KR0135256Y1 - Electric heater for defrosting of freezer - Google Patents

Abstract

The present invention relates to a heat transfer heater for defrost of the refrigerating device, and is made of a material having excellent heat transfer efficiency, the heat transfer pipe of the structure in which a space portion of a predetermined diameter is formed along the longitudinal center line therein, and the heat transfer pipe It is installed in the space portion of the interior, and generates heat while being heated in accordance with the application of current, the both ends of the heating coil connected to the connection terminal, the insulator applied between the heating coil and the inner peripheral surface of the heating pipe, the heating pipe In the defrosting heat transfer heater of the refrigerating device consisting of a wire drawn to both ends of the heating wire connected to the connecting terminal connected to both ends of the heating coil, the heat pipe is gradually reduced in the outer diameter toward the both ends from a predetermined position close to both ends thereof; The tapered portion of the shape is formed, the knurled portion is formed on the outer surface of the tapered portion, On the outer circumferential surface of the tapered portion it is to improve the installation workability for the refrigerating device by having the waterproof cap integrally molded to have the same outer diameter as the outer diameter of the heat transfer pipe.

Description

Heat transfer heater for defrost of refrigeration unit

1 is a perspective view showing the installation state of the defrost heat transfer heater of the general refrigerating device.

Figure 2 is a side cross-sectional view showing a defrost heat transfer heater of the conventional refrigeration apparatus.

Figure 3 is a perspective view showing a defrosting electric heater of the refrigerating device according to the present invention.

Figure 4 is a side cross-sectional view of the defrost heat transfer heater of the refrigerating device according to the present invention.

* Explanation of symbols for main parts of the drawings

18: heat transfer pipe 20: connection terminal

22: heating coil 24: insulator

26: power cord 42: taper

44: Knurling part 46: waterproof cap

The present invention relates to a heat transfer heater for defrost of a refrigerating device, and more particularly, it is used to melt frost formed on the outer surface of the refrigerating device installed on an ice maker or a freezing device of a refrigerator for home or business. In order to apply electric current to the internal heating coil in the electric heater, the installation cap for the refrigerating device is formed by allowing the waterproof cap to be molded to the same outer diameter as the electric heating pipe on the outer surfaces of both ends of the electric heating pipe into which the wires are drawn from the outside. The present invention relates to a defrosting electric heater for a refrigerating device.

In general, as shown in FIG. 1, the refrigerator 10 of the ice maker or the refrigerator for home or business uses a plurality of thin endothermic fins 12 having excellent heat transfer efficiency and is installed at a tight interval over a certain distance range. Each of the heat absorbing fins 12 has a structure in which a refrigerant circulation pipe 14 is penetrated through a closed loop shape, and is forcibly circulated through the refrigerant circulation pipe 14 together with compressed air generated from a conventional compressor. When the heat passing through the heat absorbing fins 12 installation portion, the heat exchange between the heat absorbing fins 12 and the surrounding air is cooled by the refrigerant and the temperature of the space in which the heat absorbing fins 12 are installed rapidly. The ice is formed by the lowering principle.

However, in such a conventional refrigeration apparatus, dew is formed on the outer surface of the endothermic fin 12 in a process of performing heat exchange between the endothermic fin 12 cooled by the circulating refrigerant and the surrounding air. The dew formed in this way forms frost while freezing by the low temperature of the heat absorbing fin 12. As the operating time of the refrigeration cycle elapses, the dew formed on the outer surface of the heat absorbing fin 12 is reduced. When the thickness becomes thick, the heat exchange between the heat absorbing fin 12 and the surrounding air becomes poor, which causes a problem that the freezing effect per unit time is significantly lowered.

Accordingly, in recent years, a plurality of heat transfer heaters 16 for defrosting are installed in accordance with the installation direction of the heat absorbing fins 12 constituting the refrigerating device 10, and if necessary, current is applied to the heat transfer heater 16 for a predetermined time. By applying the heat to generate the frost formed on the outer surface of the heat absorbing fin 12 is to be removed by the heat generated from the heat transfer heater (16).

On the other hand, the conventional defrost heat transfer heater 16 installed in such a refrigeration device is made of a material having excellent heat transfer efficiency, as shown in Figure 2, the space portion of the predetermined diameter along the longitudinal center line therein The heat transfer pipe 18 having the formed structure and the heating pipe 18 are inserted into the space portion on the heat transfer pipe 18 and generate heat while being heated according to the application of an electric current, and both ends of the heating coil 22 to which the connection terminal 20 is connected. And, the insulator 24 is applied between the heating coil 22 and the inner circumferential surface of the heat transfer pipe 18, and the connection terminal is introduced into both ends of the heat transfer pipe 18 and connected to both ends of the heat generating coil 22 ( 20 connected to both ends of the heating coil 22 and the wire 26 connected to both ends of the heating coil 22 and the wire 26 connected to the outer peripheral surface of the heat transfer pipe 18. To prevent water from seeping It comprises a watertight cap (28).

However, in the structure of the defrosting heat transfer heater of the conventional refrigerating device, when the outer diameter of the waterproof cap 28 is formed larger than the outer diameter of the heat transfer pipe 18 is covered on both ends of the heat transfer pipe 18 Between the inner end of the waterproof cap 28 and the outer diameter of the heat transfer pipe 18, a step 30 having a height corresponding to the thickness of the waterproof cap 28 is inevitably formed. In the case where the step 30 is formed between the outer surface of 18 and the inner end of the waterproof cap 28, the heat transfer heater 16 is mounted on the heat absorbing fin 12 of the refrigerating device 10. The installation hole 32 should be formed larger than the outer diameter of the heat transfer pipe 18, and therefore, there exists a problem that the installation workability becomes very bad.

