KR20190060918A - Soju freezer for camping - Google Patents

Abstract

The present invention relates to a soju freezer for camping, which is able to use a thermoelectric semiconductor device as a cooling means, to make the cooling means in a small size to be proper to be used for camping, to parallelly place a plurality of cooling panels on a heat radiator panel, to greatly increase the cross-sectional area, to install a plurality of air blower fans on one side of a passage of the cooling panels to correspond to a freezing compartment, to allow external air to rapidly pass through the passage, and to improve the heat radiation efficiency of the heat radiator panel and cooling performance of the thermoelectric semiconductor device. According to the present invention, the soju freezer for camping comprises: a housing (2) penetrated by a ventilation hole (2b) to allow air to pass through; a freezing compartment (3) stored in the housing (2) to store soju bottles (B); a block-shaped maxam stone block (M) attached to an internal wall of the freezing compartment to be exposed; a thermoelectric semiconductor device (4) which cools the freezing compartment (3); a cool block (5) whose one side surface comes in contact with and is fixated on a cooling surface of the thermoelectric semiconductor device (4) and whose other side surface comes in contact with and is fixated on the freezing compartment (3), thereby transferring the heat cooled by the thermoelectric semiconductor device (4) to the freezing compartment (3) and cooling down the freezing compartment (3); a heat radiation plate (6) which comes in contact with and fixated on a heat radiation surface of the thermoelectric semiconductor device (4) to radiate the heat on the heat radiation surface of the thermoelectric semiconductor device (4); an air blower fan (7) whose wheel, which is rotated by a power supply, rotates to transfer external air to the heat radiation plate (6) and to cool down the heat radiation plate (6); and an insulation material (8) filling the inside of the housing (2) to wrap around the freezing compartment (3) and the cool block (5) and to prevent the cooled heat of the cool block (5) from exchanging with external heat.

Description

{Soju freezer for camping}

The present invention relates to a soju freezer for camping, and more particularly, to a soju freezer for camping, more particularly, to a camping so that the cooling means is made compact by using a thermoelectric semiconductor element, and a plurality of cooling panels are arranged in parallel without partition, And a plurality of blowing fans corresponding to the freezing chambers are provided on one side of the cooling panels so as to allow the passage of the outside air to have an increased cross sectional area to rapidly pass therethrough so that the heat radiation efficiency of the heat sink and the cooling performance of the thermoelectric semiconductor device can be improved And also to attach a cryptomeric block to the freezing chamber so that the soft flavor can be felt by far-infrared rays emitted from the cryptomeric block.

You can not carry a large refrigerator or freezer in the hot summer months, so you will have to put your drink or liquor in the ice box with ice and then go camping. When you arrive at the camping area, the ice melts and becomes ice water due to the hot weather. Drinks and liquor stored together in this ice water are kept locked, so you can drink coolly.

However, since the temperature of soju is raised from the ice box and the temperature rises in hot weather, unlike alcohol-free beverage, it can not drink a large amount in a short period of time. The temperature rises over time, and you can not feel the cool taste.

Therefore, even if the time is elapsed when the soju cooled in the summer camping ground is consumed, a freezer that can drink cool until the soju is finally emptied is desperately required.

In general freezer, compressed freon gas is compressed by a compressor, and then sent to a condenser, where it is condensed into a liquid phase. Thereafter, the refrigerant passes through an expansion valve to lower the pressure so that evaporation proceeds. When the refrigerant expands due to low pressure, Heat exchange is performed to cool the place where the evaporator (indoor unit) is installed. Such a conventional freezer needs to be equipped with complicated devices necessary to circulate freon gas by a compressor and to change the state in the circulation process, so that it is difficult to manufacture the refrigerator in a small size. For this reason, it is a reality that camping freezers are not widely spread.

