KR19990035496A - Chiller of refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator of a refrigerator, the structure of which is improved to increase the cooling efficiency of the refrigerator by effectively radiating the radiating fins by using a predetermined fluid. The cooling groove coupled to one end of the inner phase to be in contact with one side of the thermoelectric element 200 and the thermoelectric element 200 seated in the coupling groove, the coupling groove 130 penetrating the outer wound 110 and the inner wound 120 of the refrigerator Fins 300, a heat dissipation fin 400 in contact with the other side of the thermoelectric element is formed with a fluid outlet at one end, the fluid supply means for circulating a predetermined fluid through the fluid inlet (410, 420), the heat dissipation fin and the fluid It is provided between the supply means comprises a heat dissipation means for dissipating the fluid passing through the heat dissipation fins. The fluid supply means includes a fluid tank 500 in which fluid is stored, a fluid pipe 600 for communicating the fluid outlet of the fluid tank and the heat dissipation fin, and a fluid pump 700 connected to one end of the fluid pipe to force circulation of the fluid. Equipped. In addition, the heat dissipation means includes a coil capacitor 800 provided at one end of the fluid pipe, and an auxiliary heat dissipation pipe 610 formed by bending a plurality of ends at the one end of the fluid pipe. The present invention having such a configuration has an effect of increasing the cooling efficiency of the refrigerator by the cooling fins by circulating the fluid to one end of the heat sink fins and at the same time expanding the heat insulating area of the pipe through which the fluid is circulated. .

Description

Chiller of refrigerator

The present invention relates to a cooling device of a refrigerator, and more particularly, by circulating a fluid to one end of a heat sink fin and at the same time expanding the heat insulating area of a pipe through which the fluid is circulated, thereby inducing effective heat dissipation of the heat sink fins, thereby allowing the refrigerator to cool down. The refrigerator relates to a refrigerator of which the structure is improved to increase the cooling efficiency of the refrigerator.

In general, a refrigerator cooling apparatus of a compressed refrigerator applied to a refrigerator is divided into a freezer compartment and a refrigerator compartment by a trimmer plate, and a storage is accommodated in an internal space in which a plurality of pockets and shelves are formed, The machine room is formed.

In addition, a compressor and a condenser pipe are installed in the machine room, and an evaporator and a blower fan are installed at the rear of the freezer to circulate the cold air generated from the refrigerant into the inside of the refrigerator to perform the freezing and cooling functions.

In the conventional refrigerator configured as described above, the expansion and evaporation of the refrigerant in the refrigerant pipe is performed by forcibly circulating the high pressure refrigerant by the operation of the compressor to the condenser and the evaporator communicating with each other through the refrigerant pipe by the operating pressure of the compressor.

In addition, the refrigerant circulating through the refrigerant pipe constituting the refrigerant cycle through the interaction of each component as described above is operated to freeze and cool the inside of the refrigerator.

However, since the compressed refrigerator as described above has many necessary parts, the manufacturing process and assembly process are not only complicated, but also increase the manufacturing cost, and the volume of the refrigerator is excessive compared to the internal space in which food can be stored. There is a problem in that it is inconvenient to carry and install the refrigerator.

As shown in FIG. 1, in the refrigerator of the refrigerator to compensate for the above problems, the thermoelectric device 10 employing a peltier effect in which the flow direction of the heat flow is determined in the same direction as the current flow direction is shown. Is coupled to the coupling groove 21 formed at the upper end of the cabinet 20, the heat dissipation fin 30 coupled to one end of the cabinet 20 so as to be in contact with one surface of the thermoelectric element 10, and the thermoelectric element 10. The aluminum block 40 is coupled to the other side of the heat conduction cooling heat is transferred from the thermoelectric element 10, and the cooling fin receives the cooling heat from the aluminum block 40 to supply the low-temperature air required for cooling in the refrigerator (50) It is composed of

The thermoelectric element 10 employed in the electronic refrigerator is made of a junction of two different metals. When a current flows in the thermoelectric element 10, thermal energy is absorbed at one junction and radiated to another junction. Since the flow of heat flows from the cooling fins 50 contacted to both surfaces of the thermoelectric element, respectively, to the heat dissipation fins 30, the freezing and refrigerating effects of the refrigerator are obtained.

