KR20000006804U - Freezer Pressure Control Valve - Google Patents

Abstract

In the freezer, the installation hole 15 is connected to the freezer compartment 16 in a part of the wall surface 11 of the freezer (10); A lower part is inserted into and fixed to the installation hole 15, and when the pressure of the freezing compartment 16 is lower than the atmospheric pressure, external air is introduced to provide an inflow path of external air so that the pressure of the freezing compartment 16 is close to atmospheric pressure. A valve socket 30 to be formed; A valve coupled to the valve socket 30 to provide an exhaust path for exhausting the air in the freezer compartment 16 to the outside so that the pressure in the freezer compartment 16 approaches the atmospheric pressure when the pressure in the freezer compartment 16 is higher than the atmospheric pressure. A cap 40; And a cover 50 coupled to the valve cap 40 and having a coupling protrusion 51 protruding from the center of the bottom thereof, wherein the pressure control valve for the freezer is configured to contract the air in the freezer compartment in an operating state of the freezer compartment. The user can easily open the door by preventing the freezer door from being opened due to the negative pressure, and if the air pressure inside the freezer rises due to the freezer backup, the exhaust pressure is released to solve the high pressure. This has the advantage of eliminating hazards that can be inflicted on the user when opened.

Description

Freezer Pressure Control Valve

The present invention relates to a freezer, and more particularly, to a pressure control valve for a freezer to prevent the air pressure of the freezer compartment to increase or lower by a certain degree or more.

In general, a freezer is a device that provides a cryogenic temperature and stores the sample at a low temperature. The freezer is stored at a temperature of about −70 ° C. or lower to prevent deterioration of the sample. Samples stored in these freezers are often biological materials, and can store human organs, gene samples, sperm and eggs as well as microorganisms or tissues for a long time.

An example of a freezer for storing such a sample will be described with reference to FIG. 1. In the freezer 10, a cooling device 12 is installed at a lower portion thereof, and a freezing chamber 16 is provided above the cooling device 12. A cabinet CA is installed in the freezer compartment 16, and a storage box BO storing the various samples is stored in the cabinet CA. And the front of the freezer (10) is equipped with a door 13 having a control unit (14).

On the other hand, since the freezer 10 is basically configured to lower the temperature by using electricity, when the cooling system does not operate due to an unexpected power failure or failure of the freezer itself, the temperature inside the freezer increases due to the influence of room temperature. I'm ready to. Under these circumstances, stored biological samples may deteriorate or rot under the influence of temperature. Since the samples stored in the freezer are in some cases too expensive for themselves to be measured or valuable samples that cannot be obtained again, the failure of the cooling system is at risk of causing unforeseen damage.

Therefore, in case an abnormality occurs in the cooling system of the freezer due to a power failure or a failure, the freezer backup device BK is prepared. Most of these backup devices use liquid carbon dioxide (Liquified CO2) or liquid nitrogen (Liquified N2) to spray these liquids into the freezer to lower the temperature inside the freezer by absorbing latent heat as these liquids vaporize.

However, in the conventional freezer as described above, as shown in FIG. 1, various samples are safely stored at a low temperature, and since a separate means for properly maintaining the air pressure of the freezer compartment 16 is not provided, the freezer 10 is not included. It was inconvenient to use, in some cases the user is injured or a problem occurs such as a failure in the freezer (10).

When the freezer operates normally, since the inside of the freezer is in a cryogenic state, the air in the freezer contracts and the air pressure inside the freezer is lower than atmospheric pressure, so that the negative pressure is applied. When the user opens the freezer door 13 in such a negative pressure state, the door does not open well. Therefore, it is not only inconvenient for the user to open the door with excessive force, but also the user may be injured while the door is opened temporarily due to the handle or hinge of the door.

On the contrary, in the state where the above-mentioned refrigeration backup function is operated, the pressure inside the freezer increases as the carbon dioxide or liquid nitrogen vaporizes, and thus becomes a high pressure state. In severe cases, there is a risk of the door falling off by the explosion.

Therefore, it is necessary to improve the convenience of use and reduce the risk of explosion or injury by appropriately adjusting the pressure inside the freezer in the normal state or the state in which the freezing backup function is operated to maintain the level similar to atmospheric pressure.

The present invention is devised to solve the conventional problems as described above, the object of the present invention is a freezer pressure control valve that can maintain the appropriate pressure when the pressure of the freezer compartment rises or falls by various factors To provide.

