KR100817940B1 - Compensation circuit for low temperature of refrigerator - Google Patents

Abstract

The present invention relates to a low temperature compensation circuit of a refrigerator capable of increasing the operation rate of a compressor for a refrigerator by using radiant heat such as high temperature. The present invention controls the operating state of the temperature controller while increasing the sensing temperature in the refrigerator by using radiant heat such as the refrigerator when the low temperature phenomenon occurs. At this time, even when the external temperature is low, the compressor can be driven to prevent a decrease in the operation rate of the compressor due to the low temperature.

Refrigerator, compressor, operation rate, low temperature compensation, high

Description

Compensation circuit for low temperature of refrigerator             

1 is a control circuit diagram for low temperature compensation of a conventional refrigerator,

2 and 3 are control circuit diagrams for low temperature compensation in the refrigerator according to the first embodiment of the present invention;

4 and 5 is a control circuit diagram for low temperature compensation in the refrigerator according to a second embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

101: power input unit 103: door switch

105: high light 107: fan motor

109: temperature controller 113: defrost heater

115: compressor 117: overcurrent protector

119 defrosting temperature controller 121 defrosting timer

123: fuse 125: bimetal switch

The present invention relates to a low-temperature compensating circuit of a refrigerator, and more particularly, to a low-temperature compensating circuit of a refrigerator capable of increasing the operation rate of a compressor for a refrigerator by using radiant heat such as high temperature when the external temperature is low.

Since a refrigerator may decay when temperature rises, a refrigerator is a device which forms the space which can hold | maintain a state lower than normal temperature, and controls so that food preservation time can be kept as long as possible. The control of the refrigerator is performed by comparison between the set temperature and the high temperature inside, and the high temperature inside is controlled to be maintained within a range of ± α value of the set temperature.

However, when the outside temperature of the refrigerator is low, especially when the temperature is low, such as winter, the refrigerator is affected by the outside temperature. In addition, if the refrigerator is installed outdoors, the temperature is greatly affected. When the external temperature is lowered below a predetermined value in such an installation state, the operation rate of the refrigerator becomes very low without causing a large difference between the internal temperature of the refrigerator and the set temperature.

This is because when the ambient temperature falls below zero, the operating temperature of the compressor and the fan motor of the refrigerator is drastically reduced because the internal temperature of the refrigerator compartment is also lowered. In particular, in the case of a refrigeration system that controls the supply of cold air in the freezer compartment based on the temperature of the freezer compartment, when the low temperature phenomenon of the cold compartment is not supplied to the freezer compartment, there is a problem that damages the food stored in the freezer compartment.

In order to suppress such a low temperature phenomenon, the conventional low temperature compensation circuit as shown in FIG. 1 is implemented.

In the conventional refrigerator low temperature compensation circuit, the resistance heating element is attached to the thermostat sensing unit, and the resistance heating element is configured to increase the temperature of the thermostat sensing unit when a low temperature phenomenon occurs.

That is, as shown, the power supply line (L1, L2) is connected to the first and second terminals of the power input unit 1 for inputting the external AC power, between the power supply line (L1, L2) The door switch 3 which is turned on / off in conjunction with the opening / closing operation of the door, and the interior lamp operating section 20 in which the interior lamp 5 is connected in series are constituted. The interior lamp 5 is supplied with current through the door switch 3 which is operated when the door is opened. The third terminal of the power input unit 1 is grounded to ground.

In addition, the power supply line (L1) is connected to a temperature controller 9 that is on / off operation according to the set temperature. A defrost timer 21 is installed at the next stage of the temperature controller 9 to control the power supply to the compressor driver 31 or the power supply to the defrost heater driver 29. The power supplied to the compressor driver 31 drives the compressor 15, and the power supplied to the defrost heater driver 29 drives the defrost heater 13. The defrost timer 21, the initial state maintains the connection state (d-e) to the compressor drive unit 31 side. When the compressor driving time is completed, the defrost heater has a connection state d-f.

A heating resistor 11 is installed around the temperature controller 9, and the heating resistor 11 is connected between the power supply lines L1 and L3. The power supply line L3 is a supply line of the compressor driver 31. Therefore, when power is not supplied to the compressor 15, heat is generated in the heat generating resistor 11.

In the conventional refrigerator having the above configuration, the low temperature compensation circuit operates as follows.

The power input to the power input unit 1 while the power is supplied to the inside of the product is provided to the high-light lamp operation unit 20. In addition, the power input to the power input unit 1 is in a state that is provided to the defrost heater unit 29 and the compressor driving unit 31.

