KR20200113759A - Constant temperature-humidity device - Google Patents

Abstract

Disclosed is a constant temperature and humidity apparatus. The constant temperature and humidity apparatus comprises: a main body including a chamber in which a test target is accommodated and an opening for opening the chamber; a door having a first vertical side rotationally connected to the main body, and opening and closing the main body to open and close the opening; a plurality of first locking devices installed on the front surface of the main body so as to be adjacent to a second vertical side of the door parallel to the first vertical side, and including first locking rods provided to be moved forward and backward; a ring-shaped rod holder installed on the front surface of the door so as to be disposed on the same line with the plurality of first locking rods at a position adjacent to the second vertical side, and inserting and fixing the advancing first locking rods; and a rod driving device for driving the plurality of first locking devices.

Description

Constant temperature and humidity device {CONSTANT TEMPERATURE-HUMIDITY DEVICE}

The present invention relates to a constant temperature and humidity device, and to a constant temperature and humidity device capable of preventing an accident due to an explosion when testing an explosive test object such as a battery.

The constant temperature and humidity device is a device that provides an environment of a specific temperature and humidity in a chamber in which the test object is placed.

For example, a thermo-hygrostat is a chamber in which an experiment object is accommodated, a heating heater for temperature control inside the chamber, a humidifier for adjusting the humidity inside the chamber, a blower for circulation of air inside the chamber, and water by being disposed in the thermo-hygrostat. It may include a humidification heater to heat.

The test object is located inside the chamber of the thermo-hygrostat, and for example, a plurality of batteries may be housed and tested to test the performance of the battery. In this case, if the temperature inside the chamber rises and the temperature of the battery contained in the chamber rises, there is a risk of explosion of the battery, and if the battery explode inside the chamber, the door of the thermo-hygrostat is damaged, smoke leaks out, etc. There was a problem.

Therefore, the problem to be solved by the present invention is that even if an explosion occurs in the chamber and the door is impacted, the door is maintained in a closed state to prevent accidents due to explosion during the testing process of the battery, etc. It is to provide a humidity control device.

A thermo-hygrostat according to an embodiment of the present invention includes a body including a chamber in which a test object is accommodated and an opening for opening the chamber; A door having a first vertical side rotatably connected to the main body and opening and closing the main body to open and close the opening; A plurality of first locking devices including a first locking rod installed on the front surface of the main body so as to be adjacent to a second vertical side of the door parallel to the first vertical side, and provided to be moved forward and backward; A ring-shaped rod holder installed on the front surface of the door so as to be disposed on the same line with the plurality of first locking rods at a position adjacent to the second vertical side, and inserting and fixing the advancing first locking rods; And a rod driving device for driving the plurality of first locking devices.

In one embodiment, each of the first locking device, a first cylinder portion acting on the inside of the hydraulic pressure or pneumatic; And a first locking rod coupled to the first cylinder unit and operating forward and backward by an action of the hydraulic pressure or pneumatic pressure, wherein the rod driving device turns on hydraulic pressure or pneumatic pressure to the first cylinder unit. ) A first fluid supply unit for supplying in an operation or recovering in an OFF operation; It is interposed at the interface between the inner surface of the door and the outer surface of the main body to detect the closed state of the door, and is electrically connected to the first fluid supply unit, and the first fluid supply unit is driven when the door is closed. A door motion detection sensor for transmitting an operation signal to the first fluid supply unit; And a first lock release button for turning off the first fluid supply unit so that the plurality of first locking devices are released.

