KR20000000794U - Refrigerator safety device - Google Patents

Abstract

The disclosed safety device includes an ice crushing motor for crushing ice produced in a refrigerator having an ice maker and a dispenser for discharging the ice, a dispenser solenoid for returning the dispenser to the original state when the dispenser discharges ice; When an inductive load such as a cube solenoid that selects ice cubes and ice cubes is overheated, the power supply is cut off to prevent a safety accident.

When the control means operates a plurality of inductive loads, the AC power is supplied to the plurality of inductive loads through a temperature detection switch such as a bimetal switch that is turned on and off depending on the temperature. The temperature detection switch shuts off and the AC power supply when the overheating occurs, and the temperature detecting switch has the least resistance value among the inductive loads, and thus the inductive load that overheats the fastest when an abnormal voltage and overvoltage are applied. Install in contact with.

Description

Refrigerator safety device

The present invention is a refrigerator having an ice maker (ice maker) for producing ice and a dispenser (dispenser) for discharging the produced ice, the power supply is cut off when the inductive load is overheated so that a safety accident does not occur It relates to the safety device of the refrigerator.

In general, many users who use a refrigerator include water in ice-making containers when ice is prepared and put it in a freezer of a refrigerator to freeze water with cold in a freezer.

And when ice is manufactured, the container for ice manufacture is taken out of a freezer compartment, and the manufactured ice is isolate | separated from the container for ice manufacture.

However, manufacturing and separating the ice as described above has given a lot of inconvenience and inconvenience to the user.

Therefore, many refrigerators have ice makers and dispensers installed in the freezer compartment, and the ice maker automatically prepares the ice in the freezer compartment, and the produced ice is discharged to the outside.

1 is a circuit diagram showing a dispenser driver equipped with a conventional safety device.

As shown therein, the cube switch 1 and the cube solenoid 2 are connected in series between the power supply terminals A and B to which the AC power source AC is applied.

After the power supply terminal A is connected to the power supply terminal B through the bimetal switch 4 and the ice crushing motor 5 which are connected in series after the switch 3 for the dispenser, the retarder connected in series. (6) and the dispenser return solenoid (7) are connected to the power supply terminal (B).

The conventional dispenser driver configured as described above connects the dispenser switch 3 when the user discharges the ice produced by the ice maker in the state in which the AC power source AC is applied to the power supply terminals A and B. FIG.

Then, the AC power source AC is applied to the ice grinding motor 5 through the dispenser switch 3 and the bimetal switch 4, and the AC power source AC is supplied through the dispenser switch 3 to the retarder ( 6) is applied.

Therefore, the ice grinding motor 5 is driven to crush and discharge the ice produced by the ice maker.

At this time, when the ice crushing motor 5 is driven and overheated above the predetermined temperature set by the bimetal switch 4, the bimetal switch 4 is opened and the ice crushing motor 5 is stopped.

The size of the ice that is driven by the ice grinding motor 5 to be crushed and discharged is determined by the driving of the solenoid 2 for the cube.

That is, when a user connects the cube switch 1, the AC power source AC is applied to the cube solenoid 2 through the cube switch 1, so that the cube solenoid 2 is driven and the discharge passage of the ice is reduced. Finely crushed ice is discharged.

In addition, when the cube solenoid 2 is not driven because the cube switch 1 is not connected, the ice discharge passage is not reduced and largely fragmented ice is discharged.

In this state, when the discharge of ice is completed and the set time of the retarder 6 has elapsed, the dispenser return solenoid 7 is driven in accordance with the output signal of the retarder 6 so that the dispenser returns to its original state.

According to this conventional technique, the bimetal switch 4 is connected in series to the ice crushing motor 5 so that the bimetal switch 4 when the ice crushing motor 5 is overheated due to the application of an abnormal voltage and an overvoltage, or the like. ) By opening the AC power (AC) to stop the operation of the ice crushing motor (5) to prevent damage, and the occurrence of safety accidents such as the occurrence of fire due to overheating of the ice crushing motor (5) It is prevented beforehand.

The component that overheats due to the application of the abnormal voltage and the overvoltage while performing a predetermined operation, the ice crushing motor 5, the cube solenoid 2 and the dispenser return solenoid 7 is overheated.

However, the above-described conventional technique can only prevent the occurrence of a safety accident by providing a bimetal switch 5 in the ice grinding motor 5, and the solenoid 2 for the cube and the solenoid 7 for returning the dispenser are overheated. The cube solenoid (2) and the dispenser return solenoid (7) are damaged due to overheating due to the application of abnormal voltage and overvoltage, and the deformation of the surrounding structure is frequently caused as well. There was a problem that occurs.

Therefore, the purpose of the present invention is to determine whether overheating occurs in inductive loads such as the solenoid for cubes and the solenoid for dispensers, as well as the motor for ice crushing, and in case of overheating, stops the operation of the inductive load and generates a safety accident. It is to provide a safety device of the refrigerator that prevents in advance.

According to the safety device of the present invention for achieving the above object, when the control means operates a plurality of inductive loads, the temperature of a bimetal switch or the like in which the AC power is turned on and off depending on the temperature of the plurality of inductive loads. In order to be supplied through a detection switch, the temperature detection switch turns off the AC power supply when the inductive load is overheated.

The temperature detection switch is installed in contact with any one of a plurality of inductive loads. Preferably, the inductive load that is overheated fastest when an abnormal voltage and an overvoltage are applied, that is, has the least resistance value. Install in contact with inductive loads.