In this power supply state, when the user opens the refrigerator door, the door switch 3 is switched on. At this time, the power input to the power input unit 1 is supplied to the interior lamp 5 through the door switch 3 operated on, and the interior lamp 5 is turned on.

And when the temperature inside the high temperature is higher than the set temperature, the temperature controller 9 is turned on. In addition, when the count time of the defrost timer 21 has not completed the preset compressor operation time, the movable terminal d of the defrost timer 21 remains connected to the terminal e. At this time, the power passing through the temperature controller 9 and the defrost timer 21 is supplied to the compressor driving unit 31 to drive the compressor 15. In addition, the power that has passed through the temperature controller 9 and the defrost timer 21 is supplied to the fan motor 7 of the freezer compartment to drive the fan motor 7.                         

In this operating state, the high temperature and high pressure refrigerant generated by the driving of the compressor 15 generates cold air while exchanging heat with ambient air in an evaporator (not shown). The generated cold air is supplied to the refrigerating chamber and the freezing chamber through the cold air supply passage (not shown). When the cold air is supplied to the refrigerating compartment and the freezing compartment by the above control, the internal temperature of the refrigerating compartment and the freezing compartment decreases, and when the predetermined time elapses, the internal temperature reaches the set temperature.

The temperature sensing temperature controller 9 switches to the off state when the internal temperature of the high temperature is lower than the set temperature. When the temperature controller 9 is turned off, power input to the power input unit 1 may not be supplied to the compressor driver 31. Therefore, the compressor 15 is controlled to a stop state without supplying power to the compressor 15.

When the compressor 15 is controlled in a stopped state, no cold air is generated without a heat exchange operation occurring in the evaporator. Therefore, cold air cannot be supplied into the refrigerator. When a predetermined time elapses in this state, the internal temperature of the refrigerator is raised, and the temperature controller 9 is switched to the on state again. And again, the compressor 15 is restarted to supply the cold air into the refrigerator.

On the other hand, when the ambient temperature is lowered below a certain value, the ambient temperature affects the internal temperature of the refrigerator. This is because the cold inside the refrigerator is released to the outside of the refrigerator due to the opening and closing operation of the refrigerator door, the outside temperature, etc., the inside temperature is increased and the compressor 15 is restarted again. The temperature difference does not occur, the cold air is not lost, and thus the temperature inside the refrigerator is not increased.                         

When the low temperature phenomenon occurs, the temperature controller 9 continues to be in an off state. When the off state of the temperature controller 9 is maintained for a predetermined time or more due to the low temperature phenomenon, the compressor 15 is not in operation for a long time, and thus the supply of cold air into the refrigerator is completely suppressed.

At this time, the supply of cold air to the freezing compartment is also not made, and thus a problem occurs that the temperature of the freezing compartment which must maintain a relatively lower temperature than the refrigerating compartment is increased.

For this reason, conventionally, the heat generating resistor 11 is provided near the temperature controller 9. That is, when the compressor 15 does not operate for a long time, the temperature detected by the temperature controller 9 is increased by the generated heat of the heat generating resistor 11. The heat generating resistor 11 is connected between a power supply line L1 directly connected to the power input unit 1 and a power supply line L3 connected to the compressor driver 31. The resistance value of the heat generating resistor 11 is set relatively higher than the resistance value of the compressor 15.

Accordingly, when the power of the power input unit 1 is supplied to the compressor driving unit 31 or the defrost heater unit 29 at regular intervals by the on / off operation of the temperature controller 9, the heat generated from the heat generating resistor 11 is It is limited to a certain value or less. However, when the temperature controller 9 continues to be off for a predetermined time or more, the power input to the power input unit 1 is not consumed in the product.

At this time, the power is continuously supplied to the heat generating resistor 11, and the heat generating resistor 11 generates a high heat when the power supply amount exceeds a predetermined value, and the temperature near the temperature controller 9 is maintained. To raise. By the heat at this time, the temperature controller 9 is switched to the on state again, and power can be supplied to the compressor driving unit 31 by the ON operation of the temperature controller 9.

However, the low temperature compensation circuit of the conventional refrigerator having the above-described configuration also has a problem that it is difficult to cope with the external temperature below a predetermined value (5 to 15 degrees). This is because the heat generated by the heat generating resistor 11 is limited to a certain value. Therefore, in the case of externally installed products that are directly affected by the external temperature, the operation rate of the compressor could not be prevented from being lowered during the low temperature.