In the thermo-hygrostat according to another embodiment of the present invention, a plurality of gap sealing bars provided on the inner surface of the main body are positioned adjacent to all four sides of the opening in the chamber, and are disposed parallel to each side of the opening. ; A second locking device provided to advance and reverse by hydraulic pressure or pneumatic pressure acting in the second cylinder part and the second cylinder part, and the end part penetrates each gap sealing bar in the opening direction and is coupled to the gap sealing bar. A plurality of second locking devices including a rod; And a rod insertion hole provided on the inner surface of the door so as to face the second locking device when the door is closed, and inserting and fixing the second locking rod facing the second locking rod and moving forward. Locking block; A temperature measurement sensor that measures the temperature of the battery accommodated in the chamber; A second fluid supply unit for supplying hydraulic pressure or pneumatic pressure to the second cylinder unit in an ON operation or recovering it in an OFF operation; When the temperature of the threshold value for driving the second locking device is input in advance, and the temperature input from the temperature measuring sensor corresponds to the threshold value, the fluid supply device supplies hydraulic pressure or pneumatic pressure to the second cylinder unit. A second locking device control unit that controls the second locking device to be operated; And a second lock release button for turning off the second fluid supply unit so that the plurality of second locking devices are released, wherein the second locking rod is in contact with the locking block when the gap sealing bar is in contact with the locking block. The gap sealing bar may be moved to seal a boundary where the edge of the closed door and the edge of the opening are in contact, and the gap sealing bar may be moved to be spaced apart from the locking block and the boundary when moving backward.

In an embodiment, the second locking device includes: a bisong plate provided on the second locking rod and pushing the gap sealing bar in the direction of the opening when the second locking rod advances; And an annular groove formed along the circumferential direction of the second locking rod on the second locking rod and positioned between the gap sealing bar and the boundary in a normal state, wherein the gap sealing bar comprises the second locking rod A rod through hole through which it passes; And a latch disposed in the rod through hole at an end side adjacent to the locking block, and provided inside the rod through hole so as to rotate in the direction of the opening and not in a direction opposite to the opening, the When the second locking rod advances in the locking block direction, the locking clasp freely rotates in the opening direction, and when the second locking rod moves backward in a direction away from the locking block, the annular groove corresponds to the locking member. An end portion of the stopper may be inserted into the annular groove so that the gap sealing bar moves backward together with the second locking rod.

According to the thermo-hygrostat according to the present invention, as soon as the door is closed, the first locking device is operated to lock the door, and an explosion of the battery or the like occurs due to an increase in temperature in the chamber in which the test object is accommodated, and an impact is applied to the door Even if the door is kept closed, there is an advantage of preventing accidents due to explosion or the like during testing of batteries.

1 is a view for explaining a constant temperature and humidity device according to an embodiment of the present invention.
2 is a view showing the appearance of a thermo-hygrostat according to another embodiment of the present invention.
3 is a view showing a part of the interior of the thermo-hygrostat for explaining the thermo-hygrostat according to another embodiment of the present invention.

Hereinafter, a thermo-hygrostat according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present invention, various modifications may be made and various forms may be applied, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In describing each drawing, similar reference numerals have been used for similar elements. In the accompanying drawings, the dimensions of the structures are shown to be enlarged compared to the actual size for clarity of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are used only for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element.

The terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of being added.

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

1 is a view for explaining a constant temperature and humidity device according to an embodiment of the present invention.

Referring to FIG. 1, the thermo-hygrostat according to an embodiment of the present invention includes a main body 110, a door 120, a plurality of first locking devices 130, a plurality of rod holders 140, and a rod driving device ( 150).

The main body 110 may have a rectangular parallelepiped shape, and includes a chamber 111 in which the test object is accommodated and an opening 112 for opening the chamber 111. The opening 112 may have a square shape. The test object accommodated in the chamber 111 may be a battery, and a plurality of batteries may be connected in series and received.

The door 120 opens and closes the opening 112 of the main body 110. The door 120 may have a square shape, and a first vertical side is rotatably connected to the main body 110.

The plurality of first locking devices 130 fix the door 120 in a closed state so that it is not easily opened. The plurality of first locking devices 130 are installed on the front surface of the main body 110 so as to be adjacent to the second vertical side of the door 120 parallel to the first vertical side of the door 120. The plurality of first locking devices 130 may be two.

For example, each of the first locking devices 130 may include a first cylinder part 131 and a first locking rod 132. The first cylinder part 131 has a cylinder shape and one side of the cylinder is opened so that the first locking rod 132 can advance and retreat, and hydraulic or pneumatic pressure acts therein. The first locking rod 132 is coupled to the first cylinder part 131 and is provided to move forward and backward by the action of hydraulic pressure or pneumatic pressure.