That is, the thermoelectric device 10 as described above uses a peltier effect in which a heat flow flows from the inside to which the heat dissipation fins 30 are coupled to the inside of the aluminum block 40. By applying a current to the device 10, a flow direction of heat flow is formed from the cooling fins 50 to the heat dissipation fins 30, and heat is released from the inside to the outside to operate at low temperatures.

However, the cooling device of the refrigerator as described above has a structure for cooling the heat dissipation fins 30 by air in the air, and thus does not effectively suck high heat generated from the outer surface of the thermoelectric element 10. Due to the limitations, the cooling efficiency of the refrigerator becomes a factor.

On the other hand, in order to improve the heat dissipation of the heat dissipation fin 30 as described above, although a predetermined blowing fan is installed at an adjacent position of the heat dissipation fin 30, the air in the air is a heat dissipation fin because the temperature is constant. The amount of heat absorbed from 30 is also constant, so that a separate heat dissipation device is required.

The present invention has been made to solve the above problems, and has the following object.

First, a heat flow path for heat dissipation of the thermoelectric element is formed at an end of the heat dissipation fin, and a fluid tank and a fluid pump for supplying and circulating fluid through the flow path are provided at a predetermined position in the refrigerator, thereby forcing the heat dissipation fin through the forced circulation of the fluid. Heat dissipation secondary. In addition, by providing a plurality of coil capacitors extending from the fluid pipe and an auxiliary heat dissipation pipe formed to expand the heat dissipation area of the fluid pipe, the heat dissipated fluid is reduced to a temperature below a predetermined temperature by passing through the flow path of the heat dissipation fin. An object of the present invention is to provide a refrigerator of a refrigerator having an improved structure such that the heat flow of the device is smooth and the cooling efficiency of the cooling fin is increased.

Second, by adopting the Peltier effect by the thermoelectric element, the electronic cooling method, which proceeds with cooling and heat dissipation, reduces the number of parts compared to the compressed refrigerator and shortens the manufacturing and assembly processes, thereby reducing the production cost of the refrigerator. The object is to provide an improved refrigerator cooling device.

Third, by adopting the electronic cooling method, the number of parts required is reduced, and the repair and maintenance work is easy when the refrigerator breaks down, and the power consumption is reduced by the thermoelectric element cooling by supplying current from the power source, thereby reducing the economic cost. It is an object of the present invention to provide a refrigerator of the refrigerator having an improved structure.

1 is a cross-sectional view showing a cooling apparatus of a conventional refrigerator;

2 is a cross-sectional view showing a cooling apparatus of the present invention refrigerator;

Figure 3 is a block diagram showing the operation relationship between the major components constituting the cooling apparatus of the present invention refrigerator.

* Explanation of symbols for main parts of the drawings

100 ... cabinet 110 ... trauma

120 ... Inner 130 ... Combined Groove

200 ... thermoelectric modul 300 ... coldsink

400 Heatsink 410,420 Fluid exit

500 fluid tank 600 fluid pipe

610 auxiliary heat dissipation pipe 700 fluid pump

800 ... coil capacitor 900 ... blowing fan

In order to achieve the above object, the refrigerator of the present invention includes a coupling groove formed at an upper end of a thick plate cabinet that penetrates the outer box and the inner box of the refrigerator, and is coupled to the coupling groove and flows of heat according to the current flow direction. A thermoelectric element having a direction formed thereon, a cooling fin coupled to one end of the inner phase to be in contact with one side of the thermoelectric element, and a cooling fin for dissipating heat in the furnace to the thermoelectric side; and one end of the outer shell to be in contact with the other side of the thermoelectric element. A heat dissipation fin that is in contact with the heat suction element and has a fluid outlet at one end thereof, a fluid supply means for circulating a predetermined fluid through the fluid outlet, and a heat dissipation fin provided between the heat dissipation fin and the fluid supply means. It characterized in that it comprises a heat radiating means for radiating the fluid passing through.

The fluid supply means is provided at a predetermined position of the refrigerator and stores a fluid tank in which a predetermined amount of fluid is stored, a fluid pipe communicating the fluid inlet of the fluid tank with the heat dissipation fin, and the fluid pipe between the fluid tank and the heat dissipation fin. And a fluid pump connected to the fluid circulation.

