cooling mechanism seating part 140 moves forward, the front end of the heat exchange part 11 of the battery cooling mechanism 10 that is seated on the cooling mechanism seating part 140 and advanced together is exposed through the seating support recess 155 .

The support part through-hole 151 is spaced apart from the rear of the seating support recess 155 and penetrates in the vertical direction. The support part through-hole 151 is exposed through the support part through-hole 151 when the battery cooling mechanism 10 seated on the cooling mechanism seating part 140 advances together with the cooling mechanism seating part 140, and the battery cooling mechanism 10 can be visually confirmed.

As shown in FIG. 6 , the pressure connection part 190 is installed to be movable up and down in the test body hole 113 formed in the test body 110 . The pressure connection unit 190 includes a connection body 192 , a pressure connection drive unit (not shown), a connection pipe 191 , and a connection pipe 193 .

The connection body 192 is provided in the test body 110 and is installed to be movable up and down through the test body hole 113 .

The pressure connection driving unit is provided as a lower portion of the connection body 192 in the test body 110 to move the connection body 192 up and down. A cylinder or the like is used as the pressure connection driving part. By the operation of the pressure connection driving part, the connection body 192 is supported by a connection guide block 195 located in the width direction or front and rear and a connection guide 197 provided in the width direction or front and rear of the test body hole 113. It moves up and down by sliding.

The connection pipe 191 is provided on the upper surface of the connection body 192 . Two connection pipes 191 are provided and are provided to be spaced apart from each other. The connecting pipe 191 is provided as a pipe that is opened upward. Ports 13 and 15 inserted into the connecting tube 191 are provided with O-rings so that the ports 13 and 15 are press-fitted into the connecting tube 191, and a gap between the ports 13 and 15 and the connecting tube 191 is provided. sealed The O-ring may be provided in the connection pipe 191 .

The connecting pipe 193 is connected to a pressurized air supply means such as a compressor. The connection pipe 193 is connected to one of the connection pipes 191 through a connection screw 193-1, and the other end is connected to a pressurized air supply means such as a compressor. An opening/closing valve (not shown) connected to and controlled by the control unit is installed in the connection pipe 193 .

The pressure connection part 190 supplies air to the port 13 or 15 of the battery cooling mechanism 10 seated on the cooling mechanism seating part 140 at the position in which the cooling mechanism seating part 140 is advanced so that the pressure is increased. to be sensed. As for the pressure connection part 190, the connection body 192 is raised by the driving of the pressure connection driving part, and the ports 13 and 15 protruding downward through the port hole 145 are inserted into the connection pipe 193, respectively, and , the air supplied from the air supply means is supplied through the connection pipe 193 on one side to pressurize the battery cooling mechanism 10 . The pressure connection part 190 is connected to the port to supply air to the other port while blocking one port of the battery cooling mechanism 10 .

The transfer attachment part 130 is installed on the test body 110 . The transfer attachment unit 130 serves to attach the management code (B) to the battery cooling mechanism (10) tested in the test unit and to read the attached management code (B). The transfer attachment unit 130 is provided on the upper portion of the code printing unit 171 for printing the management code (B).

As shown in FIG. 5 , the transfer attachment unit 130 includes a transfer frame 131 , a moving member 137 , a code transfer drive unit, a code reader 133 , and a code transfer attachment unit 135 . made including

The transfer frame 131 is provided on the test body 110 and extends from the upper part of the code printing part 171 through the upper part of the test part in the width direction. The transfer frame 131 is provided in front of the seating part support 150 . The transfer frame 131 is provided with a moving member guide 139 that is installed extending along the longitudinal direction.

The moving member 137 is provided to be movable along the longitudinal direction of the transfer frame 131 . The moving member 137 reciprocates in the longitudinal direction of the transfer frame 131 while being guided by the moving member guide 139 by driving the code transfer driving unit. The code transfer driving unit may be a cylinder or a ball screw-motor.

The code reader 133 is provided on the movable member 137 . The code reader 133 extends in the vertical direction and is fixedly provided at the lower end of the reader installation part 133-1, the upper part of which is fixed to the moving member 137.

The code transfer attachment part 135 is provided on the movable member 137 on one side of the code reader 133 . The cord transfer attachment part 135 includes an attachment guide 135-3, an attachment drive part 135-1, a connecting pipe body 135-5, and a cord attachment part 135-7.

The attachment guide 135-3 is provided in the form of a rod extending in the vertical direction. The attachment guides 135-3 are two, and are spaced apart from each other in the width direction and provided side by side.

The attachment driving part 135 - 1 is coupled to the attachment guide 135 - 3 and is installed so as to reciprocate in the vertical direction. The attachment driving part 135 - 1 may be provided as a cylinder or a ball screw-motor. The connecting pipe body 135-5 is provided to extend downwardly from the attachment driving part 135-1. A cord attachment part 135-7 is provided at the lower end of the connecting pipe body 135-5.