Recently, a small freezer is manufactured using a thermoelectric semiconductor device. A related art related to this is a refrigerator using a thermoelectric element of Utility Model Registration No. 20-0251823. The prior art includes a plurality of refrigerant tanks 10, 10-1 and 10-2 each having an inlet 11 and an outlet 12 and communicating with each other through a connection hose 50, Sequentially;

The thermoelectric elements (20) are attached to the respective refrigerant tanks (10, 10-1, 10-2), and the polarities of the thermoelectric elements (20) attached to the respective refrigerant tanks are reversed;

A motor pump 30 is installed in any one of the connecting hoses 50;

A radiator fin (40), a radiator plate (41), and a radiator fan (42) are provided in any of the coolant tanks (10).

However, since the conventional technology has a structure in which the refrigerant is cooled by the thermoelectric element 20 using any one of the refrigerant tanks 10, there is a problem in that it is not suitable for camping because the refrigerant is liquid, there was.

Another prior art is a thermoelement-type refrigerator of the registered patent 10-1791383. The present invention relates to a refrigerator having a refrigerator compartment 20 in which a plurality of refrigerated articles are stored in a refrigerator 10 and a refrigerator compartment 20 inside the refrigerator compartment 20, A cooling package 40 for cooling the refrigerator compartment 20 by being engaged with the refrigerator compartment 20 after being inserted into the cover insertion hole 32; A heat dissipation package 50 coupled to the cooling package 40 for dissipating the heat absorbed in the process of cooling the refrigerating compartment 20 and a heat dissipation package 50 connected to the cooling package 40 inside the refrigerating compartment 20, A heat absorbing block 60 for absorbing heat inside the refrigerating compartment 20; a rotary table 70 rotatably installed in the refrigerating compartment 20 to store a plurality of refrigerated articles; 10) is hinged to one side of the refrigerator A door 100 for opening and closing (20);

The rotary table table 70 includes a table body 71c composed of upper and lower plates 71a and 71b spaced from each other and a plurality of vertical partition walls 71c symmetrically provided between the upper and lower plates 71a and 71b, A plurality of shelves 72 provided between the vertical partition 71c and the vertical partition 71c and a plurality of shelf attachment and detachment recesses 73 formed in the vertical partition 71c; And a shelf attaching / detaching protrusion (74) formed at a close end of the shelf (72) in close contact and detachably attached to the shelf attaching / detaching groove (73), wherein the shelf attaching / detaching protrusion (74) (74a) and a second detachment protrusion (74b) having a groove formed on one side thereof;

A plurality of flow holes 75 are formed in the respective vertical partition walls 71c so that cool air can smoothly flow between the space formed by the one vertical partition and the space formed by the other vertical partition,

The shelf 72 provided between the vertical partition walls 71c facing each other is provided with a shoulder 72a for preventing the refrigerated article, which is stored when the table body 71 is rotated, from being pushed down by the centrifugal force.

However, since the liquid refrigerant circulating through the refrigerant pipe 52 is cooled by the heat dissipation block 51 as shown in FIG. 3, a compressor or a pump circulating the liquid refrigerant The heat dissipation packaging 50 corresponding to the heat dissipation plate of the present invention is a water-cooled structure. Therefore, when the refrigerant pipe 52 is corroded for a long period of time, So that the problem of the water-cooled heat dissipating means is maintained.

If the refrigerant pipe 52 is filled with the refrigerant gas and circulated, it is necessary to install a compressor, a condenser, an expansion valve, an evaporator, etc. on the path of the cold pipe 52, can not avoid. Further, if the cooling water is filled in the refrigerant pipe 52 and circulated, another cooling means for cooling the cooling water must be additionally installed on the outside, so that the structure is complicated. If cooling water is not additionally provided outside, the cooling water is heated and passes through the heat-dissipating block again after it has been heated. When the cooling water is not cooled, The temperature is further increased, and the temperature is equal to the temperature of the heat-dissipation block. As a result, the cooling performance can not be expected.

Accordingly, although the above-described conventional technique does not show the external cooling means for cooling the refrigerant, the structure is simple, but considering the cooling means to be additionally installed outside, the refrigerator has a problem that it is bulky and can not be used for camping .