In addition, the radiating means is provided with a predetermined coil capacitor at one end of the fluid pipe between the fluid outlet of the radiating fin and the fluid tank,

The fluid is heated to a high temperature while passing through the heat radiating fin has a structure to release heat while passing through the coil capacitor.

In addition, the heat dissipation means is provided with an auxiliary heat dissipation pipe formed by bending a plurality of one end of the fluid pipe, has a structure that the heat of the fluid circulated into the fluid pipe is sufficiently dissipated.

The cooling device of the present invention refrigerator configured as described above heats the thermoelectric element by air in the air by the heat radiation fins exposed to the outside of the refrigerator and forcibly fluids the fluid from the fluid tank and the fluid pump through a flow path formed at one end of the heat radiation fins. By circulating the heat radiation fins to secondary heat dissipation, the heat flow rate of the thermoelectric element is increased to improve the heat dissipation of the refrigerator.

In addition, through the coil capacitor and the auxiliary heat dissipation pipe installed at one end of the fluid pipe between the heat dissipation fin and the fluid tank, the heat rising to the high temperature is radiated to the low temperature fluid by the heat dissipation fin. Has the characteristic of being raised.

Hereinafter, a preferred embodiment of a cooling apparatus of a refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

2 and 3 schematically illustrating a cooling apparatus of the present invention, the present invention provides a coupling groove 130 at an upper end of the thick plate cabinet 100 so as to pass through the outer box 110 and the inner box 120 of the refrigerator. And a thermoelectric element 200 in which the flow direction of the heat flow is formed according to the current flow direction is seated and coupled to the coupling groove 130.

In addition, one end of the inner groove 120 in which the coupling groove 130 is formed is provided with a cooling fin 300 that cools the inside of the refrigerator by contacting one side surface of the thermoelectric element 200 to release heat to the thermoelectric element 200 side.

In addition, one end of the outer wound 110, the coupling groove 130 is formed is provided with a heat dissipation fin 400 that is in contact with the other side of the thermoelectric element 200 to inhale heat to radiate heat to the outside, one end of the heat dissipation fin 400 A flow path having fluid inlets 410 and 420 is formed in the channel.

And the fluid supply means for circulating a predetermined fluid through the fluid inlet (410, 420), and the heat dissipation means provided between the heat dissipation fin 400 and the fluid supply means to dissipate the fluid passing through one end of the heat dissipation fin 400 of the refrigerator Is provided in a predetermined position has a structure to improve the heat dissipation performance of the heat dissipation fin 400.

In addition, the fluid supply means as described above includes a fluid tank 500 in which a predetermined amount of fluid is installed and provided with a predetermined space provided between the outer box 110 and the inner box 120 of the lower end of the refrigerator, and the fluid tank 500. And a fluid pipe 600 which is provided to communicate the fluid inlets 410 and 420 of the heat dissipation fin 400 and serves as a circulation path of the fluid, and at one end of the fluid pipe 600 between the fluid tank 500 and the heat dissipation fin 400. It is provided with a fluid pump 700 for forced circulation of the fluid.

In addition, the heat dissipation means is provided with a predetermined coil capacitor 800 at one end of the fluid pipe 600 between the fluid outlet 410 of the heat dissipation fin 400 and the fluid tank 500, the heat dissipation fin 400 The fluid is heated to a high temperature while passing through the coil capacitor 800 has a structure to release heat.

On the other hand, the heat dissipation means further has an effect of extending the length of the fluid pipe 600 by further installing an auxiliary heat dissipation pipe 610 formed by bending a plurality of at one end of the fluid pipe 600, Heats the air in the air to the heat dissipation fin 400 by installing a blowing fan 900 at one end of the outer case 110 so as to sufficiently dissipate heat from the circulating fluid and adjacent to the heat dissipation fin 400. By doing so, it is preferable to actively use air in the atmosphere to increase the heat radiation effect of the heat radiation fins 400.

The cooling apparatus of the refrigerator according to the present invention configured as described above operates as follows.

When a predetermined current is applied to the thermoelectric element 200 by the peltier effect in which the flow direction of the heat flow is determined according to the flow of the current, the flow direction of the heat flow from the inner side to the outer side of the thermoelectric element 200 is changed. As it is formed, the suction and release of heat from the cooling fin 300 toward the radiating fin 400 occurs at the same time.