A plurality of rod holders 140 are installed on the front side of the door 120 so as to be disposed in line with the plurality of first locking rods 132 at a position adjacent to the second vertical side of the door 120, The first locking rod 132 is inserted and fixed. The plurality of rod holders 140 may be provided in a ring shape having a diameter into which the first locking rod 132 can be inserted.

The rod driving device 150 drives the plurality of first locking devices 130. As an example, the rod driving device 150 may include a first fluid supply unit 151, a door motion detection sensor 152, and a first lock release button 153.

The first fluid supply unit 151 may be configured to supply hydraulic pressure or pneumatic pressure to the first cylinder unit 131 in an ON operation or recover it in an OFF operation. As an example, the first fluid supply unit 151 may be in the form of supplying pneumatic pressure, and may be provided on an outer side of the body 110.

The door motion detection sensor 152 is interposed at the interface between the inner surface of the door and the outer surface of the main body 110 to detect the closed state of the door 120. For example, the door motion detection sensor 152 may be an electrically configured pressure detection sensor. The door motion detection sensor 152 is electrically connected to the first fluid supply unit 151 and transmits an operation signal to the first fluid supply unit 151 so that the first fluid supply unit 151 is driven when the door 120 is closed. do.

The first lock release button 153 turns off the first fluid supply unit 151 so that the plurality of first locking devices 130 are released. The first lock release button 153 may be provided on the front surface of the main body 110.

Hereinafter, a process of driving the first locking device 130 when the door 120 is closed in the constant temperature and humidity chamber according to an embodiment of the present invention will be described.

When the door 120 is closed, the door motion detection sensor 152 detects the closed state of the door 120 by the pressure of the door 120, and at this time, the door motion detection sensor 152 is the first fluid supply unit 151 It transmits an operation signal.

When an operation signal is input from the door motion detection sensor 152 to the first fluid supply unit 151, the first fluid supply unit 151 starts to operate, so that the pressure is applied to the first cylinder unit 131 of the first locking device 130. Supply.

When pneumatic pressure is supplied to the first cylinder portion 131 of the first locking device 130, the first locking rod 132 advances in the direction of the rod holder 140, and at this time, the first locking device 130 ) And the edge of the opening 112 of the main body 110, the end of the first locking device 130 is inserted into the inner side of the rod holder 140 and fixed. Accordingly, the door 120 is fixed in a closed state by the first locking device 130, and the door 120 is not opened even when the door 120 is forcibly pulled.

In this way, even if an impact is applied to the door 120 from the inside of the chamber 111 while the door 120 is locked by the first locking device 130, the door 120 is not opened. For example, even if an accident occurs in which the battery housed in the chamber 111 is overheated due to an increase in the temperature inside the chamber 111, the door 120 is firmly fixed and closed by the first locking device 130. Since the state is maintained, the door 120 may not be opened due to an explosion impact.

When the constant temperature and humidity device according to the embodiment of the present invention is used, the first locking device 130 is operated as soon as the door 120 is closed, the door 120 is locked, and the chamber 111 in which the test object is accommodated. Even if an explosion occurs due to an increase in the temperature of the battery, etc., the door 120 remains closed even if an impact is applied to the door 120, so there is an advantage of preventing an accident due to an explosion or the like during the test process of the battery. have.

FIG. 2 is a view showing the appearance of a thermo-hygrostat according to another embodiment of the present invention, and FIG. 3 is a view showing a part of the interior of the thermo-hygrostat for explaining the thermo-hygrostat according to another embodiment of the present invention. 4 is a view showing a state in which the second locking device and the gap sealing bar shown in FIG. 3 are moved.

2 and 3, the thermo-hygrostat according to another embodiment of the present invention includes a gap sealing bar 210, a second locking device 220, a locking block 230, a temperature measuring sensor 240, and 2 A fluid supply unit 250, a second locking device control unit 260, and a second lock release button 270 may be further included.