Korea Utility Model Registration 20-0251823 (Notice of November 22, 2001) Korean Patent No. 10-1791383 (issued October 31, 22017)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a camping soju freezer which is suitable for camping by making the cooling means compact using a thermoelectric semiconductor device.

Another object of the present invention is to provide a refrigerator having a plurality of cooling panels of a heat radiating plate arranged parallel to each other without a partition wall to greatly increase the cross sectional area and a plurality of blowing fans corresponding to the freezing chamber on one side of the cooling panels, The present invention is to provide a soju freezer for camping which can improve the heat radiation efficiency of the heat sink and the cooling performance of the thermoelectric semiconductor device by allowing the passage to pass quickly.

It is still another object of the present invention to provide a soju freezer for camping, in which the cryptomeric block is attached to the freezing chamber so that the soft sour taste can be felt by far-infrared rays emitted from the cryptomeric block.

In order to achieve the above object, a soju freezer for camping according to the present invention has a size that can be carried, an entrance port (2a) for accommodating the freezing chamber (3) at an upper portion thereof, A housing (2) through which the vent hole (2b) passes;

A freezing chamber (3) housed in the housing (2) so as to correspond to the entrance (2a) and storing the soju bottle (B) therein;

A cryptomeric block M in block form attached to the inner wall of the freezing compartment;

A thermoelectric semiconductor element (4) for cooling the freezing chamber (3) by power supply;

One side is closely fixed to the cooling surface of the thermoelectric semiconductor element 4 and the other side is closely fixed to the freezing chamber 3 to transfer the heat cooled by the thermoelectric semiconductor element 4 to the freezing chamber 3 A cool block (5) for cooling the freezing chamber (3);

A heat dissipating plate (6) tightly fixed to the heat radiating surface of the thermoelectric semiconductor element (4) to dissipate heat on the heat radiating surface of the thermoelectric semiconductor element (4);

A blowing fan 7 installed at one side of the passage C of the heat radiating plate 6 and rotating the wheel rotated by power supply to pressurize external air to the heat radiating plate 6 to cool the heat radiating plate 6; And

And a heat insulating material 8 filled in the housing 2 so as to enclose the freezing chamber 3 and the cooling block 5 to block heat exchange between the cooling heat of the freezing chamber 3 and the cooling block 5 with external heat do.

The freezing chamber (3) and the cool block (5) of the present invention are closely tightly fixed to each other with fastening bolts (9).

A freezing chamber (3) of the present invention is formed with a tab so that a bottom surface thereof protrudes so as to be in close contact with a bottom surface of the soju bottle (B), and a fastening bolt (9) is fastened and assembled on the bottom surface thereof.

The heat sink (6) of the present invention is characterized in that a plurality of cooling panels (62) are fixed in parallel close to a fixing panel (61) which is in close contact with the heat radiating surface of the thermoelectric semiconductor element (4)

The cooling panel 62 has a shape in which the longitudinal direction of the body of the metal thin plate is connected to the front end of the front pin 63b having a continuous waveform shape by joining the first convex portion 63a and the first concave portion 63b with the first connecting portion 63c 63 are extended in the longitudinal direction and the second convex portion 64a and the second concave portion 64b are joined to the rear portion of the front pin 63 by the second connecting portion 64c to have a continuous waveform shape The positions of the second convex portion 64a and the second concave portion 64b are different from the positions of the first convex portion 63a and the first concave portion 63b located in front of the second convex portion 64a and the rear pin 64 A gap H is formed at the boundary between the first and second convex portions 63a and 64a and between the first and second concave portions 63b and 64b and the front pin 63, And the rear fins (64) are repeatedly longitudinally interlocked with each other;

The cooling panel 62 includes a first convex portion 63a, a first concave portion 63b, a first connecting portion 63c, a second convex portion 64a, a second concave portion 64b, and a second connecting portion 64c are arranged in parallel to each other so that the distance between the first convex portions 63a, the distance between the first concave portions 63b, the distance between the second convex portions 64a, and the distance between the second concave portions 64b Are formed to form the passage C.

