KR102371376B1 - Constant temperature and humidity chamber for testing with precise local control - Google Patents

Abstract

The present invention relates to a constant temperature and humidity chamber for testing performance of a test subject. More specifically, the constant temperature and humidity chamber with precise local control for a test has a double structure and stores the test subject inside an inner chamber where a plurality of first maintenance units are arranged to perform a performance test to instantly perform local temperature control according to a temperature change of the test subject, thereby more accurately testing the performance of the test subject.

Description

Constant temperature and humidity chamber for testing with precise local control

The present invention relates to a constant temperature and humidity chamber for testing the performance of a test subject, and more particularly, a double chamber is configured, and the test subject is accommodated in an internal chamber in which a plurality of first holding parts are arranged. It relates to a constant temperature and humidity chamber for testing that allows for local precise control that allows for more accurate performance testing of a test object by immediately performing local temperature control according to the change in the temperature of the test object.

In recent years, as electronic parts and electronic devices become highly functional, their composition becomes more complex and product groups are exposed to various environments. and malfunctions are found depending on temperature and humidity.

In particular, since the performance of batteries used in electronic devices is affected by various factors, various performance tests of batteries are essential when developing electronic devices.

In general, the performance test of the battery is performed under constant temperature and humidity conditions, and as one of the technologies for such a constant temperature and humidity tester, Korean Patent Application Laid-Open No. 10-2018-0123865 (hereinafter referred to as the prior art) is disclosed.

The prior art relates to a constant temperature and humidity constant temperature and humidity constant temperature and humidity environment by having a gauze tube for controlling the humidity inside the chamber, and configuring a blower that circulates the internal air.

When the performance test of the battery is performed using this prior art, the test is generally conducted in a state where the battery is simply placed in the inner space of a wide chamber. There is a problem in that it is difficult to cool the set temperature in a short time, so it is difficult to maintain a constant temperature condition, and thus there is a problem in that the reliability of the battery performance test performed is lowered.

Laid-open Patent Publication No. 10-2018-0123865 2018.11.20.

The present invention was created to solve the problems of the prior art, and the problem to be solved in the present invention is to configure a chamber in a double, and to accommodate the test object in an inner chamber in which a plurality of first holding parts are arranged, so that the performance test is performed. It is to provide a constant temperature and humidity chamber for testing capable of local precise control that allows for more accurate performance testing of the test object by immediately performing local temperature control according to the change in the temperature of the test object.

The present invention provides a constant temperature and humidity chamber for testing the performance of a test subject, comprising: an outer chamber 100 having an empty interior; an inner chamber 200 provided inside the outer chamber 100 so as to accommodate a test subject therein; a first holding part 300 for controlling the internal temperature of the internal chamber 200 to maintain a constant state; a second holding unit 400 for controlling the internal temperature and humidity of the external chamber 100 to maintain a constant state; and a control unit for controlling the operations of the first holding unit 300 and the second holding unit 400 .

At this time, the inner chamber 200, the table 210 is made to seat the test object on the upper portion; and a housing portion 220 configured to cover and cover the upper portion of the table 210 in an open state with the inner and lower portions thereof being opened.

On the other hand, a plurality of through holes are formed in the housing portion 220 so that the inside of the outer chamber 100 and the inside of the inner chamber 200 are in communication with each other.

In addition, the first holding unit 300 includes a block (module) type case 310 provided on the table 210; a first temperature measuring unit 320 provided inside the case 310 to measure the temperature of the outer surrounding environment of the case 310; and a heat exchange member 330 provided in the case 310 and heat exchanged through the surface of the case 310 .

Meanwhile, the heat exchange member 330 is configured as a thermoelectric element or a cooling passage.

In addition, a plurality of the first temperature measurement unit 320 measures the temperature in real time and transmits it to the control unit, and the control unit changes the temperature value among the temperature values measured by the first temperature measurement unit 320 for a certain period of time or more The first holding unit 300 provided with the first temperature measuring unit 320 that is not installed determines that the test object is not provided on the upper part, and the first temperature measuring unit 320 having a changing temperature value is provided in the first holding unit 300 . The holding part 300 determines that the test object is provided on the upper part.