The attachment driving part 135-1 may be a cylinder operated by pneumatic pressure, and the movable member 137 is provided with an attachment guide 135-3 which is a guide bar extending in the vertical direction, and the attachment driving part 135-1 is provided. ) may be guided by the attachment guide 135-3 to reciprocate up and down.

The cord transfer attachment part 135 forms a flow path communicating with the cord attachment part 135-7, and connects the pipe so that it is adsorbed, so that the management code (B) is attached to the paper (P) in the cord attachment part 135-7. ) can be separated from

The code transfer attachment part 135 moves to the upper part of the code printing unit 171 along the transfer frame 131 and the code transfer attachment part 135 descends by the driving of the attachment driving unit 135-1 while lowering it. The management code (B) printed by the code printing unit 171 is attached to the code attaching unit 135-7 provided in the It is moved to the upper part of the test section as it rises in operation.

When the test part is moved to the upper part, the cord transfer attachment part 135 descends by the operation of the attachment driving part 135-1, and the management code (B) is applied to the heat exchange part 11 of the battery cooling mechanism 10 located at the lower part. attach it The management code (B) transferred by the transfer attachment part 130 is attached to the heat exchange part 11 exposed through the seating support concave part 155 . At this time, the suction of the cord attaching part 135-7 is released. And it rises again, and the code reader 133 located on one side reads the management code B attached to the heat exchange unit 11 , and the read information is stored in the storage unit and displayed on the display unit 173 . The display unit 173 may be, for example, an LCD panel.

The test part, the transfer attachment part 130, the display part 173, the test sensor 105, the pressure sensor (not shown) of the battery cooling mechanism testing apparatus 100, the moving member 137 of the transfer attachment part 130 ), the code transfer driving unit (not shown), the pressure connection unit 190, and the code printing unit 171 are connected to the control unit, and the control unit controls their driving.

The control unit drives and controls the pressure connection driving unit that moves the pressure connection unit 190 up and down, and controls opening and closing of the opening/closing valve provided in the connection pipe 193 of the pressure connection unit 190 .

In addition, the control unit controls the adsorption air of the code reader 133 of the transfer and attachment unit 130, the attachment driving unit 135-1 of the code transfer attaching unit 135, and the cord attaching unit 135-7 to control the paper ( Separate the management code (B) from P).

Hereinafter, a test process of the battery cooling mechanism testing apparatus 100 according to the present invention will be described.

The battery cooling mechanism ( 10) is seated on the cooling mechanism seating part 140 . The ports 13 and 15 have an end protruding downward through the port hole 145 , and the heat exchange unit 11 is provided to cover the seating portion concave portion 147 .

The seating part driving unit 160 is operated by sensing or a switch input, and the cooling mechanism seating part 140 moves forward and is supported by the lower surface of the seating support part 150 and moves to the upper part of the pressurizing connection part 190 . A front part of the heat exchange part 11 of the battery cooling mechanism 10 is exposed as a seating part concave part 147 formed in a form in which a part of the front end of the cooling mechanism seating part 140 is removed.

After the test sensor 105 senses the heat exchange part 11 covered with the upper part of the seating part concave part 147 and confirms that the battery cooling mechanism 10 is mounted, the connection part body 192 rises by the operation of the pressurized connection driving part. and ports 13 and 15 are inserted into each connector 191 .

Air is supplied through a connection pipe 193 connected to one of the connection pipes 191, and the air pressure is sensed by a pressure sensor (digital pressure gauge) and maintained for a predetermined time. The test result through the pressure sensor is transmitted to the control unit, and a management code (B) is printed in the code printing unit 171 .

As the code transfer attachment part 135 of the transfer attachment part 130 descends, the printed management code (B) is separated from the paper (P), attached to the code attachment part 135-7, and tested by the operation of the code transfer driver. A management code (B) is attached to the heat exchange part 11 exposed to the seating part support recessed part 155 by moving to the upper part of the battery cooling mechanism 10 and descending.

The management code (B) attached to the code reader 133 provided on one side of the code transfer attachment unit 135 of the transfer attachment unit 130 is read, and the reading result is stored in the storage unit and the display unit 173 ) is displayed. The information displayed on the display unit 173 can be checked by the operator.

The transfer attachment part 130 moves toward the original position of the code printing part 171 , and after the cooling mechanism seating part 140 is moved backward by the driving of the seating part driving part 160 , it is placed on the cooling mechanism seating part 140 . Recovers the seated battery cooling mechanism 10 and completes the work.