A plurality of freezing chambers 3 of the present invention are arranged in a row and the fixing panel 61 of the heat radiating plate 6 is elongated in a single body shape corresponding to the entire length of the freezing chamber 3, Is installed at one side of the passage (C) of the heat sink (6) corresponding to the freezing chamber (3) at a ratio of 1: 1.

Further, in the present invention, the auxiliary freezing cup 10 is contained in the freezing chamber 3 so that beer or beverage can be consumed coolly.

The present invention configured as described above is advantageous for camping because it can be manufactured in a small size because the cooling chamber is cooled by using the thermoelectric semiconductor element.

Further, the present invention is characterized in that a plurality of cooling panels of a heat radiating plate are arranged in parallel without partition walls to greatly increase the cross-sectional area, and a plurality of blowing fans are provided on one side of the cooling panels to correspond to the freezing chamber, The cooling efficiency of the thermoelectric semiconductor device can be improved by increasing the heat radiation efficiency of the heat sink.

Further, the present invention is advantageous in that an auxiliary freezing cup can be stored in a freezing chamber to store beer or beverage in a container that can not be stored in the freezing chamber and drink coolly.

In addition, the present invention is advantageous in that a lot of far-infrared rays are radiated in the cryptomeric block attached and fixed to the inner wall of the freezing chamber to soften the soju taste.

1 is a perspective view of a soju freezer for camping according to the present invention;
2 is a perspective view showing a state in which soju is stored in a soju freezer for camping according to the present invention;
3 is a front sectional view of a soju freezer for camping according to the present invention
4 is a side sectional view of a soju freezer for camping according to the present invention
5 is an enlarged view of an assembled state of the freezing chamber, the cool block, and the heat sink according to the present invention.
6 is an enlarged cross-sectional view of the heat sink according to the present invention before assembly
Fig. 7 is an enlarged cross-sectional view after assembly of the heat sink according to the present invention
8 is a perspective view of a heat sink fins of the heat sink according to the present invention
9 is an enlarged view of the assembled heat sink according to the present invention,
10 is a side sectional view showing a state where an auxiliary freezing cup is housed in a freezing room according to another embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the structure of a soju freezer for camping according to the present invention will be described in detail with reference to the accompanying drawings.

As can be seen from the figure, the structure of the soju freezer 1 for camping according to the present invention mainly includes a housing 2 constituting an external shape, a freezing chamber 3 for storing soju, A cool block 5 for transferring the cooling heat of the thermoelectric semiconductor element 4 to the freezing chamber 3 and a heat sink for dissipating the heat of the thermoelectric semiconductor element 4 A blowing fan 7 for feeding outside air to the heat sink 6 and a heat insulating material 8 for enclosing the freezing chamber 3 and the cool block 5 to block heat exchange with the external heat.

The housing 2 has a size such that the user can carry it without any tools. An opening 2a for accommodating the freezing chamber 3 is formed in the upper portion of the housing 2 and a ventilation hole 2b is formed in the side thereof for allowing fresh outside air to pass therethrough. Respectively. The air vents 2b are formed on both sides, and a blowing fan 7, which will be described later, is mounted at a position corresponding to one side to allow outside air to pass.

Since the freezing chamber 3 is cooled by the thermoelectric semiconductor element 4 to cool the soju or beverage stored therein, the freezing chamber 3 is made of a metal material having good heat transfer, Shape. The bottom surface of the freezing chamber 3 is brought into close contact with the bottom surface of the concave soap bottle B because the soap bottle B is seated, so that the bottom surface of the freezing chamber 3 protrudes so as to increase the heat transfer efficiency. That is, the bottom surface of the freezing chamber (3) has the same shape as the bottom surface of the shake bottle (B), and tightly adhered to the bottom surface of the freezing chamber (3).

In addition, a thread, that is, a tab is formed on the bottom surface of the freezing chamber 3 so that the fastening bolt 9 can be fastened and assembled.

