KR200158094Y1 - Defrost controller of a refrigerator - Google Patents

Abstract

The present invention relates to an assembly of a demetallic regulator integrating a bimetallic defrosting regulator and a thermal fuse, and more particularly, to a defrosting regulator that solves electrical instability caused by the effects of insulation and withstand voltage between the bimetallic defrosting regulator and the temperature fuse. It is about assembly.

The defrost regulator assembly includes a lead insulator connected between the thermal fuse and the terminal of the defrost regulator to be out of the body of the defrost regulator, and the insulation tube of the wire connected between the other terminal of the thermal fuse and the heater is connected to the body of the defrost regulator. It is configured to be located in the lower part, while solving the electrical instability (short or unnecessary configuration of the conductive path) caused by the use of the conventional insulating tube, while reducing the cost by improving the workability due to the simplification of the process. have.

Description

Defrost regulator assembly integrating bimetal defrost regulator and thermal fuse

The present invention relates to an assembly of a demetallic regulator integrating a bimetallic defrosting regulator and a thermal fuse, and more particularly, to a defrosting regulator that solves electrical instability caused by the effects of insulation and withstand voltage between the bimetallic defrosting regulator and the temperature fuse. It is about assembly.

1 is a circuit diagram of a general refrigerator.

In a typical refrigerator, as shown in FIG. 1, a refrigerator unit lamp which operates on / off in conjunction with an operation of the power supply unit 5, a refrigerating chamber door switch 10, and the switch 10 that supplies power required for the refrigerator, as shown in FIG. (15), a freezer compartment door switch (20), and a freezer compartment lamp (25) operating on / off in conjunction with the operation of the switch (25).

The current path is controlled so that the temperature controller 35 is turned on / off according to the temperature and energizes the power supplied from the power supply unit 5, and the power supplied from the temperature controller 35 is applied to the cooling circuit for a predetermined time. Defrost timer 40 is included. At this time, the switch switching state of the defrost timer 40 is a state in which the terminal A is connected to the terminal B, and the cooling circuit mentioned above generates cold air by the compressor 50 and the fan motor 30. Refers to the circuit configuration.

After the power is supplied to the cooling circuit through the defrosting timer 40 for a predetermined time, the power applied from the temperature controller 35 is applied to the defrosting circuit by the switching operation of the defrosting timer 40. At this time, the switch switching state of the defrost timer 40 is a state that the terminal (A) is connected to the terminal (C), the above-mentioned defrost circuit is supplied power through the defrost regulator 65 and the thermal fuse (60) And a heater 55 that generates heat.

That is, in the operation circuit of a general refrigerator, as shown in the figure, power is supplied to the cooling circuit or the defrost circuit by the switching operation of the defrost timer 40.

In this way, the power supply to the defrost regulator assembly consisting of a defrost regulator 65 and the temperature fuse 60 to be described in the present invention in the refrigerator constituting the circuit is made as follows.

When power is applied to the defrost circuit through the terminal (A-C) of the defrost timer 40, power is first applied to the defrost regulator (65). And while the power through the defrost regulator 65 is applied to the temperature fuse 60 and the timer (T), the power through the temperature fuse 60 is supplied to the heater 55 to induce heat generation of the heater. The defrost timer T is stopped while the potentials of the input / output terminals of the timer T become equal.

On the other hand, the defrost regulator 65 and the thermal fuse 60 is integrated as shown in Figure 2 is composed of a defrost regulator assembly 70 in one protective tube (73).

As shown in FIG. 3, the thermal fuse 60 is provided with springs 62, 64 and a disk 66 (DISK) between the lead 61 and the lead 67. In the on state, the lead 61 and the lead 67 are connected to each other by the springs 62 and 64 and the disk 66. In the off state, the lead 61 and the lead 67 are separated. .

However, the case 63 surrounding the thermal fuse 60 is made of a non-insulator such as aluminum or copper, and the body 71 of the defrost regulator 65 is also made of a non-insulator such as aluminum or copper. have.

Thus, when the thermal fuse 60 is turned on, power from the lead 61 is transferred to the case 63, and a problem occurs that the power is influenced through the body 71 of the defrost regulator 65. This is because the current flowing through the body 71 of the defrost regulator 65 and the current flowing through the casing 63 of the thermal fuse 60 are different in direction, which may cause breakage of the device due to adverse action. to be.

Therefore, as shown in FIG. 2 of the related art, the thermal fuse 60 and the lead portions 61 and 67 are wrapped with an insulating tube 69 to electrically connect the body portion 71 of the defrost regulator 65. Are separated.

However, when the defrosting regulator assembly 70 is integrated, the insulation tube 69 is missing or the length of the insulation tube 69 is short, resulting in a problem that the insulation role is not properly performed.

In addition, by including the insulating tube 69, the unit price is increased in terms of payment, and there is a problem in that the volume of the defrost regulator assembly 70 is increased.

In addition, the leads 61 and 67 connected to the misleading fuse 60 have a length thereof and are coupled to the defrost regulator 65. Therefore, the lids 61 and 67 may be bent to touch the case 63 of the thermal fuse 60 during handling or in the assembling process according to the integrated configuration of the defrost regulator assembly 70. There was a problem in that unnecessary conduction paths were formed through the case 63 of the thermal fuse 60.

Accordingly, an object of the present invention is to provide a defrost controller assembly capable of electrically separating a lead of a thermal fuse and a body of a defrost controller in a defrost controller assembly integrating a bimetal type defrost controller and a temperature fuse.

