KR19990017199U - Evaporator Defrost Structure - Google Patents

Abstract

Disclosed is an evaporator defrost structure that reduces the manufacturing cost of a refrigerator by employing a thin thermofoil heater on the rear inner wall of the evaporator and shortening the manufacturing and assembling thereof. This is to defrost the frost generated due to the temperature difference in the refrigerator on the surface of the evaporator installed on the rear inner wall of the freezer compartment, the thermofoil heater is coupled between the evaporator 100 and the inner wall 400 by a predetermined coupling means ( 200) is provided. In addition, the thermofoil heater 200 has a structure in which the aluminum heating wire 220 is zigzag-bonded between a plurality of layers of polyethylene members 210 and the power line 230 extends from the aluminum heating wire 220 so that the current is thermostated. It is applied to the foil heater 200 to emit a predetermined heat. In addition, the coupling means has a seating groove 300 is formed in the inner upper wall 400 behind the evaporator 100 so that the thermofoil heater 200 is seated, and also provided with a predetermined adhesive on the one side of the inner upper wall 400 The foil heater 200 has a structure that is bonded by bonding. The evaporator defrosting structure of the present invention having such a structure can be installed in a narrow space between the evaporator 100 and the inner wall 400, and its structure is simple, so that the manufacturing process and the assembly process are shortened, power is applied and instantaneous. Since the exothermic reaction is fast, the defrosting efficiency is improved.

Description

Evaporator Defrost Structure

The present invention relates to an evaporator defrosting structure. In particular, the thin foil thermofoil heater is adopted on the rear inner wall of the evaporator to improve the defrosting efficiency of the evaporator and to reduce the manufacturing cost of the refrigerator. An improved evaporator defrost structure.

In general, the refrigerator performs the freezing and refrigerating functions through heat exchange with hot air in the high temperature of the low temperature refrigerant circulated through the refrigerant pipe connected to the compressor, the condenser and the evaporator, respectively.

In the refrigerator as described above, the refrigerant circulated by the pressure of the compressor and converted into a state of low pressure and low pressure through the condenser is transferred to hot air in the cold air through heat exchange with hot air in the cold air on the surface of the evaporator installed at the rear of the freezer compartment. Will be converted.

The refrigerant in the evaporator pipe heat-exchanged with the hot air in the refrigerator is sucked back into the compressor and circulated through the refrigerant pipe while forming a refrigeration cycle.

In addition, cold air in the heat exchanged with the low-temperature refrigerant is circulated to the cold air flow path formed around the storage stored in the freezer compartment and the refrigerating compartment through a predetermined cold air flow path formed in the inside of the refrigerator to keep the storage in the fresh store.

The hot air circulated through the cold air flow path in the furnace is sucked into the surface of the evaporator pipe, and the cycle which is converted into cold air through heat exchange with cold air circulating in the evaporator pipe is repeated.

However, in the circulation of the cold air, the hot air passing through the cold air flow path absorbs a large amount of moisture contained in the storage through heat exchange with the storage in the refrigerator and circulates to the surface of the evaporator. Since hot air reaching the pipe surface contains a certain amount of moisture therein, the frost grows on the surface of the evaporator pipe due to the temperature difference between the low temperature refrigerant circulating inside the evaporator pipe and the temperature at the same time. .

As described above, when the frost grows on the surface of the evaporator pipe, the heat exchangeability between the cold air emitted from the evaporator pipe and the air in the air is weakened, so that the heat exchange efficiency of the evaporator is lowered.

In the conventional evaporator defrosting structure for preventing the functional deterioration of the evaporator, as shown in FIG. 1, the defrost heater 20 is installed below the evaporator 10, and the defrost heater 20 is connected to the evaporator 10. The upper and lower covers 21 and 22 are provided at the same time to prevent the leakage of the defrost heater 20 and at the same time to prevent the leakage of the defrost heater 20 can be fixed at the same time and the frost melts and flows down to the defrost heater (20). Has a structure.

By the way, the defrost heater as described above is excessive in volume compared to the amount of heat generated, and the peripheral parts such as covers 21 and 22 for installing the defrost heater 20 are added, so that the number of parts is difficult and difficult to install The assembling process is increased and the assembling work is complicated, which increases the manufacturing cost of the refrigerator.

In addition, since the surface of the defrost heater 20 is formed of glass tubes, the defrost heater 20 may increase the defect rate of the defrost heater due to the breakage of the glass tubes in the manufacturing process and the assembly process. There is a problem in that there is a risk of a safety accident.

In addition, in order to install the defrost heater 20 as described above, since sufficient space around the evaporator 10 must be secured, the space of the freezer compartment and the refrigerating compartment in which the storage is stored due to the expansion of unnecessary space is relatively reduced to the size of the refrigerator. Compared to the storage capacity and the performance of the refrigerator will be a factor.

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

First, the present invention provides an evaporator defrosting structure whose structure is improved to reduce the manufacturing cost of the refrigerator by employing a small thermofoil heater on the rear inner wall of the evaporator to shorten the manufacturing process and the assembly process.

Second, by adopting a thin sheet of thermofoil heater composed of polyethylene and aluminum heating wires, there is no fear of damage due to inadvertent operator's carelessness, thus reducing material costs due to product defects in the manufacturing and assembly process and preventing the risk of safety accidents. Its purpose is to provide an evaporator defrost structure with improved structure.

Third, by adopting a thermofoil heater that can be installed even in a narrow space, the evaporator has been improved so that the storage capacity of the freezer compartment and the refrigerating compartment can be relatively enlarged by increasing the space utilization, and the storage capacity is improved compared to the refrigerator of the same size. The purpose is to provide a defrost structure.