Accordingly, an object of the present invention is to provide a low temperature compensation circuit of a refrigerator that can increase the operation rate of a compressor by using radiant heat such as high temperature when the external temperature is low.

The low temperature compensation circuit of the refrigerator according to the present invention for achieving the above object, the power is supplied, the compressor is driven to generate the cold air in the refrigerator; A high light driving unit driven for lighting of the high light; A temperature controller connected between a power input unit and the compressor, the temperature controller opening and closing the power supply to the compressor such that the internal temperature can maintain a set temperature; It is attached to one side of the machine room in which the compressor is installed, comprising a bimetal switch which is turned on when the sensing temperature is below a certain temperature, characterized in that the drive of the high-light driving unit in conjunction with the on operation of the bimetal switch. .

In the present invention, the high-light drive unit includes a three-terminal door switch connecting the movable terminal to the power supply; And a high-light lamp connected to the first fixed terminal of the three-terminal door switch, wherein the bimetal switch is connected between the second fixed terminal of the three-terminal door switch and the high lamp.

In addition, in the present invention, the high-light drive unit includes a two-terminal door switch connecting the movable terminal to the power supply; The high light is connected to the fixed terminal of the two-terminal door switch, the bimetal switch is characterized in that connected between the power supply and the high light.

Hereinafter, a low temperature compensation circuit of a refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a control circuit diagram for low temperature compensation in the refrigerator according to the present invention. 2 shows a control state when the ambient temperature is not low.

As shown in the drawing, power supply lines L111 and L112 are connected to the first and second terminals of the power input unit 101 for inputting external AC power, and between the power supply lines L111 and L112. The door switch 103 which is turned on / off in conjunction with the opening / closing operation and the interior lamp 105 are connected in series. The interior lamp 105 is supplied with a current through the door switch 103 that is operated when the door is opened. The third terminal of the power input unit 101 is grounded to ground.

The door switch 103 is composed of a three-terminal type, the movable terminal (a) is connected to the power supply line (L111), the terminal (b) is connected to the interior lamp 105, the terminal (c) is It is configured to be connected to the interior lamp 105 through a bimetal switch 125 that is on / off operation by the ambient temperature. The bimetallic switch 125 is operated on when the internal temperature of the refrigerator is higher than or equal to a predetermined temperature to control the supply of current to the internal lamp 105. At this time, the radiant heat generated from the interior lamp 105 controls the temperature controller 109, which will be described later, while raising the interior temperature of the refrigerator.

The initial state of the door switch 103 is a state in which the terminal a and the terminal c are connected as shown in FIG. 2, and the bimetallic switch 125 is kept in the off state. Therefore, the power supplied through the door switch 103 is cut off from the bimetal switch 125 and cannot be supplied to the interior lamp 105. The state shown in FIG. 2 represents an operating state when the external temperature is not a low temperature state.

The bimetallic switch 125 is a switch configured to be turned on when a predetermined temperature (between about 5 degrees and about 15 degrees) or less is detected, and to be turned off when a detected temperature is outside the predetermined temperature. In the present invention, the bimetal switch 125 is installed in a machine room in which a compressor is installed. Therefore, when the compressor 115 is not driven for a long time due to the low temperature phenomenon, the temperature of the machine room is lowered, and the bimetallic switch 125 is operated in an on state. In addition, when the compressor 115 is driven again due to the operation of the bimetal switch 125, the machine room is raised in temperature due to the generated heat of the compressor 115. When the temperature of the machine room rises in this way, the bimetallic switch 125 is switched to the off state.

The temperature controller 109 is connected to a power supply line (L111). The defrost timer 121 is installed at the next stage of the temperature controller 109 to control power supply to the compressor 115 or power supply to the defrost heater 113. The temperature controller 109 is a temperature sensing switch. That is, the high temperature inside the refrigerator operates on / off to maintain the preset temperature set by the user or optimally set for the operation of the product. Therefore, when the internal temperature rises above the set temperature, it is turned on to induce power supply to the compressor and the fan motor, and when the internal temperature falls below the set temperature, the operation is turned off to cut off the power supply to the compressor. The temperature controller 109 is installed on one side in the furnace. Therefore, the on / off operation state is controlled by the difference between the internal temperature and the set temperature.