In addition, the control unit controls the first holding unit 300 , which determines that the test object is not provided on the upper part, to maintain a temperature corresponding to the set temperature of the internal chamber 200 , and determines that the test object is provided on the upper part. The determined first holding unit 300 is controlled to be cooled to a low temperature in proportion to the difference from the set temperature for each local location.

Meanwhile, the second holding unit 400 includes a second temperature measuring unit 410 configured to measure the temperature of the internal air of the external chamber 100 and transmitting the measured external temperature value to the control unit; a humidity measuring unit 420 configured to measure the humidity inside the outer chamber 100 and transmitting the measured humidity value to the control unit; an air inlet 430 for supplying air heated or cooled to a constant temperature, the humidity of which is adjusted to have a constant humidity, into the interior of the external chamber 100; and an air discharge unit 440 for discharging the internal air of the external chamber 100 to the outside.

On the other hand, the first holding part 300 includes a step 340 formed along the circumference, and a plurality of first holding parts 300 are arranged in the longitudinal and transverse directions between adjacent steps 340 . A fastening groove 341 into which the lower end of the housing unit 220 is inserted and fastened is formed.

At this time, the housing unit 220, one end is bent or bent upwardly inclined to the inner side of the housing unit 220, and the other end is bent or bent upward and the outer end of the housing unit 220 consists of a plate bent or bent, A plurality of fixing members 222 are provided while being spaced apart from each other by a predetermined distance along the circumference of the lower end of the housing unit 220 so as to include the fixing member 222 .

According to the present invention, as the chamber is configured as a double and the performance test is performed by accommodating the test object in the inner chamber in which the plurality of first holding parts are arranged, the local temperature control according to the change in the temperature of the test object is performed immediately, so that it is more accurately It has the advantage of being able to test the performance of the test object.

1 is a perspective view of a constant temperature and humidity chamber for testing capable of local precise control according to the present invention.
2 is a cross-sectional side view of a constant temperature and humidity chamber according to the present invention.
Figure 3 is a perspective view of the inner chamber applied to the present invention.
Figure 4 is an exploded perspective view of the inner chamber and the first holding part applied to the present invention.
Figure 5 is a cross-sectional view of an embodiment of the use of the outer chamber and the inner chamber applied to the present invention.
Figure 6a is a view showing an embodiment of the use of the fixing member applied to the present invention, a view showing a state before the fixing member is fastened.
Figure 6b is a view showing an embodiment of the use of the fixing member applied to the present invention, a view showing a state in which the fixing member is fastened.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

The present invention relates to a constant-temperature and constant-humidity chamber for testing the performance of a test object, and more particularly, by accommodating the test object in the inner chamber 200 in which the chamber is configured as a double and a plurality of first holding parts 300 are arranged. It relates to a constant temperature and humidity chamber for testing capable of local precise control that allows for more accurate performance testing of a test object by immediately performing local temperature control according to a change in the temperature of the test object as the performance test is performed.

1 and 2, the present invention includes an outer chamber 100, an inner chamber 200, a first holding unit 300, a second holding unit 400, and a control unit (not shown). is composed

The external chamber 100 is to provide an environment isolated from the external environment, and is configured in an empty state.

In other words, the outer chamber 100 is made in the form of an empty enclosure, and an openable outer door 110 is configured on one side, and the outside air is provided in the outer door 110 inside the outer chamber 100 . Packing to prevent inflow into the perimeter should be provided along the perimeter.

On the other hand, the outer door 110 may be made of a transparent material in order to be able to recognize the situation inside the outer chamber (100).

The inner chamber 200 is for forming an isolated examination environment in the outer chamber 100 , allows a test subject to be accommodated therein, and is provided inside the outer chamber 100 .

In other words, as shown in FIGS. 1 to 4 , the inner chamber 200 covers the upper portion of the table 210 so that the test object is seated thereon, and the inner and lower portions of the table 210 are open. and an enclosure portion 220 configured to cover.