A plurality of gap sealing bars 210 are provided on the inner surface of the main body 110 so as to be positioned adjacent to all four sides of the opening 112 in the chamber 111 and to be disposed parallel to each side of the opening 112, respectively. The plurality of gap sealing bars 210 may be the number corresponding to the four sides of the opening 112, that is, four. The gap sealing bar 210 has a square cross section and may have a length less than or equal to the length of four sides of the opening 112. For example, the gap sealing bar 210 adjacent to the upper and lower two parallel sides of the opening 112 may have a length corresponding to the upper and lower two sides of the opening 112, and the remaining two gaps The sealing bar 210 may have a length as short as the thickness of the other two vertically arranged gap sealing bars 210. Accordingly, the four gap sealing bars 210 are disposed in a square shape when they come into contact with each other, so that they can accurately correspond to the four sides of the opening 112.

The plurality of second locking devices 220 includes a second cylinder portion 221 and a second locking rod 222. The second cylinder portion 221 has a cylinder shape and one side of the cylinder is opened so that the first locking rod 132 can advance and retreat, and hydraulic or pneumatic pressure acts therein. The second locking rod 222 is coupled to the second cylinder portion 221 and is provided to move forward and backward by the action of hydraulic pressure or pneumatic pressure. The second locking rod 222 has a distal end passing through each of the gap sealing bars 210 in the direction of the opening 112 and is coupled to each gap sealing bar 210. The plurality of second locking devices 220 may be connected to each of the gap sealing bars 210 by two.

On the other hand, the plurality of second locking devices 220, when the second locking rod 222 advances, the gap sealing bar 210 is in contact with the locking block 230 and the edge of the door 120 closed at the opening 112 and The gap sealing bar 210 is moved to seal the boundary (hereinafter referred to as the door sealing boundary) where the edge of the opening 112 is in contact, and the gap sealing bar 210 is locked when the second locking rod 222 moves backward. It is moved to be spaced apart from the block 230 and the boundary.

To this end, each of the second locking device 220 further includes a bar transfer plate 223 and an annular groove 224, and the gap sealing bar 210 has a rod through hole 211 and a catch 212 Can include.

The bar transfer plate 223 is provided on the second locking rod 222 and pushes the gap sealing bar 210 in the direction of the opening 112 when the second locking rod 222 advances. The bar transfer plate 223 is disposed so as to be spaced apart from the gap sealing bar 210 before the second locking rod 222 is advanced, that is, normally. As an example, the plate for bar transfer 223 may be provided on the second locking rod 222 in an annular ring shape.

The annular groove 224 is formed along the circumferential direction of the second locking rod 222 on the second locking rod 222, and is normally fastened with the latch 212.

The rod through hole 211 is a hole through which the second locking rod 222 passes.

The catch 212 is disposed at an end side adjacent to the locking block 230 in the rod through hole 211. The catch 212 is rotatably connected to the locking block 230, and freely rotates in the direction of the opening 112 when the second locking rod 222 advances in the direction of the locking block 230, and the second locking rod ( When 222 moves backward in the direction away from the locking block 230, the end of the locking member 212 is inserted into the annular groove 224 at the time when the annular groove 224 corresponds to the locking member 212 and the second locking rod ( Together with 222), the gap sealing bar 210 moves backward. Although not shown, a torsion spring for pressing the catch 212 in the direction of the rod through hole 211 at all times may be provided on a rotation shaft connecting the catch 212 to the gap sealing bar 210 so as to be rotatable.

The locking block 230 is provided on the inner surface of the door 120 to face the second locking device 220 when the door 120 is closed. The locking block 230 faces the second locking rod 222 and allows the second locking rod 222 to advance to be inserted and fixed. For example, the locking block 230 may be a block having a rectangular parallelepiped shape, and an insertion hole 231 for inserting the second locking rod 222 may be formed on a surface opposite to the second locking rod 222. .

The temperature measurement sensor 240 measures the temperature of the battery accommodated in the chamber 111. For example, the temperature measuring sensor 240 may be installed outside the main body 110 and a sensing unit may be inserted into the chamber 111. Connection to the battery may be connected through a metal terminal capable of heat conduction.

The second fluid supply unit 250 is configured to supply hydraulic pressure or pneumatic pressure to the second cylinder unit 221 of the second locking device 220 in an ON operation or recover by an OFF operation. As an example, the second fluid supply unit 250 may be in the form of supplying pneumatic pressure, and may be provided on an outer side of the body 110.