100: test device of the battery cooling device 110: test body
120: horizontal frame 130: transfer attachment
140: cooling mechanism seating part 150: seating part support part
160: seating unit driving unit 171: code printing unit
172: display unit 180: protective cover
190: pressure connection part

Claims (7)

A test body 110 as a frame, a test part installed in the test body 110 and performing a pressure test by supplying air to the battery cooling mechanism 10 to be tested, and a code printing on which the management code (B) is printed Transfer for attaching the unit 171 and the management code (B) installed in the test body 110 and printed by the code printing unit 171 to the battery cooling mechanism 10 and reading the attached management code (B) It includes an attachment unit 130 and a display unit 173 on which management code information read from the transfer attachment unit 130 is displayed;
The test unit is installed movably in the front-rear direction on the test body 110 and includes a cooling mechanism seating part 140 on which the battery cooling mechanism to be tested is seated, and a seating part for moving the cooling mechanism seating part 140 in the front-rear direction. One port of the battery cooling mechanism 10 seated on the driving unit 160 and the cooling mechanism seating unit 140 is blocked and the pressure connection unit 190 connected to the port to supply air to the other port is characterized in that it comprises a Inspection device 100 of the battery cooling device. According to claim 1, wherein the cooling mechanism seating part 140 is guided along the seating guide 101 installed in the test body 110, forward and backward, and spaced apart in the width direction, the heat exchange part of the battery cooling mechanism (10) ( 11) The seating jaw portions 141 supported on both sides are formed, and port holes 145 into which the ports 13 and 15 of the battery cooling mechanism 10 are respectively inserted are formed between the seating jaw portions 141, the The bottom surface 143 on which the port hole 145 is formed is spaced apart from the heat exchange unit 11 ;
A seating portion concave portion 147 is formed at the front end in a form in which the bottom portion 143 is removed, and the heat exchange portion 11 of the battery cooling mechanism 10 seated on the cooling mechanism seating portion 140 is recessed in the seating portion. Inspection apparatus 100 of the battery cooling device, characterized in that formed to cover the portion (147). According to claim 2, wherein the test body (110) is formed with a test body hole (113); The pressure connection part 190 includes a connection body 192 installed to be movable up and down through the test body hole 113, a pressure connection driving part for moving the connection body 192 up and down, and the connection body 190. It is provided spaced apart on the upper surface of the connecting pipe 191, which is a pipe opened upward, and a connection pipe 193 connected to one of the connecting pipes 191 and the other end connected to the air supply means;
The connection body 192 is raised by the driving of the pressure connection driving part, and the ports 13 and 15 protruding downward through the port hole 145 are respectively inserted into the connection pipe 193, and the connection pipe 193 on one side. ) through which air supplied from the air supply means is supplied to pressurize the battery cooling mechanism (10). According to claim 2 or 3, further comprising a plate-shaped seating portion support 150 that is spaced upward from the test body 110, and the cooling mechanism seating portion 140 by the operation of the seating portion driver 160. Inspection of a battery cooling device, characterized in that it is located on the lower surface of the seat support part 150 when moving forward, and the upper part is supported by the lower surface of the seat part support part 150 when the battery cooling mechanism 10 is pressed from the lower part. device 100 . 5. The method of claim 4, wherein the seating support recess 155 is formed at a front end of the seating part support part 150, and the cooling mechanism seating part 140 is formed by the operation of the seating part driving part 160. When moving forward, the front end of the heat exchange part 11 of the battery cooling mechanism 10 that is seated on the cooling mechanism seating part 140 and advanced together is exposed through the seating support recess 155; The management code (B) transferred by the transfer attachment unit 130 is attached to the heat exchange unit 11 exposed through the seating support concave portion 155 . . The seating member (140-1) of claim 2, wherein the cooling mechanism seating part (140) is a plate-shaped metal seating member (140-1) having a guide block (103) installed at a lower portion of the cooling mechanism seating part (140) to enable forward and backward movement along the seating part guide (101). and a plate-shaped seating unit body (140-3) made of synthetic resin provided on the upper surface of the seating member (140-1);
The seating jaw 141 and the bottom surface 143, which is a surface spaced downward from the seating jaw part 141, is formed in the seating part body 140-3, and the port hole 145 is formed with the seating member 140-1 and Inspection apparatus 100 of the battery cooling device, characterized in that formed through the seat body (140-3). According to claim 1, wherein the transfer attachment portion 130 is provided on the test body 110, the transfer frame 131 extending from the upper portion of the code printing unit 171 past the upper portion of the test portion, and the transfer frame (131) ), a movable member 137 provided to be movable along the longitudinal direction, a code reader 133 provided in the movable member 137, and a movable member 137 provided to one side of the code reader 133 and a cord transfer attachment part 135 installed to be movable in the vertical direction by the attachment driving unit 135-1, and a code transfer drive part for moving the movable member 137 along the transfer frame 131;
A code attachment part 135-7 is provided at the lower end of the code transfer attachment part 135, and the code transfer attachment part 135 moved to the upper part of the code printing unit 171 along the transfer frame 131 is The management code (B) printed by the code printing unit 171 is attached to the code attaching unit 135-7 provided at the bottom while descending by the driving of the attachment driving unit 135-1 and separated from the paper P. ; The test apparatus 100 for a battery cooling device, characterized in that it moves to the upper part of the test part while ascending by the operation of the attachment driving part (135-1) and the cord transfer driving part.

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