KR100854627B1 - A cosmetic refrigerator - Google Patents

Abstract

A cosmetic refrigerator is provided to be used in a silent bedroom by preventing noise and vibration from being generated from the cosmetic refrigerator. A cosmetic refrigerator comprises a case(10) having a keeping chamber(15) for storing cosmetic. A door(20) is hinged to the lateral side of the case to open and close the keeping chamber. A cooling unit is installed at the case to cool the keeping chamber. A humidity sensor(40) is installed at the keeping chamber to generate a humidity signal corresponding to humidity in the keeping chamber. A limit switch(50) is installed at the keeping chamber to generate a signal when the door opens and closes the keeping chamber. A vacuum generator(60) is driven by the signal from the humidity sensor or the limit switch to generate vacuum in the keeping chamber. An air introduction unit(70) introduces external air having no humidity into the keeping chamber when the vacuum generator is driven.

Description

A cosmetic refrigerator

The present invention relates to a cosmetic refrigerator for storing cosmetics, and more particularly to a cosmetic refrigerator that can prevent the generation of water during use.

Since cosmetics are used directly on the skin, care is very important, especially since they are used for days to months after purchase. Typically, cosmetics are stored inside the dressing table, and since the inside of the dressing table is always at room temperature, there is always a possibility of cosmetic deterioration. On the basis of these problems, refrigerators for cosmetics have recently been introduced and sold. Such cosmetic refrigerators are implemented at low capacity because only cosmetics are stored.

However, in the cosmetic refrigerator, hot air enters the inside of the process of opening and closing the door in order to remove or store the cosmetics, and water is generated by the difference in the saturated steam pressure depending on the temperature. In particular, a lot of water is generated inside the cosmetic refrigerator in the mid-summer or high humidity season, the user has to be inconvenient to remove the water frequently.

The present invention was created to solve the above problems, and an object of the present invention is to provide a cosmetic refrigerator that can prevent the generation of water during use.

Another object of the present invention is to provide a cosmetic refrigerator that can be used even in a quiet bedroom by fundamentally preventing the occurrence of noise and vibration.

In order to achieve the above object, the cosmetic refrigerator according to the present invention,

A case 10 in which a storage room 15 in which cosmetics are stored is formed; A door 20 hinged to a side of the case 10 to open and close the storage compartment 15; A cooling unit (30) installed in the case (10) to cool the inside of the storage chamber (15); A humidity sensor 40 installed in the storage room 15 to measure humidity in the storage room 15 to generate a corresponding humidity signal; A limit switch 50 installed in the storage room 15 to generate a corresponding signal when the door 20 opens and closes the storage room 15; A vacuum forming unit 60 which is operated by a signal generated from the humidity sensor 40 or the limit switch 50 so as to form a vacuum in the storage chamber 15; A moisture removal air inlet unit 70 for introducing external air from which moisture is removed into the storage chamber 15 when the vacuum forming unit 60 is operated; And a controller interlocked with the humidity sensor 40 and the limit switch 50 to control the cooling unit 30, the vacuum forming unit 60, and the moisture removal air inlet unit 70. The unit 30 is a conductive plate 31 including a rear portion 31a installed behind the storage compartment 15 and a bottom surface portion 31b that is bent from the rear portion 31a and extends to an inner bottom of the storage compartment 15. And a cold block 32 installed in close contact with the rear surface 31a, a thermoelectric semiconductor 33 in which one side is in close contact with the cold block 32, and the other side of the thermoelectric semiconductor 33 in close contact with each other. Heat evaporation block 34 is a heat medium is accommodated therein, and the evaporator tube 35 is disposed in the rear of the case 10 and connected in a zigzag shape on the upper and lower ends of both sides of the heat evaporation block 34, ; The vacuum forming unit 60 includes an internal duct 61 communicating with the inside of the storage chamber 15, a vacuum pump 62 connected to the internal duct 61, and an exhaust gas communicating with the outside of the case 10. And a one-way check valve 64 provided between the duct 63 and the vacuum pump 62 and the exhaust duct 63 to open and close in the direction of the exhaust duct 63.