That is, the inner chamber 200 is configured such that the housing unit 220 is detachable from the table 210 , and an enclosure unit 220 of an appropriate size is selected according to the size of the test object seated on the table 210 . to make it usable.

In addition, the housing unit 220 is provided with an inner door 221 that can be opened and closed on one side so that the test object can be accommodated inside or discharged to the outside while the housing unit 220 is installed.

On the other hand, the sidewalls and the upper surface constituting the housing unit 220 are composed of thermoelectric elements so that they can play an auxiliary role in regulating the internal temperature of the outer chamber 100 and the inner chamber 200 . It will be described in more detail.

In addition, a gate 230 that can be opened and closed manually or automatically is formed in the enclosure 220 so that the outer chamber 100 and the inner chamber 200 are in communication or isolated from each other depending on the type of test. make it possible

In this case, although the gate 230 is shown in a form that can be opened and closed by vertical rotation in the present invention, it is provided on one side of the housing unit 220 and can be opened and closed in any form automatically or manually.

As shown in FIG. 2 , the first holding part 300 is for controlling the internal temperature of the internal chamber 200 to maintain a constant state, and includes a case 310 and a first temperature measuring part 320 . and a heat exchange member 330 .

The case 310 is configured in a block (module) type to be provided on the table 210 . In this case, the case 310 is made of a material having high thermal conductivity.

The first temperature measuring unit 320 is provided inside the case 310 to measure the temperature of the outer surrounding environment of the case 310 .

In other words, the first temperature measuring unit 320 measures the surface temperature of the test object while in close contact with the surface of the test object when the test object is provided on the table 210, and the test object is not provided. is to measure the temperature of the ambient air of the first temperature measuring unit (320).

Meanwhile, the temperature value from the first temperature measurement unit 320 is transmitted to the control unit and stored.

The heat exchange member 330 is provided inside the case 310 and heat exchanges through the surface of the case 310 so that the internal temperature of the internal chamber 200 is constantly maintained.

In other words, the heat exchange member 330 may be composed of a thermoelectric element made of a Peltier element or the like or a cooling passage, which is cooled or heated to a predetermined temperature according to a control command transmitted from the control unit while being heated in the inner chamber 200 . to keep the temperature of the internal space of the

The first holding part 300 configured as described above is provided on the table 210 in a state in which a plurality of them are arranged to measure the temperature of the test object in contact with each position, and each temperature according to the temperature change of the measured position. The control is made, which will be described in more detail later.

Meanwhile, as shown in FIG. 2 , the second holding part 400 is for controlling the internal temperature and humidity of the external chamber 100 to maintain a constant state, and is provided on one side of the external chamber 100 . It is configured to adjust the internal temperature and humidity of the external chamber 100 in the provided state, for this purpose, a second temperature measuring unit 410, a humidity measuring unit 420, an air inlet 430 and an air outlet ( 440) is included.

The second temperature measuring unit 410 is configured to measure the temperature of the internal air of the external chamber 100, and is configured to transmit the measured external temperature value to the control unit.

The humidity measuring unit 420 is configured to measure the humidity inside the external chamber 100, and is configured to transmit the measured humidity value to the control unit.

The air inlet 430 is configured to supply air, which is heated or cooled to a constant temperature, and whose humidity is adjusted to have a constant humidity, into the interior of the external chamber 100 .

In other words, the air inlet 430 regulates and controls the air so that the temperature and humidity conform to the control command transmitted from the control unit, and then supplies the air to the inside of the external chamber 100 .

The air discharge unit 440 discharges the internal air of the external chamber 100 to the outside, so that the internal air of the external chamber 100 can be circulated.

According to the above configuration, the second holding unit 400 allows the temperature and humidity inside the external chamber 100 to be maintained at a constant state while the experiment of the subject is performed.

Meanwhile, the control unit is configured to control the operations of the first holding unit 300 and the second holding unit 400 .

In other words, the control unit receives the temperature information inside the inner chamber 200 from the first holding unit 300 , and transmits the temperature and humidity information inside the outer chamber 100 from the second holding unit 400 . and compares the received temperature information and humidity information with a set temperature, and the first holding unit 300 and the second By controlling the operation of the holding unit 400, it is possible to maintain a constant temperature and constant humidity state.