When the temperature of the threshold value for driving the second locking device 220 is input in advance and the temperature input from the temperature measuring sensor 240 corresponds to the threshold value, the second locking device control unit 260 The fluid supply unit 250 supplies hydraulic pressure or pneumatic pressure to the second cylinder unit 221 to control the second locking device 220 to be operated. For example, the second locking device control unit 260 may be disposed on an outer side of the main body 110 and may be electrically connected to the temperature measuring sensor 240.

The second unlocking button 270 turns off the second fluid supply unit 250 so that the plurality of second locking devices 220 are released. For example, the second lock release button 270 may be provided on the front surface of the main body 110.

Hereinafter, a driving process of the second locking device 220 according to an increase in temperature of a battery accommodated in the chamber 111 in the thermo-hygrostat according to another embodiment of the present invention will be described.

The temperature measurement sensor 240 measures the temperature of any one of a plurality of batteries accommodated in the chamber 111 of the main body 110 and inputs the measured temperature to the second locking device controller 260 in real time.

The second locking device control unit 260 continuously determines whether the temperature value input from the temperature measurement sensor 240 corresponds to a preset threshold value, and when the input temperature value corresponds to the threshold value, the second locking device is locked. The device 220 is driven.

When the second locking device 220 is driven by the second locking device control unit 260, the second fluid supply unit 250 supplies hydraulic pressure or pneumatic pressure to the second cylinder unit 221, and the second cylinder unit 221 ) The second locking rod 222 is advanced by hydraulic pressure or pneumatic pressure acting inside.

When the second locking rod 222 advances to some extent, the bar transfer plate 223 provided on the second locking rod 222 corresponds to the gap sealing bar 210, and the second locking rod 222 continues. When moving forward, the bar transfer plate 223 pushes the gap sealing bar 210 in the direction of the opening 112 so that the gap sealing bar 210 moves in the direction of the opening 112 together with the second locking rod 222. . At this time, the gap sealing bar 210 moves until it corresponds to the locking block 230 to block the door sealing boundary as shown in FIG. 4, and immediately before the gap sealing bar 210 corresponds to the locking block 230, 2 The distal end of the locking rod 222 enters the insertion hole 231 of the locking block 230 and is further inserted into the insertion hole 231 at the time when the gap sealing bar 210 corresponds to the locking block 230 And stops. Therefore, by the second locking rod 222 advancing, the gap sealing bar 210 blocks the door sealing boundary, and the distal end of the second locking rod 222 is coupled to the locking block 230 so that the door 120 The closed state of is fixed.

The moving distance of the gap sealing bar 210 according to the advance of the second locking rod 222 and the length at which the second locking rod 222 is inserted into the locking block 230 are preset.

Meanwhile, the locked state of the second locking device 220 is released through the second unlocking button 270. That is, when the second lock release button 270 is pressed, the second fluid supply unit 250 is turned off to recover hydraulic pressure or pneumatic pressure supplied to the second cylinder unit 221, whereby the second locking rod 222 is 2 It returns to the inside of the cylinder part 221.

At this time, the second locking rod 222 moves backward and is withdrawn from the insertion hole 231 of the locking block 230, and an annular groove 224 formed on the second locking rod 222 that moves backward is formed in the gap sealing bar 210 ) At a time corresponding to the latch 212 provided in the latch 212 is inserted into the annular groove 224, and accordingly, the gap sealing bar 210 moves backward together with the second locking rod 222 to the initial position Can be returned to

The thermo-hygrostat according to another embodiment of the present invention can promptly cope with the increase in the temperature of the battery accommodated in the chamber 111 so that the door 120 can be kept in a more tightly sealed state. (111) In case the battery explodes due to the continuous temperature increase of the battery inside, the door sealing boundary is completely sealed by the gap sealing bar 210 and the door 120 is more tightly sealed by the second locking device 220 Since it is fixed, it is possible to prevent the explosion of the battery, flame, and smoke from leaking out of the chamber 111, and opening of the door 120 due to damage of the door 120 may be completely prevented. Accordingly, it is possible to prevent a safety accident due to an explosion during a battery test.