That is, the thermoelectric element 200 sucks heat from the internal space of the refrigerator through the cooling fin 300 to radiate heat to the outside through the heat radiation fin 400.

Then, the fluid is supplied from the fluid tank 500 to the heat dissipation fin through the flow path formed at one end of the heat dissipation fin 400, and by forcibly circulating the fluid by the fluid pump 700, rapid heat dissipation of the heat dissipation fin 400 proceeds. The flow of heat flows through both sides of the 200 is smooth, so that the cooling operation of the refrigerator proceeds actively.

In addition, the heat dissipation action of the fluid rises to a high temperature while passing through the heat dissipation fin through the coil capacitor 800 provided at one end of the fluid pipe 600 between the heat dissipation fin 400 and the fluid tank 500, thereby increasing the temperature of the fluid. It is possible to improve the heat dissipation effect of the heat dissipation fin 400 by keeping the low, and also to the flow path of the heat dissipation fin by the auxiliary heat dissipation pipe 610 which is bent in a plurality at one end of the fluid pipe 600 to enlarge the heat insulating area. It is operated to maintain the best heat dissipation of the fluid circulated through it.

The cooling apparatus of the present invention refrigerator configured as described above has the following advantages.

First, a flow path for heat dissipation of the thermoelectric element 200 is formed at an end of the heat dissipation fin 400, and a fluid tank 500 and a fluid pump 700 for supplying and circulating fluid through the flow path have a predetermined position in the refrigerator. By providing to the heat dissipation fin 400 through the forced circulation of the fluid, and further bent in a plurality of coil capacitor 800 and extending from the fluid pipe 600 is formed to expand the heat dissipation area of the fluid pipe 600 The heat dissipation pipe 610 is provided to smooth the heat flow of the thermoelectric element 200 by cooling the fluid taken away while passing through the flow path of the heat dissipation fin 400 to a predetermined temperature or less, and at the same time the cooling fin 300. This has the effect of increasing the cooling efficiency.

Second, by adopting the electronic cooling method of cooling and heat dissipation by applying the peltier effect by the thermoelectric element 200, the number of parts is smaller and the manufacturing process and the assembly process are shorter than that of the compressed refrigerator. The production cost is reduced.

Third, the number of parts required is reduced by adopting the electronic cooling method, the repair and maintenance work is easy when the refrigerator breaks down, and the power consumption according to the operation of the refrigerator by the thermoelectric element 200 to supply the current from the power supply to perform the cooling operation. Has the effect of reducing the economic cost.

On the other hand, the present invention as described above, of course, various modifications can be made without departing from the scope of the technical idea of the present invention.

Claims (4)

Coupling grooves formed in the upper end of the thick plate cabinet penetrating the outer and inner wounds of the refrigerator; A thermoelectric element seated and coupled to the coupling groove, the flow direction of the heat flow being formed according to the flow direction of the current; A cooling fin coupled to one end of the inner phase to be in contact with one side of the thermoelectric element and dissipating heat in the furnace to the thermoelectric side; A heat dissipation fin coupled to one end of the outer shell to be in contact with the other side of the thermoelectric element, the heat being sucked from the thermoelectric element, and a flow path having a fluid outlet at one end; Fluid supply means for circulating a predetermined fluid through the fluid inlet; And a heat dissipation means installed between the heat dissipation fin and the fluid supply means and dissipating the fluid passing through the heat dissipation fin. According to claim 1, The fluid supply means, the fluid tank is provided at a predetermined position of the refrigerator and stores a predetermined amount of fluid; A fluid pipe communicating the fluid tank with the fluid inlet of the heat dissipation fin; And a fluid pump connected to one end of the fluid pipe to force circulation of the fluid. The method of claim 1, wherein the heat radiating means, a predetermined coil capacitor is provided at one end of the fluid pipe between the fluid outlet of the heat radiating fin and the fluid tank, Cooling apparatus of the refrigerator characterized in that the fluid is heated to a high temperature while passing through the heat radiating fins to pass heat through the coil capacitor. According to claim 1 or 3, wherein the heat dissipation means is provided with an auxiliary heat dissipation pipe is formed by bending a plurality of one end of the fluid pipe, Cooling apparatus of the refrigerator, characterized in that to dissipate heat from the fluid circulated into the fluid pipe.