1 is a cross-sectional view showing the structure of a typical freezer,

Figure 2 is an exploded perspective view showing a pressure control valve of the present invention,

3 is a cross-sectional view of a freezer showing an application state of the present invention,

4 is a cross-sectional view showing a structure of the present invention,

5 and 6 are cross-sectional view showing an operating state of the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

10: freezer 11: the wall

12 cooling device 13 door

14: control unit 15: mounting hole

16: freezer compartment 20: pressure control valve

30: valve socket 31: hole

32: engaging groove 33: contraction pressure adjusting hole

34: O-ring 35: contraction pressure control membrane

40: valve cap 41: coupling hole

42: expansion pressure adjusting hole 45: expansion pressure adjusting membrane

50: cover 51: engaging projection

52: O-ring

According to the present invention, a freezer comprising: an installation hole connected to a freezer compartment on a part of a wall surface of the freezer; A valve socket having a lower portion inserted into and fixed to the installation hole and providing an inflow path of the outside air by introducing external air when the pressure of the freezing compartment is lower than the atmospheric pressure to bring the pressure of the freezing compartment close to the atmospheric pressure; A valve cap coupled to the valve socket to provide an exhaust path for exhausting air in the freezer compartment to the outside so that the pressure of the freezer compartment is close to the atmospheric pressure when the pressure of the freezer compartment is higher than the atmospheric pressure; It is coupled to the top of the valve cap, there is provided a pressure control valve for a freezer comprising a; cover is formed protruding from the bottom center.

Hereinafter, one preferred embodiment of a pressure control valve for a freezer according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is an exploded perspective view showing a pressure control valve according to the present invention, Figure 3 is a cross-sectional view of the freezer showing the application state of the present invention.

2 and 3, the pressure control valve 20 for the freezer 10 of the present invention is installed in the installation hole 15 formed in a part of the wall surface 11 of the freezer 10, the freezer compartment 16 Is connected to the configured to provide a path for the outside air is introduced into the freezer compartment according to the pressure state of the freezer compartment 16 or to provide a path for exhausting the air of the freezer compartment 16.

The pressure regulating valve 20 is composed of a valve socket 30, a valve cap 40, and a cover 50. First, the valve socket 30 has an installation hole 15 of the freezer 10 described above. Inserted and fixed in), the hole 31 is vertically penetrated in the inner center, the coupling groove 32 is formed around the hole 31 of the upper surface.

In addition, a plurality of, preferably 3 to 8, contraction pressure adjusting holes 33 connected to the outside around the coupling groove 32 are vertically formed on the upper surface of the valve socket 30. In addition, the shrinkage pressure adjusting membrane 35 is fitted into the coupling groove 32, and the shrinkage pressure adjusting membrane 35 covers the shrinkage pressure adjusting hole 33. Such a valve socket 30 is preferably provided with an O-ring 34 on the lower and upper outer peripheral surface to increase the sealing.

On the other hand, the valve cap 40 has a coupling hole 41 is formed in the center of the upper surface, a plurality of expansion pressure adjusting holes 42 are formed around the center of the upper surface on which the coupling hole 41 is formed. In addition, an expansion pressure adjusting membrane 45 is disposed on the expansion pressure adjusting hole 42 so as to cover the hole 42 sufficiently to cover the expansion pressure adjusting hole 42. Therefore, when the pressure of the freezing chamber 16 is increased due to vaporization of the liquid gas, the adjustment membrane 45 is lifted upward by the pressure, and the hole 42 is opened to exhaust the air in the freezing chamber 16 to the outside. As a result, the pressure in the freezing chamber 16 is lowered to approximate the atmospheric pressure.

In addition, the cover 50 is coupled to the engaging hole 41 of the valve cap 40 is formed by the engaging projection 51 protruding in the center of the bottom surface. At this time, it is preferable that the coupling protrusion 51 is further provided with an O-ring 52 on the outer circumferential surface so as to be hermetically coupled to the coupling hole 41.

In the present invention, the contraction pressure regulating membrane 35 and the inflation pressure regulating membrane 45 are elastic resins having elasticity and self-weight so that the contraction pressure regulating hole 33 and the inflating pressure regulating hole 42 are formed. The cover is kept tight and the hole is opened by a temporary pressure shock to allow the inflow or outflow of air.

Referring to the operation and effects of the present invention configured as described above in detail.