As shown in the drawing, the height of the freezing chamber 3 has a height capable of accommodating from the lower portion of the soju bottle B to the end of the straight section. The soju bottle B accommodated in the freezing chamber 3 is tightly adhered to the freezing chamber 3 by the weight of its own weight and the weight of the soju contained therein and the side surface is in close proximity to the wall surface of the freezing chamber 3 So that the cooling heat of the freezing chamber 3 is transferred to the soju as it is, so that the heat loss is hardly generated and the storage temperature is remarkably lowered. The temperature of the bottom surface of the freezing chamber 3 was -13 캜 and the temperature of the lower side and the side of the side were measured at -11 캜 and -7 캜, respectively, according to the prototype of the present invention, The performance was good, so the name of the invention was freezer, not refrigerator.

In view of the fact that the present invention is made for a compact size because it is for camping, as shown in the drawing, three freezing chambers 3 are mounted so as to simultaneously cool three soju bottles (B). It is not easy for a large number of people in the summer to drink three bottles in a short period of time. Moreover, when the soju bottle (B) is emptied in the freezing chamber (3), a new shochu bottle (B) A large number of people can drink enough cool shochu for a long time.

The cryptomeric block M is attached and fixed in a state of being inserted into the bottom surface of the freezing chamber 3 so as to be exposed. Adamshell block (M) fixation uses adhesive. The bottom surface of the freezer compartment 3 and the surface of the calseramic block M are smoothly processed without leveling or the bottom of the shochu bottle B is lowered by the crawlerblock block M to the freezing chamber 3) Prevent the phenomenon of not touching the bottom surface.

Cryptomeria is a stone composed of mysterious rare earths emitting more than 90% of 8-11 ㎛ far infrared rays. As is widely known, far-infrared rays activate the motility of water molecules to make water molecules into a fine and stable structure to prevent contamination and increase the adhesion and permeability to the cell membrane, thus enhancing the vital vitality. By this far infrared effect, alcohol, coffee, juice, etc. are placed on the croaker and the taste is soft and smooth. This is because the infrared ray breaks the water molecules to help the in vitro release of harmful substances and increases the adhesion and permeability of water molecules, Because it helps.

The cryptomeric block of the present invention is first crushed at a high temperature to remove impurities and then pulverized into a fine powder form in a crusher. The block is compressed into a block form at a high pressure and then baked in a kiln at 1300 ° C. for a long time, .

The thermoelectric semiconductor device 4 has a thin plate shape. When power is supplied, one side of the thermoelectric semiconductor element 4 is cooled to become a low-temperature cooling surface, and the other side thereof radiates heat to maintain the cooling surface continuously. Is a heat radiating surface rising. Conversely, if the power polarity is changed, the cooling surface becomes the heat releasing surface and the heat releasing surface becomes the cooling surface. Therefore, the user can adjust the cooling and heating surfaces according to the user's power polarity selection.

The thermoelectric semiconductor element 4 is a standard product having a length and width of 40 mm and a thickness of 4 mm. When one side is cooled when power is supplied, the temperature of the cooling surface is transferred to the freezing chamber (3), the small soju freezer (1) for camping according to the present invention can be manufactured. In addition, recently developed thermoelectric semiconductor device 4 has been reported to be able to control its own cooling surface temperature to the lowest -50 ° C and the heat-releasing surface temperature to the maximum 80 ° C, which is expected to lead the refrigeration field in the future.

The cool block 5 is closely assembled between the freezer compartment 3 and the thermoelectric semiconductor element 4 and functions to transfer the temperature of the cooling surface of the thermoelectric semiconductor element 4 to the freezer chamber 3, A metal material having a good thermal conductivity such as aluminum or copper can be used and an aluminum material which is light, easy to purchase, inexpensive, and resistant to corrosion can be used. The reason why the cool block 5 is used is that as the thermoelectric semiconductor element 4 is a compact standard product as described above, it does not come in contact with the bottom surface of the freezing chamber 3 having a large area in a sufficient area, It is for. Therefore, if the cool block 5 is brought into close contact with a sufficient area over the entire bottom surface of the freezing chamber 3, the low temperature of the cooling surface of the thermoelectric semiconductor element 4 can be quickly transmitted to the bottom surface of the freezing chamber 3, One of the reasons why the bottom surface temperature of the freezing chamber 3 of the present invention reaches -13 캜 is also because of the large area of the cool block.