1 is a circuit diagram showing a dispenser driver equipped with a conventional safety device,

Figure 2 is a circuit diagram showing a dispenser driver with a safety device of the present invention.

* Description of the symbols for the main parts of the drawings *

11: ice crushing motor 12: dispenser return solenoid

13: solenoid for the cube 14: control means

15: temperature detection switch 141: dispenser switch

142: delay unit 143: switch for the cube

AC: AC power A, B: power supply terminal

Hereinafter, a safety device of the refrigerator of the present invention will be described in detail with reference to the accompanying drawings of FIG. 2.

Figure 2 is a circuit diagram showing a dispenser driver with a safety device of the present invention.

Here, numerals 11 to 13 are inductive loads, numeral 11 is an ice grinding motor, numeral 12 is a dispenser return solenoid, numeral 13 is a cube solenoid.

Reference numeral 14 denotes control means for controlling an operation by applying an AC power source AC to the ice crushing motor 11, the dispenser return solenoid 12 and the cube solenoid 13, and controlling the operation. It is a temperature detection switch, such as a bimetal switch which cuts off AC power supply AC when the motor 11, the dispenser return solenoid 12, and the cube solenoid 13 overheat.

The control means 14, the temperature detection switch 15 is connected to the ice crushing motor 11 through the dispenser switch 141, and the connection point is a solenoid for the dispenser return through the retarder 142 It is connected to (12).

The temperature detection switch 15 is also connected to the cube solenoid 13 via a cube switch 143.

In the safety device of the present invention configured as described above, the AC power source AC is applied to the power supply terminals A and B, and the induction of the ice crushing motor 11, the dispenser return solenoid 12, and the cube solenoid 13 is performed. When the user connects the dispenser switch 141 of the control means 14 to discharge the ice produced by the ice maker while the temperature load is not overheated and the temperature detection switch 15 is connected, the AC power supply (AC) ) Is applied to the ice grinding motor 11 and the retarder 142 through the temperature detection switch 15 and the switch 141 for the dispenser.

Then, the ice crushing motor 11 is driven to crush and discharge the ice produced by the ice maker.

Here, the size of the ice to be crushed and discharged by driving the ice grinding motor 11 is determined according to the driving of the cube solenoid 13, when the user connects the cube switch 143 AC power (AC) Since it is applied to the cube solenoid 13 through the temperature detection switch 15 and the switch 143 for the cube, the cube solenoid 13 is driven, the discharge passage of the ice is reduced, the finely crushed ice is discharged, the switch for the cube 143 If the solenoid 13 for the cube is not driven because the cube is not connected, the ice discharge passage is not reduced, and largely fragmented ice is discharged.

In this state, when the discharge of ice is completed and the set time of the retarder 142 has elapsed, the dispenser return solenoid 12 is driven according to the output signal of the retarder 142 so that the dispenser returns to its original state.

Among the inductive loads of the ice crushing motor 11, the dispenser return solenoid 12 and the cube solenoid 13 in this state of operation, the inductive load provided with the temperature detection switch 15 is above a set temperature. When overheated, the temperature detection switch 15 detects an overheating of the inductive load and opens it, whereby the AC power source AC is shut off, so that the operations of the plurality of inductive loads are all stopped to prevent damage.

Here, the temperature detection switch 15 is installed in any one of a plurality of inductive loads to detect overheating.

For example, an inductive load having a low resistance value is the fastest overheating when an abnormal voltage and an overvoltage are applied, and the temperature detection switch 15 is installed in the fastest overheating inductive load to detect overheating.

On the other hand, in the above, when the inductive load provided in the dispenser, that is, the ice crushing motor 11, the dispenser return solenoid 12 and the cube solenoid 13 overheats, the temperature detection switch 15 is opened to alternating current. As an example, the power supply AC is blocked and prevented from overheating.

In carrying out the present invention, the present invention is not limited thereto, and it detects whether various inductive loads provided in the refrigerator are overheated, and in the event of overheating, one bimetal switch is opened to cut off the AC power of the entire inductive load. It can also be configured to prevent.

As described above, the present invention prevents damage to the inductive load due to overheating by stopping the operation of the entire inductive load while one temperature detection switch is opened when overheating occurs in the inductive load provided in the refrigerator. Of course, safety accidents such as the occurrence of fire can be prevented in advance.

Claims (5)

A plurality of inductive loads; Control means for driving by applying AC power to the inductive load; And And a temperature detecting switch for detecting whether an overheat of the inductive load is overheated and for shutting off an AC power when an overheat is detected. The method of claim 1, wherein the inductive load; A refrigerator safety device, characterized in that the ice grinding motor of the dispenser, the solenoid for returning the dispenser and the solenoid for the cube. The method of claim 1 or 2, wherein the control means; A dispenser switch for driving the ice grinding motor according to a user's operation; A delay unit for driving the dispenser return solenoid after a predetermined time elapses when the dispenser switch is turned on; And Safety device of the refrigerator, characterized in that consisting of a switch for the cube to drive the cube solenoid according to the user's operation. The method of claim 1, wherein the temperature detection switch; Safety device for a refrigerator, characterized in that the bimetal switch. The method of claim 1 or 4, wherein the temperature detection switch; A safety device of a refrigerator, characterized in that overheating is detected by installing in an inductive load having a lowest resistance value among a plurality of inductive loads.