KR100366444B1 - Circuit for control lamp in refrigerator - Google Patents

Abstract

The present invention relates to a high-light control circuit of the refrigerator, and more particularly, to a high-light control circuit of the refrigerator that can efficiently control the high lamp of the refrigerator, reduce the manufacturing cost, and prevent unnecessary power consumption. The high lamp control circuit of the refrigerator according to the present invention includes: a voltage dividing capacitor configured to generate a voltage having a predetermined magnitude by receiving power; A refrigerator compartment lamp and a freezer compartment lamp connected in parallel to the capacitor; A refrigerator compartment door switch interlocked with a refrigerator compartment door opening so that the divided voltage of the capacitor is supplied to the refrigerator compartment lamp; It is configured to include a freezer door switch for controlling the divided voltage of the capacitor to be supplied to the freezer compartment lamp in conjunction with the freezer door opening.

Description

Circuit for control lamp in refrigerator

The present invention relates to a high-light control circuit of the refrigerator, and more particularly, to a high-light control circuit of the refrigerator that can efficiently control the high lamp of the refrigerator, reduce the manufacturing cost, and prevent unnecessary power consumption.

Halogen lamps are manufactured for rated voltages of 12 or 24 volts. Therefore, in order to use in homes or home appliances, it is necessary to step down the power supply voltage supplied to the halogen lamp.

1 is a diagram of a lamp control circuit of a refrigerator of a first embodiment according to the prior art.

Conventionally, in the high lamp control circuit of the refrigerator according to the first embodiment, transformers 7 and 9 for voltage step-down are provided in the freezer compartment lamp 3 and the refrigerator compartment lamp 5, respectively. That is, the primary side of the transformer 7 for generating the necessary power of the freezer compartment lamp 3 is connected to the power supply voltage 1 for inputting the power supply voltage into the refrigerator. In addition, the primary side of the transformer 9 for generating the required power source of the refrigerating chamber lamp 5 is connected to the power supply voltage 1.

The transformer 7 is controlled to open and close the power passage by the freezer door switch 11, and the transformer 9 is controlled to open and close the power passage by the refrigerating compartment door switch 13. The transformers 7 and 9 are set in accordance with the rated voltages of the freezer compartment lamp 3 and the refrigerator compartment lamp 5.

In addition, the conventional refrigerator interior lamp control circuit includes a fan motor 15 that operates under the control of the freezer compartment door switch 11 to circulate the cold air inside the refrigerator. In addition, the operation unit 23 for operating the compressor for generating cold air for lowering the temperature in the refrigerator while being circulated in the refrigerating chamber and the freezing chamber, and operated to remove frost caught on the evaporator due to the operation of the driving unit 23. And a timer 21 for controlling the operation of the defroster 25 or the operation of the driver 23.

Next, an operation process according to the first embodiment having the above configuration will be described.

First, the driving unit 23 and the defrosting unit 25 are operated irrespective of the operation of the interior lamp. That is, when a current is supplied to the driving unit 23 under the control of the timer 21, the driving unit 23 is operated while cold air is generated and circulated in the refrigerator. In addition, when a current is supplied to the defrosting portion 25 under the control of the timer 21, the defrosting portion 25 is operated, and frost is removed from the evaporator.

On the other hand, when the freezer door is closed, the freezer door switch 11 has a control state of the position indicated by the solid line in FIG. Likewise, when the refrigerating compartment door is closed, the refrigerating compartment door switch 13 has a control state at the position indicated by the solid line in FIG.

Therefore, the primary sides of the transformers 7 and 9 are open. Therefore, the transformers 7 and 9 do not generate secondary voltages due to normal operation, and as a result, the voltages applied to the freezer compartment lamp 3 and the refrigerating compartment lamp 5 are almost never. Therefore, both lamps remain off.

Of course, when the freezer compartment door is closed, the freezer compartment door switch 11 has a control state at a position indicated by a solid line in FIG. 1, so that a current path of the fan motor 15 is formed, and the fan motor ( 15) Power is supplied. Therefore, the fan motor 15 rotates to smooth the cold air circulation inside the refrigerator compartment and the freezer compartment door in a closed state.

However, when the freezer compartment door is opened, the freezer compartment door switch 11 is switched to the position indicated by dashed lines in FIG. 1. Therefore, while the current path on the primary side of the transformer 7 is formed, voltage is induced from the primary side to the secondary side of the transformer 7. The voltage is supplied to the freezer compartment lamp 3 by the generated voltage, and the freezer compartment lamp 3 is turned on.