The defrost timer 121 is composed of a timer T and a three-terminal switch. The three-terminal switch is composed of three terminals to connect the movable terminal (d) to one side of the temperature controller 109, the terminal (e) to one side of the power supply line to the compressor 115, defrost heater Another terminal f is connected to one side of the power supply line to 113. Then, the power supplied through the temperature controller 109 is controlled to be selectively supplied to the compressor 115 and the defrost heater 113. At this time, the timer T is set at the compressor operation time. Therefore, the power supplied through the temperature controller 109 is controlled to be supplied to the compressor 115 until the compressor operation time is reached by the timer T. When the compressor operation time is reached, the temperature controller 109 is controlled. Power supplied through is controlled to be supplied to the defrost heater (113).

Terminal f of the defrosting timer 121 is connected to a defrosting temperature controller 119 which is automatically turned off when a predetermined temperature is detected during the defrosting operation, and a defrosting heater 13 is provided through the defrosting temperature controller 119. ) Is connected. The overcurrent protection switch 117 is connected to the terminal e of the defrost timer 121, and the compressor 115 is connected through the overcurrent protection switch 117. The overcurrent protection switch 117 serves to block current supply to the compressor 115 to protect the compressor when the current supplied to the compressor 115 is in an overcurrent state.

In addition, the freezer compartment motor 107 is connected between the terminal e of the defrost timer 121 and the power supply line L112, so that when the power for driving the compressor is supplied, the freezer compartment fan motor 107 is also provided. As the power is supplied, the freezing chamber fan motor 107 is driven. Reference numeral 23 denotes a temperature fuse.

Next, when the low temperature phenomenon occurs in the refrigerator according to the present invention having the above configuration, it will be described for the control process for increasing the operation rate of the compressor.

When the power is input into the product, the power input to the power input unit 101 is provided to the front end of the door switch 103 for controlling the operation of the interior lamp 105. In addition, the power input to the power input unit 101 is provided to the front end of the temperature controller 109.

In this power supply state, when the user opens the refrigerator door, the door switch 103 is switched to the state in which the terminal a and the terminal b are connected in the initial state (a-c connection state) shown in FIG. At this time, the power input to the power input unit 101 is supplied to the interior lamp 105 through the terminal (a-b connection state) of the door switch 103, and the interior lamp 105 is turned on.

When the internal temperature is higher than the set temperature, the temperature controller 109 is turned on. In addition, when the count time of the defrost timer 121 has not completed the preset compressor operation time, the movable terminal d of the defrost timer 121 remains connected to the terminal e. At this time, the power passing through the temperature controller 109 and the defrost timer 121 is supplied to the compressor 115 to drive the compressor. In addition, the power passing through the temperature controller 109 and the defrost timer 121 is supplied to the fan motor 107 of the freezer compartment to drive the fan motor 107.

In this operating state, the high temperature and high pressure refrigerant generated by the driving of the compressor 115 generates cold air while exchanging heat with ambient air in an evaporator (not shown). The generated cold air is supplied to the refrigerating chamber and the freezing chamber through the cold air supply passage (not shown). When the cold air is supplied to the refrigerating compartment and the freezing compartment by the above control, the internal temperature of the refrigerating compartment and the freezing compartment decreases, and when the predetermined time elapses, the internal temperature reaches the set temperature.

At this time, the temperature-sensing temperature controller 109 switches to the off state when the internal temperature is lower than the set temperature. When the temperature controller 109 is turned off, power input to the power input unit 101 is not supplied to the compressor 115. Therefore, the compressor 115 is controlled in a stopped state without power being supplied to the compressor 115.

When the compressor 115 is controlled in a stopped state, no cold air is generated without a heat exchange operation occurring in the evaporator. Therefore, cold air cannot be supplied into the refrigerator. When a predetermined time elapses in this state, the internal temperature of the refrigerator is raised, and the temperature controller 109 is switched to the on state again. And again, the compressor 115 is restarted to supply the cold air into the refrigerator.

The defrost timer 121 switches the terminal of the switch to the (d-f) connection state when the set compressor driving time elapses. The power supplied to the compressor 115 and the fan motor 107 is cut off by the switching operation of the defrost timer 121, and the supply power is supplied to the defrost heater 113 through the defrost temperature controller 119. The defrost heater 113 as a supply power at this time, performs a defrost operation to remove the frost formed on the evaporator (not shown).

On the other hand, if the external temperature is lowered below a certain value, the external temperature affects the internal temperature. This is because the cold inside the refrigerator is released to the outside of the refrigerator by the opening and closing operation of the refrigerator door, the outside temperature, etc., the inside temperature is raised and the compressor 115 is restarted again. The temperature difference does not occur, the cold air is not lost, and thus the temperature inside the refrigerator is not increased.