The description of the presented embodiments is provided to enable any person skilled in the art to use or implement the present invention. Various modifications to these embodiments will be apparent to those of ordinary skill in the art, and the general principles defined herein can be applied to other embodiments without departing from the scope of the present invention. Thus, the present invention is not to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

Claims (4)

A main body including a chamber in which the test object is accommodated and an opening for opening the chamber;
A door having a first vertical side rotatably connected to the main body and opening and closing the main body to open and close the opening;
A plurality of first locking devices including a first locking rod installed on the front surface of the main body so as to be adjacent to a second vertical side of the door parallel to the first vertical side, and provided to be moved forward and backward;
A ring-shaped rod holder installed on the front surface of the door so as to be disposed on the same line with the plurality of first locking rods at a position adjacent to the second vertical side, and inserting and fixing the advancing first locking rod; And
It characterized in that it comprises a rod driving device for driving the plurality of first locking devices,
Constant temperature and humidity device. The method of claim 1,
Each of the first locking devices,
A first cylinder part with hydraulic or pneumatic action therein; And
And a first locking rod coupled to the first cylinder portion and operating forward and backward by the action of the hydraulic pressure or pneumatic pressure,
The rod driving device,
A first fluid supply unit for supplying hydraulic pressure or pneumatic pressure to the first cylinder unit in an ON operation or recovering it in an OFF operation;
It is interposed at the interface between the inner surface of the door and the outer surface of the main body to detect the closed state of the door, and is electrically connected to the first fluid supply unit, and the first fluid supply unit is driven when the door is closed. A door motion detection sensor for transmitting an operation signal to the first fluid supply unit; And
It characterized in that it comprises a first lock release button for turning off the first fluid supply unit so that the plurality of first locking devices are released,
Constant temperature and humidity device. The method of claim 2,
A plurality of gap sealing bars disposed on the inner surface of the main body so as to be positioned adjacent to all four sides of the opening in the chamber and disposed parallel to each side of the opening;
A second locking device provided to advance and reverse by hydraulic pressure or pneumatic pressure acting in the second cylinder part and the second cylinder part, and the end part penetrates each gap sealing bar in the opening direction and is coupled to the gap sealing bar. A plurality of second locking devices including a rod;
And a rod insertion hole provided on the inner surface of the door so as to face the second locking device when the door is closed, and inserting and fixing the second locking rod facing the second locking rod and moving forward. Locking block;
A temperature measurement sensor that measures the temperature of the battery accommodated in the chamber;
A second fluid supply unit for supplying hydraulic pressure or pneumatic pressure to the second cylinder unit in an ON operation or recovering it in an OFF operation;
When the temperature of the threshold value for driving the second locking device is input in advance, and the temperature input from the temperature measuring sensor corresponds to the threshold value, the fluid supply device supplies hydraulic pressure or pneumatic pressure to the second cylinder unit. A second locking device control unit that controls the second locking device to be operated; And
Further comprising a second lock release button for turning off the second fluid supply unit so that the plurality of second locking devices are released,
When the second locking rod moves forward, the gap sealing bar is in contact with the locking block, and the gap sealing bar is moved so that the edge of the door closed to the opening and the boundary where the edge of the opening are in contact with each other, and the gap sealing bar is Characterized in that moving so as to be spaced apart from the locking block and the boundary,
Constant temperature and humidity device. The method of claim 3,
The second locking device,
A bisong plate provided on the second locking rod and pushing the gap sealing bar in the opening direction when the second locking rod advances; And
It is formed on the second locking rod along the circumferential direction of the second locking rod, and further comprises an annular groove positioned between the gap sealing bar and the boundary in normal times,
The gap sealing bar,
A rod through hole through which the second locking rod passes; And
It is disposed at an end side of the rod through hole adjacent to the locking block, and includes a catch provided inside the rod through hole so as to rotate in the direction of the opening and not to rotate in a direction opposite to the opening,
The catch is freely rotated in the opening direction when the second locking rod advances in the direction of the locking block, and the annular groove corresponds to the stopper when the second locking rod moves backward in a direction away from the locking block. Characterized in that the end of the catch is inserted into the annular groove so that the gap sealing bar moves backward together with the second locking rod,
Constant temperature and humidity device.

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