In the present invention, the moisture removal air inlet 70 is in communication with the outside of the case 10 inlet duct 71 in close contact with the zigzag in close contact with the rear portion 31a, and the lower portion of the rear portion 31a Is installed on the side is connected to the lower end of the inlet duct 71 is connected to one side and the drip box 72 is formed in the space and the other side of the drip box 72 is connected to the inside of the storage chamber 15 An inner duct 73 and a sponge member 74 installed between the heat evaporation block 34 at the bottom of the drip tray box 72.

In the present invention, the one-way check valve 64, the valve body formed with a first hole (64a) communicated to the vacuum pump 62 side and the second hole (64b) communicated to the exhaust duct 63 side ( 64c, a check ball 64d embedded in the valve body 64c, and a spring 64e for elastically biasing the check ball 64d toward the first hole 64a.

According to the cosmetic refrigerator according to the present invention, the vacuum forming unit is operated by a signal generated from the humidity sensor or the limit switch to form a vacuum in the storage compartment, and the external air from which moisture is removed into the storage compartment when the vacuum forming unit is operated. By including the moisture removal air inlet for introducing, it is possible to effectively remove the water generated in the process of opening and closing the door, it is possible to reduce the effort to remove the water.

In addition, since the cooling unit for cooling the storage unit exchanges heat to the outside by using an evaporator tube, it is possible to fundamentally prevent the occurrence of noise and vibration during the operation of the cosmetic refrigerator, and thus can be used in a quiet space such as a bedroom. There is action, there is effect.

Hereinafter, a cosmetic refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view of a cosmetic refrigerator according to the present invention, FIG. 2 is a view illustrating a state in which a door is opened in the cosmetic refrigerator of FIG. 1, and FIG. 3 is a rear perspective view of the cosmetic refrigerator of FIG. 1. In addition, Figure 4 is a view for explaining the internal structure of the cosmetic refrigerator of Figures 1 to 3, Figure 5 is a view showing an extract of the cooling unit and the moisture removal air inlet employed in Figure 4, Figure 6 Fig. 1 is a sectional view showing the one-way check valve employed in Fig. 4.

As shown, the cosmetic refrigerator according to the present invention includes a case 10 in which a storage room 15 in which cosmetics are stored is formed; A door 20 hinged to the side of the case 10 to open and close the storage compartment 15; A cooling unit (30) installed in the case (10) to cool the inside of the storage compartment (15); A humidity sensor 40 installed in the storage room 15 and measuring humidity inside the storage room 15 to generate a corresponding humidity signal; A limit switch 50 installed in the storage compartment 15 and interlocked with the door 20 to open and close the storage compartment 15 to generate a corresponding signal; A vacuum forming unit 60 which is operated by a signal generated from the humidity sensor 40 or the limit switch 50, and allows a vacuum to be formed inside the storage chamber 15; A dehumidification air inlet unit 70 for introducing external air from which moisture is removed into the storage chamber 15 when the vacuum forming unit 60 is operated; And a controller (not shown) interlocked with the humidity sensor 40 and the limit switch 50 to control the cooling unit 30, the vacuum forming unit 60, and the moisture removing air inlet unit 70.

The storage compartment 15, in which the cosmetics are stored, is installed inside the case 10, and a space between the storage compartment 15 and the case 10 is filled with a heat insulating material such as styrofoam for insulation.

The door 20 is hinged (h) to the front lower side of the case 10, the interior of the storage chamber 15 is opened as it opens to the front side. The rubber edge around the inner edge of the door 20 is attached to the front surface of the case 10 is made of iron plate material. Therefore, when the door 20 is closed to the case 10, the rubber magnet border 21 is attached to the front of the case 10 so that the inside of the storage part 15 is completely blocked from the outside.