When the low temperature phenomenon occurs, the temperature controller 109 continues to be in an off state. When the off state of the temperature controller 109 is maintained for a predetermined time or more by the low temperature phenomenon, the compressor 115 does not operate for a long time, and thus the supply of cold air into the refrigerator is completely suppressed.

At this time, the supply of cold air to the freezing compartment is also not made, and thus a problem occurs that the temperature of the freezing compartment which must maintain a relatively lower temperature than the refrigerating compartment is increased.

When the low temperature phenomenon occurs, the temperature inside the machine room in which the compressor 115 is installed is also lowered. At this time, the bimetallic switch 125 installed at one side of the machine room switches the operation to the on state when the sensing temperature becomes lower than a predetermined temperature (about 5 degrees to 15 degrees). The on operation of the bimetal switch 125 affects the operation of the interior lamp 105.

That is, in the state where the initial state of the door switch 103 is connected to the terminal (ac), when the bimetallic switch 125 is turned on (shown in Figure 3), the front end of the door switch 103 Power being supplied is supplied to the interior lamp 105 through the terminal ac of the door switch and the bimetallic switch 125. By the operation at this time, the interior lamp 105 is turned on.

When the interior lamp 105 is turned on, radiant heat is generated in the interior lamp 105, and the generated heat affects the temperature controller 109 installed in the interior. That is, the temperature controller 109 is switched from the off state to the on state by the radiant heat generated due to the lighting operation of the interior lamp 105.

When the temperature controller 109 is turned on, the compressor 115 is restarted while power is supplied to the compressor 115 again. In this operation, it is possible to control the cooling air to be supplied into the refrigerator by controlling the operation of the compressor 115 even in a low temperature phenomenon.

When the compressor 115 is restarted by the above operation, the internal temperature of the machine room is increased due to the heat generated by the compressor, and the bimetallic switch 125 is turned off by the elevated machine room temperature. In conjunction with this, the interior lamp 105 is also turned off.

As described above, the low temperature compensation circuit of the refrigerator according to the present invention controls the operation state of the temperature controller while increasing the detection temperature in the refrigerator by using radiant heat such as the refrigerator when the temperature decreases. At this time, the compressor can be driven even when the external temperature is low, thereby preventing the compressor operation rate from being lowered due to the low temperature.

4 and 5 show an embodiment in which the door switch is implemented in the case of two terminals.

That is, in FIGS. 2 and 3, the door switch 103 is a three-terminal case, and is configured to be directly supplied with power to the interior lamp 105 or through the bimetallic switch 125 according to the switching state of the door switch. have. However, in FIGS. 4 and 5, the door switch 203 is a two-terminal case. At this time, the bimetallic switch 225 is connected between the front end of the door switch 203 and the front end of the interior lamp 205.

Accordingly, when the user opens the door, the door switch 203 is turned on while the power is supplied to the high lamp 205 through the door switch 203, and the bimetal switch 225 is opened by the low temperature phenomenon in the closed state of the door. When turned on, power is supplied directly to the lamp 205 through the bimetal switch 225. 4 shows an initial state of the bimetal switch, and FIG. 5 shows an operating state of the bimetal switch.

The present invention described above has the following effects.

First, when the external temperature is low, it is possible to increase the operation rate of the compressor by using radiant heat such as high inside, so that it is possible to cope with the low temperature phenomenon.

Second, it is possible to cope with low temperature phenomenon without using a separate heating element.

Claims (3)

A compressor driven when the power is supplied, for generating cold air in the refrigerator; A high light driving unit driven for lighting of the high light; A temperature controller connected between a power input unit and the compressor, the temperature controller opening and closing the power supply to the compressor such that the internal temperature can maintain a set temperature; It is attached to one side of the machine room where the compressor is installed, and comprises a bimetal switch that is turned on when the sensing temperature is below a certain temperature, The low temperature compensation circuit of the refrigerator, characterized in that the high light driving unit is driven in conjunction with the on operation of the bimetal switch. The method of claim 1, The high light driving unit, A three-terminal door switch connecting the movable terminal to the power supply unit; Consists of a high level lamp connected to the first fixed terminal of the three-terminal door switch, The bimetal switch is a low-temperature compensation circuit of the refrigerator, characterized in that connected between the second fixed terminal of the three-terminal door switch and the interior lamp. The method of claim 1, The high light driving unit includes a two-terminal door switch connecting a movable terminal to a power supply unit; Consists of a high level lamp connected to the fixed terminal of the two-terminal door switch, The bimetal switch is a low-temperature compensation circuit of the refrigerator, characterized in that connected between the power supply and the interior lamp.

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