The present invention is to solve such a conventional problem, the purpose of the wire is drawn from the outside to apply a current to the internal resistance coil in the electric heater used to melt the frost formed on the outer surface of the refrigeration device It is to provide a defrost heater of a new type of refrigerating device to improve the installation workability of the refrigeration device by allowing the waterproof cap to be molded to the same outer diameter as the heat transfer pipe on the outer surface of both ends of the heat transfer pipe. .

In order to achieve the above object, the present invention is made of a material having excellent heat transfer efficiency, the heat transfer pipe of the structure in which a space portion of a predetermined diameter is formed along a longitudinal center line therein, and is fitted into the space portion inside the heat transfer pipe. And generates heat while being heated according to the application of a current, and at both ends thereof, a heating coil connected with a connection terminal, an insulator applied between the heating coil and an inner circumferential surface of the heating pipe, and drawn into both ends of the heating pipe, thereby generating heat. In the defrosting heat transfer heater of the refrigerating device consisting of a wire connected to the connecting terminal connected to the both ends of the coil, the heat transfer pipe is formed with a tapered portion of the shape that the outer diameter decreases toward the both ends from a predetermined position close to both ends thereof, A knurled portion is formed on the outer surface of the tapered portion, while the outer circumference of the tapered portion is On characterized made to have the same outer diameter as the outer diameter of the heat transfer pipe by the watertight cap is molded integrally with the structure.

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

3 is a perspective view showing a defrost heat transfer heater of the refrigerating device according to the present invention, the defrost heat transfer heater 40 of the refrigerating device according to the present invention is made of a material having excellent heat transfer efficiency, the inner longitudinal center line Accordingly, the heat pipes 18 and the heat pipes 18 having a predetermined diameter are formed to penetrate into the spaces inside the heat pipes 18, and generate heat while being heated according to the application of electric current. 20 is connected to the heating coil 22, the insulator 24 applied between the heating coil 22 and the inner circumferential surface of the heating pipe 18, and both ends of the heating pipe 18 are led to the heating coil ( In the defrosting heat transfer heater of the refrigerating device consisting of the electric wire 26 connected to the connecting terminal 20 connected to both ends of 22, the heat transfer pipe 18 is gradually moved from a predetermined position close to both ends thereof. A tapered portion 42 having a shape of gradually decreasing outer diameter is formed, and a knurled portion 44 is formed on the outer surface of the tapered portion 42, while the heat transfer pipe 18 is formed on the outer circumferential surface of the tapered portion 42. It shows that the waterproof cap 46 is integrally molded so as to have the same outer diameter as).

In this invention, the tapered portion 42 formed at both ends of the heat transfer pipe 18 may be different depending on the total length of the heat transfer heater 40, but is formed in the length range of approximately 60-100mm It is preferable.

On the other hand, in the present invention, the waterproof cap 46 molded on the outer peripheral surface of the tapered portion 42 is made of a rubber material, in addition to being formed by the molding can also be formed by a mechanical crimping method.

4 is a side cross-sectional view of the defrosting electric heater 40 of the refrigerating device according to the present invention, the heating coil 22 is inserted into the space formed in the heat transfer pipe 18, the heating coil 22 An electric wire 26 drawn from the outside is connected to the connection terminal 20 connected to both ends of the taper portion having a shape in which the outer diameter gradually decreases from a predetermined position near both ends of the heat transfer pipe 18 to both ends thereof. 42 is formed, a knurled portion 44 is formed on the outer surface of the tapered portion 42, while a waterproof cap 46 of rubber material is formed on the outer circumferential surface of the tapered portion 42 of the heat transfer pipe 18. The molded state is shown to have the same outer diameter as the outer diameter.

According to the present invention, a tapered portion is formed in which the outer diameter gradually decreases toward both ends over a predetermined length range of both ends of the heat transfer pipe constituting the defrosting heat transfer heater of the refrigerating device, and on the outer peripheral surface of the tapered part As the waterproof cap of the rubber material is integrally molded, the stepped portion of the structure in which the conventional waterproof cap is covered is not formed. Therefore, when the heat heater is installed on the heat absorbing pin constituting the refrigerating device, the installation hole is larger than the outer diameter of the heat pipe. There is no need to form, there is an effect that the installation workability is significantly improved, as a result, there is an effect that the flow of the heat transfer heater is not generated in the state installed in the refrigeration apparatus.

Claims (1)

It is made of a material having excellent heat transfer efficiency, and is fitted to the heat pipe 18 having a structure in which a space part of a predetermined diameter is formed along a longitudinal center line therein, and fitted into a space part inside the heat pipe 18, and applying current. And generates heat while being heated, and at both ends thereof, a heat generating coil 22 to which the connection terminal 20 is connected, and an insulator 24 applied between the heat generating coil 22 and the inner circumferential surface of the heat transfer pipe 18; In the defrosting heat transfer heater of the refrigerating device consisting of an electric wire 26 drawn into both ends of the heat transfer pipe 18 and connected to the connection terminal 20 connected to the hem end of the heating coil 22, the heat transfer pipe ( 18, a tapered portion 42 is formed in which the outer diameter gradually decreases from a predetermined position close to both ends thereof, and a knurled portion 44 is formed on the outer surface of the tapered portion 42, Of the tapered portion 42 The defrost heat transfer heater of the refrigerating device, characterized in that the waterproof cap 46 is integrally molded on the outer peripheral surface to have the same outer diameter as the outer diameter of the heat transfer pipe (18).