The cooling unit 30 cools the inside of the storage compartment 15, and is bent from the rear portion 31a installed in the room after the storage compartment 15, and a bottom surface portion which is bent from the rear portion 31a and extends to the bottom of the storage compartment 15. A conductive plate 31 composed of a 31b, a cold block 32 installed in close contact with the rear portion 31a, a thermoelectric semiconductor 33 in which one side is in close contact with the cold block 32, and a thermoelectric conductor 33 Heat evaporation block 34 which is in close contact with the other side of the heat storage body and the heat medium is accommodated therein, and an evaporation tube which is arranged at the rear of the case 10 and has a zigzag shape connected to the upper and lower ends of both sides of the heat evaporation block 34 ( 35).

As shown in Figs. 4 and 5, the conducting plate 31 has a cross-section "b", so that the rear portion 31a in the vertical direction is located at the rear side of the case 10, and the bottom in the horizontal direction. The surface portion 31b extends to the bottom of the storage chamber 15. It is preferable that the conductive plate 31 is made of aluminum with high thermal conductivity.

The cold block 32 is in close contact with one side of the thermoelectric semiconductor 33, and the heat evaporation block 34 is in close contact with the other side to form a unit. Therefore, when DC power is applied to the thermoelectric semiconductor 33, the temperature on the side of the cold block 32 is lowered and the temperature on the side of the heat evaporation block 34 is increased.

Evaporation tube 35 is one end is connected to the upper side of the heat evaporation block 34, the other end is connected to the lower side of the heat evaporation block 34, a plurality of heat radiation fins to increase the heat exchange rate with the outside air 35a is provided.

By the structure of the cooling unit 30, when a direct current power source is applied to the thermoelectric semiconductor 33, the cold block 32 in close contact with the one side of the thermoelectric semiconductor 33 is cooled, accordingly the cold block 32 The heat of cooling is transferred to the rear portion 31a and the bottom portion 31b to cool the inside of the storage compartment 15.

On the other hand, as one side of the thermoelectric semiconductor 33 is cooled, the temperature of the other side rises, and the heat medium inside the heat evaporation block 34 in close contact with the other side is heated. Therefore, the heat medium inside the heat evaporation block 34 is evaporated to pass through the evaporation tube 35 connected to the upper side of the heat evaporation block 34, and the heat of the heat medium evaporates while passing through the evaporation tube 35. The heat is radiated to the outside air through the tube 35 and the heat radiating fin 35a. As a result, the heat medium phase changes into a liquid phase after losing energy and flows into the heat evaporation block 34 through the lower side of the evaporation tube 35. It is circulated continuously. The storage chamber 15 is cooled while the circulation operation of the heat medium is repeated. At this time, since the cooling heat of the cold block 32 is transmitted to the storage chamber 15 through the conduction plate 31, it is possible to exclude the use of a fan or the like to fundamentally prevent the occurrence of noise and vibration.

The humidity sensor 40 generates a signal corresponding to the case where the humidity inside the storage room 15 is high and transmits the signal to the controller, and the limit switch 50 generates a corresponding signal when the door 20 is opened. Send it to the controller.

As shown in FIG. 5, the vacuum forming unit 60 includes an internal duct 61 communicating with the inside of the storage chamber 15, a vacuum pump 62 connected to the internal duct 61, and an outside of the case 10. And a one-way check valve 64 provided between the exhaust duct 63 and the vacuum pump 62 and the exhaust duct 63 to open and close in the direction of the exhaust duct 63. At this time, the inner duct 61 is connected to the duct bracket 61a installed in the storage chamber 15.

As shown in FIG. 6, the one-way check valve 64 includes a valve body having a first hole 64a communicating with the vacuum pump 62 and a second hole 64b communicating with the exhaust duct 63. 64c, a check ball 64d embedded in the valve body 64c, and a spring 64e for elastically biasing the check ball 64d toward the first hole 64a. When the vacuum pump 62 is operated by the structure of the one-way check valve, the high pressure is formed in the first hole 64a by the air in the storage chamber 15 in which the vacuum pump 62 is sucked, so that the check ball 64d is The rear first hole 64a is opened, and the air is exhausted to the outside through the second hole 64b and the exhaust duct 63. When the operation of the vacuum pump 62 is stopped, the spring 64e pushes the check ball 64d to close the first hole 64a, thereby preventing the air of the outside air from entering the storage chamber 15.