Also in the case of the cool block 5, tabs are formed so that the fastening bolts 9 can be fastened and assembled on the upper surface contacting the freezing chamber 3.

In the meantime, as shown in the drawing, the freezing chamber 3 and the cool block 5 are closely tightly fixed to each other with fastening bolts 9, as shown in the drawings. Since the fastening bolts 9 are fastened and assembled between the freezing chamber 3 and the cool block 5, they can be assembled tightly and tightly. In addition, since the fastening bolts 9 are not visible to the naked eye, This has a nice advantage.

The heat dissipating plate 6 has one side surface of the fixing panel 61 closely contacting the heat dissipating surface of the thermoelectric semiconductor element 4 and functioning to dissipate the heat of the heat dissipating surface thereof in an air cooling manner. As described above, one side of the thermoelectric semiconductor element 4 becomes a cooling surface and the other side thereof becomes a heat releasing surface. If the temperature of the heat releasing surface is not lowered, the temperature of the cooling surface can not be lowered. In other words, the lower the temperature of the heat radiation surface, the lower the temperature of the cooling surface. Therefore, it is very important to lower the temperature of the heat dissipation surface of the thermoelectric semiconductor element 4 to the maximum, so that the heat dissipation plate 6 that lowers the temperature of the heat dissipation surface is a very important factor.

Therefore, the ideal design of the air-cooled heat sink is that it is press-fed by the blowing fan to come in contact with the rapidly passing air in a large area so as to dissipate its own heat sufficiently in the air and thereby the heated air can pass quickly So as not to interfere with the flow of air.

The heat sink (6) of the present invention meets the above-mentioned ideal design. 6 to 9, the heat sink 6 of the present invention includes a plurality of cooling panels 62 which are closely attached to a fixed panel 61 which is in close contact with the heat radiating surface of the thermoelectric semiconductor element 4, 61 may be formed with a groove 61a so that one end of the cooling panel 62 is press-fitted and then brazed or fixed by brazing without forming the groove 61a.

Since the cooling panel 62 is in contact with air passing therethrough and dissipates its heat in the air, the cross-sectional area of the cooling panel 62 in contact with the air is large, so that heat exchange efficiency is improved. As shown in the figure, a plurality of cooling panels 62 are arranged in parallel to each other and a passage C for guiding the flow of air is formed between adjacent cooling panels 62.

6 and 9, the shape of the thin metal plate in the longitudinal direction of the body is such that the first convex portion 63a and the first concave portion 63b are joined together by the first connecting portion 63c, And the second convex portion 64a and the second concave portion 64b are joined to the second connecting portion 64c on the rear side of the front pin 63. [ The positions of the second convex portion 64a and the second concave portion 64b are set such that the positions of the first convex portion 63a and the first concave portion 63b located at the front side of the second convex portion 64a and the second concave portion 64b, The rear fin 64 extends in the longitudinal direction so that the gap H is formed at the boundary between the first and second convex portions 63a and 64a and between the first and second concave portions 63b and 64b And the front pin 63 and the rear pin 64 are repeatedly arranged in the longitudinal direction so as to interlock with each other so that the first and second convex portions 63a and 64a and the first and second concave portions 63b ) 64b are arranged in a zigzag manner.

In the heat radiating plate 6 of the present invention having the above-described structure, a plurality of the cooling panels 62 are assembled in a closely fitting manner in parallel, so that the first convex portions 63a are assembled at intervals, 1 concave portions 63b are assembled at intervals, second convex portions 64a are assembled at intervals, and second concave portions 64b are assembled at intervals. Accordingly, the distance between the first convex portions 63a, the distance between the first concave portions 63b, the distance between the second convex portions 64a, and the distance between the second concave portions 64b (C).