As described above, in the present invention, the inner chamber 200 is configured in a partitioned state inside the outer chamber 100, and the test subject is tested in a state in which the subject is accommodated in the inner chamber 200. It enables to increase the reliability of the experiment by responding more quickly to the temperature change according to the experiment.

Hereinafter, the constant temperature and humidity process during the performance test of the battery will be limited to the case where the test subject is a battery.

After accommodating the battery (test subject) in the inner chamber 200, the inner chamber 200 and the outer chamber 100 have the same temperature and humidity, and then perform a performance test of the test subject. As a result, the surface temperature of the battery increases over time.

At this time, the plurality of first temperature measuring units 320 measure the internal temperature of the internal chamber 200 in real time and transmit it to the control unit, and by analyzing the received temperature value, the control unit is provided on the upper part of the test object A first holding unit with and without a first holding unit is distinguished.

In detail with reference to FIG. 5 , the control unit includes the first holding units 300a and 300b at positions P1 and P2 in which the temperature values measured by the first temperature measuring unit 320 are not changed. It is determined that the battery is not provided on the upper part of the , and it is determined that the test object is provided on the upper part of the first holding part 300c at the position P3 where the temperature value is changed.

Thereafter, the control unit compares the measured temperature value with the set temperature to cool the first holding unit 300 to an appropriate temperature according to the temperature difference, thereby cooling the battery.

In detail, the first holding parts 300a and 300b provided at the positions P1 and P2 are controlled to maintain a temperature corresponding to the set temperature of the inner chamber 200, and the first holding parts 300a and 300b provided at the positions of P3 are controlled to be maintained. By controlling the portion 300c to be cooled to a low temperature in proportion to the difference from the set temperature for each local location, the temperature of the inner chamber 200 can be maintained constant.

At this time, when the heat exchange member 330 is composed of a thermoelectric element, the first holding part 300 cools the heat exchange member 330 to a temperature suitable for the control command by varying the current output amount of the thermoelectric element, and the heat exchange member 330 is cooled. When configured as a flow path, the refrigerant supplied to the cooling flow path is cooled to a temperature suitable for a control command, thereby absorbing the heat of the test object.

That is, in the present invention, the plurality of first holding parts 300 are cooled to different temperatures for each location, and the test object is cooled, so that the cooling of the test object can be performed within a faster time.

On the other hand, when the temperature value measured by the first holding part 300 close to the position where the test object is provided increases gradually due to the strong exothermic reaction of the test object, the first holding part 300 is also proportional to the increase value. By controlling the cooling to a cooler temperature, the test object can be cooled within a short time.

In addition, in the control unit, the thermoelectric element constituting the housing unit 220 of the inner chamber according to the change in the temperature measured by the first holding unit 300b located at P2 is the current output amount of the set temperature of the inner chamber 200 . By adjusting the internal chamber 200, it is possible to more quickly control the temperature of the internal air to a constant state.

As described above, the inside of the inner chamber 200 is cooled locally while responding to the temperature change of the test object in real time, thereby maintaining a constant temperature state.

In particular, as the performance test of the test object is performed in a small area partitioned by the inner chamber 200, the first holding part 300 responds more immediately to the temperature change of the test object to increase the reliability of the test object performance test. let there be

On the other hand, in the present invention, in order to reduce unnecessary power consumption, the first holding parts 300b and 300c provided inside the inner chamber 200 and the first holding parts 300a provided outside can be controlled separately. .

In detail, a position sensing sensor 500 is provided inside the upper portion of the outer chamber 100, and the position sensing sensor 500 measures the position at which the housing unit 320 is provided and transmits it to the control unit. .

The control unit analyzes the received measurement value to derive the position where the housing unit 320 is provided, and the first holding units 300b and 300c provided in the inner chamber 200 and the first holding units 300b and 300c provided outside the inner chamber 200 After dividing the holding part 300a, only the first holding parts 300b and 300c provided in the inner chamber 200 are operated so that the internal temperature of the internal chamber 200 can be constantly maintained.