As shown in FIGS. 4 and 5, the moisture removing air inlet part 70 is in communication with the outside of the case 10 and is in close contact with the rear part 31a in a zigzag manner to allow the outside air to flow therethrough. And, installed on the lower side of the rear portion (31a) is connected to the lower end of the inlet duct 71 is connected to one side and the space is formed in the drip tray box 72, the other side of the drip box (72) storage room ( 15) and an inner duct 73 connected to the inside, and a sponge member 74 installed between the heat evaporation block 34 at the bottom of the drip box 72. At this time, the end of the inner duct 73 is connected to the inlet (73a) formed in the storage chamber (15).

By this structure, when the vacuum forming unit 60 is operated, the air in the storage chamber 15 is exhausted to the outside, whereby the air pressure is lowered. Accordingly, the outside air is stored in the storage chamber through the inlet duct 71 communicating with the storage chamber 15. (15) flows into the interior. At this time, since the inlet duct 71 is in close contact with the rear portion 31a of the conductive plate to be cooled, the temperature of the outside air passing through the inlet duct 71 is lowered, and then flows into the storage chamber 15 and the temperature of the storage chamber 15. To prevent it from going up.

On the other hand, since the temperature is lowered in the process of the external air via the inlet duct 71, water is generated in the inlet duct 71 due to condensation. This water flows along the inclined inlet duct 71 and is collected to fall into the drip box 72. Then, the water collected in the drip box 72 is absorbed by the sponge member 74 connected to the heat evaporation block 34 and then moved to the heat evaporation block 34, and the heat of the heat evaporation block 34 is stored in the sponge member ( The water absorbed in 74) is evaporated. That is, the water collected in the drip box 72 is evaporated and removed.

Next, the operation of the cosmetic refrigerator as described above will be described.

When the DC block is applied to the thermoelectric semiconductor 33 and the cold block 32 in close contact with one side is cooled, low-temperature cooling heat is transferred to the bottom surface portion 31b to cool the inside of the storage chamber 15. Then, the heat medium inside the heat evaporation block 34 in close contact with the other side of the thermoelectric semiconductor 33 is heated and evaporated, after which the heated heat medium is evaporated, circulated through the evaporation tube 35, and then phase-changed into a liquid to form a heat evaporation block ( 34) Repeat the circulating motion that flows back inside. Since this cooling is conducted in a conductive manner without using a fan, no noise or vibration is generated.

When the user opens the door 20, the limit switch 50 is linked to the door 20 generates a corresponding signal and transmits to the controller. Alternatively, when the humidity inside the storage room 15 is high, the humidity sensor 40 generates a signal corresponding thereto and transmits the signal to the controller. The controller then operates the vacuum forming unit 60. That is, when the vacuum pump 62 is operated, air containing a lot of humidity in the storage chamber 15 is exhausted to the outside via the internal duct 61-> vacuum pump 62-> exhaust duct 63, Accordingly, moisture in the storage compartment 15 is removed.

On the other hand, since the air inside the storage chamber 15 is exhausted to the outside to lower the air pressure, the outside air is introduced into the storage chamber 15 through the inlet duct 71 in communication with the storage chamber 15. At this time, the air passing through the inlet duct 71 is lowered by the rear portion 31a of the conductive plate 31, thereby preventing the temperature of the storage chamber 15 from rising.

In addition, since the temperature decreases in the process of passing the outside air through the inlet duct 71, condensation occurs and water is generated. The water is collected into the drip box 72 through the inlet duct 71. Thereafter, the water collected in the drip box 72 is absorbed by the sponge member 74 connected to the heat evaporation block 34 and then moved to the heat evaporation block 34, and the heat of the heat evaporation block 34 is transferred to the sponge member ( The water absorbed in 74) is evaporated.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a front view of a cosmetic refrigerator according to the present invention,

2 is a view showing a state in which the door is opened in the cosmetic refrigerator of Figure 1,

3 is a rear perspective view of the cosmetic refrigerator of FIG. 1, FIG.