Another object of the present invention is to provide a defrost regulator assembly which can electrically separate the lead of the thermal fuse and the body of the defrost regulator in a defrost regulator assembly integrating a bimetal-type defrost regulator and a temperature fuse. .

1 is a circuit diagram of a general refrigerator.

2 is a block diagram of a conventional bimetallic defrost regulator and a thermal fuse.

3 is an internal structure diagram of a thermal fuse.

4 is a block diagram of a defrost regulator assembly integrating a bimeltal defrost regulator and a temperature fuse according to the present invention.

* Explanation of symbols for main parts of the drawings

40: defrost timer 55: heater

60, 89: thermal fuse 65, 97: defrost regulator

70, 90: defrost regulator assembly 63, 87: thermal fuse case

61,83: thermal fuse lead insulator 67, 91: thermal fuse lead

69: insulation tube 73, 81: protection tube

71, 99: defrost regulator case 85: insulation

93 connection 95 Heater wire insulation tube

In order to achieve the above object, the defrost regulator assembly incorporating the bimetallic defrost regulator and the temperature fuse according to the present invention has one terminal of the defrost timer and one terminal of the thermal fuse in common to the one terminal of the bimetallic defrost regulator. In the compressed defrosting regulator assembly, the lead insulation portion connected between the thermal fuse and the terminal of the defrosting regulator is to be out of the body of the defrosting regulator, and the insulation tube of the wire connected between the other terminal of the thermal fuse and the heater Characterized in that configured to be located on the body portion of the defrost regulator.

Defrost regulator assembly incorporating a bimetal type defrost regulator and a thermal fuse according to the present invention, eliminating the conventional insulation tube, and combines the assembly direction of the thermal fuse as opposed to the conventional.

In addition, the present invention, so that the connection portion of the wire and the temperature fuse connected to the bimetal defrost regulator body shelf heater is located, and the lead of the temperature fuse is to leave the body portion of the defrost regulator to implement the insulation of the thermal fuse.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the demetallic regulator assembly integrating the bimetal-type defrost regulator and the temperature fuse according to the present invention.

4 shows a defrost regulator assembly integrating a bimetallic defrost regulator and a temperature fuse according to the present invention. The circuit configuration of the necessary refrigerator will be described with reference to FIG.

Then, referring to FIG. 4, the bimetal-type defrost controller and the connection configuration of the defrost controller assembly integrating the thermal fuse according to the present invention are eliminated, and the thermal fuse 89 may be eliminated. The direction of is mounted opposite to the conventional structure (see FIG. 2).

At the same time, the position is adjusted to use the portion 85 which is basically insulated from the temperature fuse 69, and the electrical short is eliminated by allowing the temperature fuse case 87 to be the same pole instead of the second pole even when power is supplied.

In addition, the connecting portion 93 of the electric wire 95 and the thermal fuse 89 connected to the heater 55 in the body portion of the bimetal-type defrost regulator 97 is positioned, and the lead of the thermal fuse is connected to the connecting portion 93. (91) was shortened and crimped | bonded. And the lead 83 of the thermal fuse (89) connected to the defrosting regulator (97) is to leave the body portion of the defrosting regulator (97), the lead is also shortened to the connection terminal of the defrosting regulator (97) and pressed.

The demetallic regulator assembly incorporating the bimetal type defrosting regulator and the temperature fuse mounted as described above operates in the same manner as in the prior art, and the process is briefly described as follows.

When power is applied to the defrost circuit, the power is applied to the integrated defrost controller 97 through the terminal (ac) of the defrost timer 40, and the power applied through the defrost controller 97 When the thermal fuse 89 is also turned on through the lead 83 and the thermal fuse 89 is also turned on, power is applied to the lead 91 connected by a spring and a disk to the lead 83. 55) Current flows through the wire connected to it.

When the thermal fuse 89 is above a predetermined temperature (about 72 ° C.), the thermal fuse 89 is turned off to protect the device. Therefore, even when the connection state is connected to the opposite state as in the present invention, there is no problem in operation. Does not occur.

In addition, since the leads 83 and 91 connected to both ends of the thermal fuse 89 are shortly formed and crimped at each connecting portion, there is no fear that the leads are bent and connected to the case of the thermal fuse 89. The unnecessary conduction path through the outer metal case of the thermal fuse 89 is not formed.

In particular, the lead 83 connected to the temperature fuse 89 is out of the body portion of the defrost regulator 97 and the lead 83 is formed by a portion 85 that is basically insulated from the temperature fuse 89. By blocking the conduction paths that may be generated between the thermal fuse case 87 and the case 99 of the defrosting regulator, each element can be prevented from electrical instability.

As described above, the defrost regulator assembly incorporating the bimetal type defrost regulator and the thermal fuse according to the present invention has a structure in which the thermal fuse is mounted in reverse with the conventional one in order to ensure stability from a power supply flowing into the case of the thermal fuse, and is conventionally insulated. While solving the factors of electrical instability (short or unnecessary conduction path) caused by the use of the tube, there is an effect that can reduce the cost by improving the workability due to the simplification of the process.

Claims (1)

In an assembly of a defrosting regulator in which a terminal of a defrosting timer and a terminal of a thermal fuse are commonly crimped through a lead to one terminal of a bimetallic defrosting regulator, a lead insulating part connected between the temperature fuse and the terminal of the defrosting regulator is defrosted. A defrost regulator assembly incorporating a thermal fuse and a bimetallic defrost regulator configured to deviate from the body of the controller and to have an insulating tube of a wire connected between the other terminal of the temperature fuse and the heater to be located in the body of the defrost controller.