On the other hand, since a plurality of gates 230 are formed in the inner chamber 200, when the experiment is conducted by opening the gate 230, the inner chamber 200 and the outer chamber 100 are in communication. In this state, the internal environment of the external chamber 100 can be controlled by manipulating the first holding part 300 and the second holding part 400 .

In other words, the second holding part 400 is controlled so that the internal temperature and humidity of the external chamber 100 correspond to the preset temperature and preset humidity of the internal chamber 200 , and according to the battery performance test, the external chamber (100) When the internal temperature and humidity rise, the second holding unit 400 cools to a set temperature, and supplies air controlled to have a set humidity value to the external chamber 100 and at the same time as the external chamber (100) to inhale the air to process it.

At this time, a plurality of through holes are formed on one side of the outer chamber 100, and the second holding part 400 is uniformly supplied to the inside of the outer chamber 100 as the controlled air is supplied through the through holes. It makes it possible to create a constant temperature and constant humidity environment within a short time.

That is, according to the operation of the second holding part 400 , the internal environment of the external chamber 100 can be constantly maintained, and thus, the internal humidity of the internal chamber 200 can also be constantly maintained. .

At this time, when it is difficult to maintain the temperature within a short time with only the second holding part 400 , the first holding part 300a is controlled to contribute to the composition of the internal environment of the external chamber 100 .

On the other hand, when the battery performance test is performed with the gate 230 of the inner chamber 200 sealed, that is, when humidity control in the inner chamber 200 is not required, the enclosure 220 is While the internal temperature of the chamber 200 is controlled to maintain a set temperature, the temperature of the internal chamber 200 is appropriately adjusted.

At this time, as the temperature and humidity inside the outer chamber 100 are changed according to the operation of the housing unit 220 , the second holding unit 400 is operated in response to the change in the inner side of the outer chamber 100 . to maintain constant temperature and humidity conditions.

On the other hand, in the present invention, it is configured in the form of a double chamber in order to allow the cooling of the test object in a short time.

Therefore, in the present invention, it is possible to form the inner chamber 200 by using the housing portion 220 of an appropriate size according to the size of the test object. In order to make this easier, the first holding part 300 includes a step 340 formed along the perimeter, and a plurality of first holding parts 300 are arranged in the longitudinal and transverse directions and adjacent step 340 . ), a fastening groove 341 into which the lower end of the housing unit 220 is inserted and fastened is formed.

That is, the fastening groove 341 is formed in a lattice shape by the plurality of first holding parts 300, and accordingly, the present invention selects and assembles the housing part 220 of an appropriate size corresponding to the size of the test object. It allows the size of the inner chamber 200 to be adjusted.

On the other hand, as shown in Figures 6a and 6b, the housing portion 220 is configured to further include a fixing member 222 to maintain the state firmly fixed to the fastening groove (341).

The fixing member 222 is formed of a plate having one end bent or bent upwardly inclined to the inner side of the housing unit 220 and the other end of the housing unit 220 is bent or bent upwardly from the outer side of the housing unit 220 , and the housing unit A plurality of pieces are provided while being spaced apart by a predetermined distance along the circumference of the lower end of the 220 .

When the lower end of the housing unit 220 is inserted into the fastening groove 341 according to the above configuration, both ends of the fixing member 222 are gradually bent toward the side wall of the housing unit 220. As a result of the corresponding reaction, the fixing member 222 pushes the inner surface of the fastening groove 341 , and the housing part 220 can maintain a state firmly fixed to the upper end of the first holding part 300 .

Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and it should be understood that the scope of the present invention extends to those substantially equivalent to the embodiments of the present invention, Various modifications can be made by those of ordinary skill in the art to which the invention pertains without departing from the spirit of the invention.