4 is a view for explaining the internal configuration of the cosmetic refrigerator of Figures 1 to 3,

5 is a view showing an extract of the cooling unit and the moisture removal air inlet is employed in Figure 4,

6 is a cross-sectional view showing an extract of the one-way check valve employed in FIG.

<Description of the symbols for the main parts of the drawings>

10 ... Case 15 ... Storage

20 ... Door 30 ... Cooling Unit

31 ... conduction plate 31a ... rear part

31b ... bottom 32 ... cold block

33 ... thermoelectric semiconductor 34 ... heat evaporation block

35 ... evaporator 35a ... heat sink fins

40 ... humidity sensor 50 ... limit switch

60 ... vacuum forming unit 61 ... internal duct

61a ... Duct bracket 62 ... Vacuum pump

63 ... exhaust duct 64 ... one-way check valve

64a ... First Hole 64b ... Second Hole

64c ... valve body 64d ... check ball

64e ... spring 70 ... dehumidification air inlet

71 ... Inlet duct 72 ... Drain box

73 ... Internal duct 73a ... Inlet

74 ... sponge member

Claims (3)

A case 10 in which a storage room 15 in which cosmetics are stored is formed; A door 20 hinged to a side of the case 10 to open and close the storage compartment 15; A cooling unit (30) installed in the case (10) to cool the inside of the storage chamber (15); A humidity sensor 40 installed in the storage room 15 to measure humidity in the storage room 15 to generate a corresponding humidity signal; A limit switch 50 installed in the storage room 15 to generate a corresponding signal when the door 20 opens and closes the storage room 15; A vacuum forming unit 60 which is operated by a signal generated from the humidity sensor 40 or the limit switch 50 so as to form a vacuum in the storage chamber 15; A moisture removal air inlet unit 70 for introducing external air from which moisture is removed into the storage chamber 15 when the vacuum forming unit 60 is operated; And And a controller interlocked with the humidity sensor 40 and the limit switch 50 to control the cooling unit 30, the vacuum forming unit 60, and the moisture removing air inlet unit 70. The cooling unit 30 may include a conductive plate formed of a rear portion 31a installed behind the storage compartment 15 and a bottom surface portion 31b that is bent from the rear portion 31a and extends to an inner bottom of the storage compartment 15 ( 31), a cold block 32 installed in close contact with the rear surface 31a, a thermoelectric semiconductor 33 in which one side is in close contact with the cold block 32, and the other side of the thermoelectric semiconductor 33 The heat evaporation block 34 which is in close contact with the heat medium is accommodated therein, and the evaporation tube 35 is arranged in the rear of the case 10 and is connected in a zigzag shape at the upper and lower ends of both sides of the heat evaporation block 34. It includes; The vacuum forming unit 60 includes an internal duct 61 communicating with the inside of the storage chamber 15, a vacuum pump 62 connected to the internal duct 61, and an exhaust gas communicating with the outside of the case 10. And a unidirectional check valve (64) installed between the duct (63) and the vacuum pump (62) and the exhaust duct (63) to open and close in the direction of the exhaust duct (63). The method of claim 1, The moisture removal air inlet 70 is in communication with the outside of the case 10 inlet duct zigzag in close contact with the rear portion 31a and the lower side of the rear portion 31a is installed A lower end of the inlet duct 71 is connected to one side and a drip box 72 having a space formed therein and an inner duct 73 connected to the other side of the drip box 72 to be connected to the inside of the storage chamber 15. And a sponge member (74) installed between the heat evaporation blocks (34) at the bottom of the drip box (72). The method of claim 1, The one-way check valve 64 includes a valve body 64c having a first hole 64a communicating with the vacuum pump 62 and a second hole 64b communicating with the exhaust duct 63. And a check ball (64d) embedded in the valve body (64c) and a spring (64e) elastically biasing the check ball (64d) toward the first hole (64a).

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