Since the temperature of the freezer compartment is maintained at a cryogenic temperature in a state in which the sample is normally stored in the freezer 10, the air is contracted so that the air pressure of the freezer compartment 16 is lower than atmospheric pressure. Therefore, the user is inconvenient to apply a strong force when opening the freezer door 13. However, in this case, since the pressure regulating valve 20 is installed on the wall surface 11 of the freezer 10 so as to be connected to the freezing chamber 16, a temporary strong negative pressure is generated when the door 13 is opened. Is applied to.

Accordingly, while the negative pressure is applied, the expansion pressure regulating membrane 45 positioned on the upper surface of the valve cap 40 is in close contact with the upper surface of the valve cap 40, while the coupling groove 32 of the valve socket 30 is provided. The contraction pressure regulating membrane 35 inserted in the outer portion is lifted up so that outside air flows into the valve cap 40 through the contraction pressure adjusting hole 33. The low air pressure in the freezer compartment 16 is close to atmospheric pressure due to the external air introduced into the valve cap 40, and the door 13 is easily opened.

On the contrary, when the freezing backup device BK is operated to vaporize liquid carbon dioxide (CO2) or liquid nitrogen (N2) in the freezing chamber 16, the contraction pressure regulating membrane 35 is the upper surface of the valve socket 30. While in close contact with the expansion pressure regulating membrane 45 is raised. Therefore, since the vaporization gas (carbon dioxide or nitrogen) of the freezing chamber 16 is exhausted to the outside through the expansion pressure adjusting hole 42, the air pressure of the freezing chamber 16 maintains an appropriate state close to atmospheric pressure.

On the other hand, if the air pressure of the freezer compartment 16 is properly maintained, the expansion pressure regulating membrane 45 raised upward is lowered and positioned on the upper surface of the valve cap 40 to block the outflow of cold air from the freezer compartment 16.

The above-described embodiment is merely to explain an example of a preferred embodiment of the present invention, the scope of the present invention is not limited to such, and can be appropriately changed within the scope of the same thought, for example to store a sample In addition to the freezer it is widely applicable to various freezers.

As described above, the present invention forms an installation hole in the wall of the freezer compartment, and installs a pressure control valve consisting of a valve socket, a valve cap, and a cover in the installation hole, so that the freezer pressure of the freezer is adjusted to approach atmospheric pressure. Therefore, there is a very useful effect that can store the sample more safely, such as to prevent in advance several accidents caused by the pressure change in the freezer compartment.

Claims (5)

In the freezer, An installation hole 15 connected to a freezer compartment 16 in a part of the wall surface 11 of the freezer 10; A lower part is inserted into and fixed to the installation hole 15, and when the pressure of the freezing compartment 16 is lower than the atmospheric pressure, external air is introduced to provide an inflow path of external air so that the pressure of the freezing compartment 16 is close to atmospheric pressure. A valve socket 30 to be formed; A valve coupled to the valve socket 30 to provide an exhaust path for exhausting the air in the freezer compartment 16 to the outside so that the pressure in the freezer compartment 16 approaches the atmospheric pressure when the pressure in the freezer compartment 16 is higher than the atmospheric pressure. A cap 40; And a cover 50 coupled to the valve cap 40 and having a coupling protrusion 51 protruding from the center of the bottom thereof. According to claim 1, wherein the valve socket 30 has a hole 31 is formed through the inner center, a plurality of contraction pressure adjusting holes 33 are formed vertically through the upper surface, the shrinkage pressure adjusting hole 33 The pressure control valve for a freezer, characterized in that the shrinkage pressure regulating membrane (35) is provided to cover the shrinkage pressure adjusting hole (33). According to claim 1, wherein the valve cap 40 has a coupling hole 41 is formed in the center of the upper surface is engaged with the engaging projection 51 of the cover 50, a plurality of expansion pressure adjusting holes (around the center of the upper surface ( 42 is formed, the pressure regulator valve for freezer, characterized in that the expansion pressure adjusting hole 42 is provided with an expansion pressure adjusting membrane 45 that can cover the expansion pressure adjusting hole (42). The pressure control valve for a freezer according to claim 1, wherein the valve socket (30) is further provided with (34) O-rings on the lower and upper outer circumferential surfaces thereof to increase the sealing property. According to claim 1, wherein the cover 50 is an O-ring 52 is further provided on the outer circumferential surface of the coupling protrusion 51 so that the coupling protrusion 51 is hermetically coupled to the coupling hole 41 of the valve cap 40. Pressure control valve for freezer, characterized in that installed.