B : test subject
100: external chamber 110: external door
200: inner chamber 210: table
220: enclosure 221: inner door
222: fixing member
230: gate
300: first holding part 310: case
320: first temperature measuring unit 330: heat exchange member
340: step 341: fastening groove
400: second holding unit 410: second temperature measuring unit
420: humidity measuring unit 430: air inlet
440: air outlet
500: position sensor

Claims (10)

In the constant temperature and humidity chamber for testing the performance of the test subject,
The outer chamber 100 is configured in an empty state;
an inner chamber 200 provided inside the outer chamber 100 so as to accommodate a test subject therein;
a first holding part 300 for controlling the internal temperature of the internal chamber 200 to maintain a constant state;
a second holding unit 400 for controlling the internal temperature and humidity of the external chamber 100 to maintain a constant state; and
a control unit for controlling operations of the first holding unit 300 and the second holding unit 400;
includes,
The inner chamber 200,
Table 210 made to be placed on the test object; and
a housing unit 220 configured to cover and cover the upper portion of the table 210 in an open state;
includes,
The first holding part 300,
a case 310 configured in a block (module) type and provided on the table 210;
a first temperature measuring unit 320 provided inside the case 310 to measure the temperature of the outer surrounding environment of the case 310; and
a heat exchange member 330 provided in the case 310 and performing heat exchange through the surface of the case 310;
A constant temperature and humidity chamber for testing capable of local precise control, characterized in that it comprises a.
delete The method according to claim 1,
In the housing unit 220,
A constant temperature and humidity chamber for testing capable of local precise control, characterized in that a plurality of through holes are formed so that the inside of the outer chamber 100 and the inside of the inner chamber 200 communicate with each other.
delete The method according to claim 1,
The heat exchange member 330,
A constant temperature and humidity chamber for testing capable of local precise control, characterized in that it consists of a thermoelectric element or a cooling passage.
The method according to claim 1,
A plurality of the first temperature measurement unit 320 measures the temperature in real time and transmits it to the control unit,
The control unit includes the first holding unit 300 provided with the first temperature measuring unit 320 in which the temperature value of the temperature value measured by the first temperature measuring unit 320 does not change for a certain period of time or more, the test object is provided on the upper part It is determined that the temperature value is not changed, and the first holding unit 300 provided with the first temperature measuring unit 320 in which the temperature value changes is a constant temperature for testing capable of local precise control, characterized in that it is determined that the test object is provided on the upper part. humidity chamber.
7. The method of claim 6,
The control unit is
The first holding part 300 determined that the test object is not provided on the upper part is controlled to maintain a temperature corresponding to the set temperature of the inner chamber 200, and the first holding part 300 determined that the test object is provided on the upper part ( 300) is a constant temperature and humidity chamber for testing capable of local precise control, characterized in that it is controlled to be cooled to a low temperature in proportion to the difference from the set temperature for each local location.
The method according to claim 1,
The second holding part 400,
a second temperature measuring unit 410 configured to measure the temperature of the internal air of the external chamber 100 and transmitting the measured external temperature value to the control unit;
a humidity measuring unit 420 configured to measure the humidity inside the outer chamber 100 and transmitting the measured humidity value to the control unit;
an air inlet 430 for supplying air heated or cooled to a constant temperature, the humidity of which is adjusted to have a constant humidity, into the interior of the external chamber 100; and
an air discharge unit 440 for discharging the internal air of the external chamber 100 to the outside;
A constant temperature and humidity chamber for testing capable of local precise control, characterized in that it comprises a.
The method according to claim 1,
The first holding part 300,
It includes a step 340 formed along the circumference,
A plurality of first holding parts 300 are arranged in the longitudinal and transverse directions, and between the adjacent step 340, a fastening groove 341 into which the lower end of the housing part 220 is inserted and fastened is formed. A constant temperature and humidity chamber for testing with local precision control.
10. The method of claim 9,
The enclosure part 220,
One end of the housing unit 220 is bent or bent upward, and the other end of the housing unit 220 is bent or bent upward and the outer end of the housing unit 220 is bent or bent. Around the lower end of the housing unit 220 . A constant temperature and humidity chamber for testing capable of local precise control, characterized in that it includes a plurality of fixing members 222 that are provided while being spaced apart by a predetermined distance along the .

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