The air passage C is a convex space formed by the first convex portion 63a of the front pin 63 and the first connecting portion 63c connected to both sides of the first convex portion 63a and the first concave portion 63b And a first connection part 63c connected to both sides thereof. The passage C is a convex space formed by the second convex portion 64a of the rear fin 64 and the second connecting portion 64c connected to both sides thereof and the second concave portion 64b and the second concave portion 64b connected to both sides thereof 2 connecting portion 64c. The spaces of the front and rear pins 63 and 64 are disagreated and the second connecting portion 64c of the rear pin 64 is located in the convex space of the front pin 63 and the concave space of the front pin 63 And the second connection portion 64c of the rear fin 64 is located.

The air flowing in the convex space of the front pin 63 moves upward and downward through the gap H while flowing in the turbulent state by colliding with the second connection portion 64c of the rear fin 64 to freely move the entire heat sink 6 Through the heat sink (6). The air flowing in the concave space of the front pin 63 moves up and down through the gap H while flowing in a turbulent state by colliding with the second connection portion 64c of the rear fin 64, Flow. The convex space of the rear fin 64 and the air flowing in the concave space move upward and downward through the gap H in the same flow so that the heat sink 6 freely flows throughout.

The air flowing in the passage C of the heat dissipating plate 6 flows in the turbulent flow state and the passage C sufficiently communicated with the cooling panels 62 and secured sufficiently wide and the gap H so that the temperature of the heat-radiating surface of the thermoelectric semiconductor element 4 is effectively lowered to improve the cooling performance of the thermoelectric semiconductor element 4. [ One of the other reasons that the bottom surface temperature of the freezing chamber 3 of the present invention reaches -13 캜 is due to the structure of the heat sink 6. [

3, a plurality of freezing chambers 3 are arranged in a row, so that the fixing panel 61 of the heat radiating plate 6 is elongated in a single body corresponding to the entire length of the freezing chamber 3. The blowing fan 7 is provided at one side of the passage C of the heat sink 6 as shown in FIG. 4 so as to correspond to the freezing chamber 3 at a ratio of 1: 1.

The air blowing fan 7 is installed on one side of the passage C of the heat radiating plate 6 while being close to the ventilation hole 2b inside the housing and the wheel rotating by the power supply is rotated to blow the outside air to the heat radiating plate 6 And functions to cool the heat radiating plate 6 by pressure feeding. Therefore, the detailed description will be omitted because it is a known technique.

Since the cooling fan 62 located below the freezing chamber 3 can be smoothly cooled, the temperature of the heat-radiating surface of the thermoelectric semiconductor element 4 can be reduced The cooling performance can be improved.

The heat insulating material 8 is filled in the housing 2 so as to enclose the freezing chamber 3 and the cooling block 5 and functions to prevent the cooling heat of the freezing chamber 3 and the cooling block 5 from being heat- And further description is omitted because it is also a known technology.

Meanwhile, in the present invention, the auxiliary freezing cup 10 separately prepared in the freezing chamber 3 is accommodated to cool the beverage contained in the bottles which can not be accommodated in the freezing chamber 3. For example, when drinking beer popularly popular with shochu in summer, the beer is filled in the auxiliary freezing cup 10 and cooled, so that a cool beer can be drunk.

The bottom surface of the auxiliary freezing cup 10 has the same shape as the bottom surface of the freezing chamber 3 so as to be in close contact with the bottom surface of the freezing chamber 3.

The present invention constructed as described above can be used for camping purposes because it can be manufactured to be small enough to store about three bottles of soju bottles (B), and that the heat sink (6) And that the radiant source far infrared rays in the cryptomeric block can soften the sour taste. Therefore, it is advantageous to enhance the value of use when it is used in related fields as an advanced technology than the conventional technology. It is an invention.