Fourth, the purpose of the present invention is to provide an evaporator defrosting structure whose structure is improved so that power loss is reduced and the defrosting efficiency of the evaporator is improved by adopting a thin thermofoil heater having a rapid heat generation reaction according to the application of current.

1 is a cross-sectional view schematically showing a conventional evaporator defrost structure;

Figure 2 is a partially separated perspective view schematically showing the evaporator defrost structure of the present invention,

Figure 3 is an exploded perspective view schematically showing a thermofoil heater employed in the evaporator defrost structure of the present invention.

* Explanation of symbols for main parts of the drawings

100 ... Evaporator 200 ... Thermofoil Heater

210.Polyethylene member 220.Aluminum heating wire

230 Power cord 300 Seating groove

400.Inner wall

In the evaporator defrosting structure of the present invention for solving the above problems in defrosting the frost generated due to the temperature difference in the high temperature on the surface of the evaporator installed on the rear inner wall of the freezing chamber,

It is characterized in that the thermofoil heater is provided between the evaporator and the inner wall by a predetermined coupling means.

In the thermofoil heater, an aluminum heating wire is zigzag-fused between a plurality of layers of polyethylene members, and a power line is extended from the aluminum heating wire,

When power is applied to the aluminum heating wire from a predetermined power source, defrost heat is generated in the thermofoil heater.

The coupling means forms a predetermined recess in the inner wall of the rear of the evaporator, so that the thermofoil heater is coupled to the recess.

In addition, the coupling means may include a predetermined adhesive, and may be formed in a structure in which the thermofoil heater is bonded to and bonded to the rear of the inner upper wall.

The evaporator defrosting structure of the present invention configured as described above has a small volume and is formed of thin thin plates such as polyethylene, so that the evaporator defrosting structure is easy to install in a narrow space between the evaporator and the inner wall of the inner wall so that a separate installation space is not necessary. It is simple to shorten the manufacturing process and assembly process is characterized by reducing the manufacturing cost of the refrigerator.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 and 3, the evaporator defrosting structure of the present invention is installed on the rear inner wall of the freezer compartment and hot air sucked around the evaporator with water contained in the storage while circulating inside the evaporator 100. The frost grows on the surface of the evaporator 100 due to the mutual temperature difference in the process of exchanging the cold air circulating through the pipe of the low temperature and low pressure refrigerant. The evaporator defrost structure defrosting the frost is the evaporator 100 and the internal wound. It is made by providing a thermofoil heater 200 is coupled between the wall 400 by a predetermined coupling means.

In addition, as shown in FIG. 3, the thermofoil heater 200 is provided with a zigzag of aluminum heating wires 220 between a plurality of layers of polyethylene members 210 to supply power to the aluminum heating wires 220 from a power source. When applied, defrost heat is generated from the aluminum heating wire 220 to the predetermined power line 230 to defrost the frost generated on the surface of the evaporator 100.

In addition, the coupling means forms a predetermined seating groove 300 in which the thermofoil heater 200 is seated on the inner upper wall behind the evaporator 100, and the thermofoil heater 200 in the seating recess 300. It is structured to combine.

On the other hand, the coupling means is provided with a predetermined adhesive, formed in a structure for directly bonding the thermofoil heater 200 to the rear of the inner wall 400, the inner wall to which the thermofoil heater 200 is coupled By simplifying the structure of the 400, it is preferable to shorten the forming process of the inner wall 400 and the assembling process of the thermofoil heater 200.

In the evaporator defrost structure of the present invention configured as described above, a current is applied from a predetermined power source, and defrost heat generated from the aluminum heating wire 220 is transferred to the evaporator 100 surface, whereby frost generated on the evaporator 100 surface is defrosted. It works.

The evaporator defrost structure of the present invention configured as described above has the following advantages.

First, a thin thermofoil heater 200 composed of a polyethylene member 210 and an aluminum heating wire 220 is installed on the rear inner wall 400 of the evaporator 100, thereby manufacturing and assembling the thermofoil heater 200. There is no fear of damage due to worker's carelessness during work, which reduces the cost of materials due to product defects in the manufacturing and assembly process and prevents the risk of worker's safety accident, thus reducing the manufacturing cost of refrigerator.

Second, by employing a thin thermofoil heater 200 on the rear inner wall 400 of the evaporator 100, the manufacturing process and the assembly process is shortened to reduce the number of workers.

Third, the thermofoil heater 200 can be installed in a narrow space between the evaporator and the inner wall 400, so that the width of the space utilization is wider, the space of the freezer compartment and the refrigerating compartment can be relatively expanded, compared to the refrigerator of the same size Has the effect of improving the storage capacity of food.

Fourth, the power loss due to the operation of the refrigerator is reduced by the thin-plate thermofoil heater 200 having a rapid heat generation reaction according to the application of current from a predetermined power source, and the defrosting efficiency of the evaporator 100 is improved.

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)

In defrosting the frost produced by the temperature difference in the refrigerator on the surface of the evaporator installed on the rear inner wall of the freezer compartment, Evaporator defrost structure, characterized in that provided between the evaporator and the inner wall of the thermofoil heater coupled by a predetermined coupling means. The method of claim 1, wherein the thermofoil heater is fused with aluminum heating wire zigzag between a plurality of layers of polyethylene member, the power supply wire is extended from the aluminum heating wire, Evaporator defrost structure characterized in that the defrost heat is generated in the thermofoil heater when the power is applied to the aluminum heating wire from a predetermined power source. 2. The evaporator defrosting structure according to claim 1, wherein the coupling means forms a predetermined seating groove in the inner upper wall behind the evaporator so that the thermofoil heater is coupled to the seating groove. 2. The evaporator defrosting structure according to claim 1, wherein the coupling means includes a predetermined adhesive to adhere the thermofoil heater to the rear of the inner wall.