1: shochu freezer for camping 2: housing
3: Freezer 4: Thermoelectric semiconductor device
5: Cool block 6: Heat sink
6: blowing fan 7: insulation
8: Insulation material 9: Fastening bolt
10: Secondary freezing cup M: Cryptomeric block

Claims (6)

A housing 2 having an opening 2a for accommodating the freezing chamber 3 at an upper portion thereof and having a ventilation hole 2b for allowing air to pass therethrough;
A freezing chamber (3) housed in the housing (2) so as to correspond to the entrance (2a) and storing the soju bottle (B) therein;
A cryptomeric block M in block form attached to the inner wall of the freezing compartment;
A thermoelectric semiconductor element (4) for cooling the freezing chamber (3) by power supply;
One side is closely fixed to the cooling surface of the thermoelectric semiconductor element 4 and the other side is closely fixed to the freezing chamber 3 to transfer the heat cooled by the thermoelectric semiconductor element 4 to the freezing chamber 3 A cool block (5) for cooling the freezing chamber (3);
A heat dissipating plate (6) tightly fixed to the heat radiating surface of the thermoelectric semiconductor element (4) to dissipate heat on the heat radiating surface of the thermoelectric semiconductor element (4);
A blowing fan 7 installed at one side of the passage C of the heat radiating plate 6 and rotating the wheel rotated by power supply to pressurize external air to the heat radiating plate 6 to cool the heat radiating plate 6; And
And a heat insulating material 8 filled in the housing 2 so as to enclose the freezing chamber 3 and the cooling block 5 to block heat exchange between the cooling heat of the freezing chamber 3 and the cooling block 5 with external heat Wherein the shoji freezer for camping is a shoji freezer for camping.
The soju freezer for camping as claimed in claim 1, wherein the freezing chamber (3) and the cooling block (5) are closely tightly fixed to each other with fastening bolts (9).
The freezing chamber (3) according to claim 1, wherein the freezing chamber (3) has a bottom surface protruding so as to be in close contact with a bottom surface of the soju bottle (B), and a tab is formed so that a fastening bolt Suzhou freezer for camping.
The heat sink (6) according to claim 1, wherein the heat sink (6) has a plurality of cooling panels (62) fixed in parallel to a fixed panel (61) closely attached to a heat radiating surface of the thermoelectric semiconductor element (4)
The cooling panel 62 has a shape in which the longitudinal direction of the body of the metal thin plate is connected to the front end of the front pin 63b having a continuous waveform shape by joining the first convex portion 63a and the first concave portion 63b with the first connecting portion 63c 63 are extended in the longitudinal direction and the second convex portion 64a and the second concave portion 64b are joined to the rear portion of the front pin 63 by the second connecting portion 64c to have a continuous waveform shape The positions of the second convex portion 64a and the second concave portion 64b are different from the positions of the first convex portion 63a and the first concave portion 63b located in front of the second convex portion 64a and the rear pin 64 A gap H is formed at the boundary between the first and second convex portions 63a and 64a and between the first and second concave portions 63b and 64b and the front pin 63, And the rear fins (64) are repeatedly longitudinally interlocked with each other;
The cooling panel 62 includes a first convex portion 63a, a first concave portion 63b, a first connecting portion 63c, a second convex portion 64a, a second concave portion 64b, and a second connecting portion 64c are arranged in parallel to each other so that the distance between the first convex portions 63a, the distance between the first concave portions 63b, the distance between the second convex portions 64a, and the distance between the second concave portions 64b Wherein the gap between the first and second passages forms a passage (C).
The refrigerator according to claim 1, wherein a plurality of the freezing compartments (3) are arranged in a row, the fixing panel (61) of the heat dissipating plate (6) is elongated in a single body shape corresponding to the entire length of the freezing compartment 7) is provided at one side of the passage (C) of the heat sink (6) so as to correspond to the freezing chamber (3) at a ratio of 1: 1.
The soju freezer for camping as claimed in claim 1, wherein the auxiliary freezing cup (10) is housed in the freezing chamber (3).

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