In addition, when the refrigerating compartment door is opened, the refrigerating compartment door switch 13 is switched to the position indicated by dashed lines in FIG. 1. Thus, a current path on the primary side of the transformer 9 is formed, and voltage is induced from the primary side to the secondary side of the transformer 7. The voltage generated at this time is supplied to the refrigerator compartment lamp 5, and the refrigerator compartment lamp 5 is turned on.

That is, in the refrigerator high lamp control circuit according to the first embodiment of the present invention, each of the transformers 7 and 9 is provided in the refrigerating chamber lamp 5 and the freezing chamber lamp 3, and the freezing chamber door switch in the primary winding of the transformer. 11) and the refrigerator door switch 13 are connected, respectively. Therefore, when the freezer door is opened, the contact of the freezer door switch 11 is switched to the dotted line position, the transformer 7 is driven to light the freezer lamp 3. When the refrigerating compartment door is opened, the contact point of the refrigerating compartment door switch 13 is switched to the dotted line position, and the transformer 9 is driven to light the refrigerating compartment lamp 5.

Therefore, the refrigerator internal lamp control circuit according to the first embodiment uses two transformers. Therefore, the manufacturing cost increases due to the use of the transformer, there was a problem that requires a lot of installation space of the transformer by using two transformers.

Next, Figure 2 is a refrigerator interior lamp control circuit diagram according to a second embodiment of the prior art.

Conventionally, the refrigerator high lamp control circuit according to the second embodiment is a transformer 37 for generating a rated voltage of the size required by the freezer compartment lamp 33 and the refrigerator compartment lamp 35 by the power supply voltage 31 input into the refrigerator. ) Is included. That is, the primary side of the transformer 37 is connected to the power supply voltage 31, and the freezer compartment lamp 33 and the refrigerating compartment lamp 35 are connected in parallel to the secondary side. In addition, a freezer compartment door switch 41 is connected in series with the freezer compartment lamp 33, and a freezer compartment door switch 43 is connected in series with the refrigerator compartment lamp 35.

And the defrost part 55, the drive part 53, the timer 51, the fan motor 45, etc. are comprised by the structure similar to 1st Embodiment.

The refrigerator internal lamp control circuit according to the second embodiment of the above-described configuration operates as follows.

The power is always supplied to the primary side of the transformer 37 by the power supply voltage 31 input into the refrigerator. However, since the secondary side of the transformer 37 is selectively formed by the door switches 41 and 43, the induction of voltage from the primary side to the secondary side of the transformer 37 is limited only in the following cases. do.

When the user opens the refrigerating compartment door, the refrigerating compartment door switch 43 operating in conjunction with the refrigerating compartment door is switched to the 'dotted' position in FIG. This operation forms a closed loop connected to the refrigerating compartment lamp 35 and the refrigerating compartment door switch 43 on the secondary side of the transformer 37.

Therefore, the voltage induced on the primary side of the transformer 37 is applied to the lamp 35 while being supplied to the secondary side, and the refrigerating compartment lamp 35 is turned on.

When the user opens the freezer compartment door, the freezer compartment door switch 41 operating in conjunction with the freezer compartment door is switched to the 'dotted' position of FIG. 2. In this operation, a closed loop connected to the freezer compartment lamp 33 and the freezer compartment door switch 41 is formed on the secondary side of the transformer 37.

Therefore, the voltage induced on the primary side of the transformer 37 is applied to the freezer compartment lamp 33 while being supplied to the secondary side, and the freezer compartment lamp 33 is turned on.

That is, in the refrigerator internal lamp control circuit according to the second embodiment of the related art, one transformer is used, and the refrigerator compartment lamp 35 and the freezer compartment lamp 33 are connected in parallel to the secondary side of the transformer 37. The primary side of the transformer 37 has a state in which the power supply voltage 31 is always energized.

Accordingly, the secondary side voltage of the transformer 37 is supplied to the refrigerator compartment lamp 35 by the control operation of the refrigerator compartment door switch 43, and by the control operation of the freezer compartment door switch 41, the transformer ( The secondary voltage of 37 is supplied to the freezer compartment lamp 33.

Therefore, the refrigerator high-light control circuit of the conventional second embodiment has a problem that the power is always supplied to the primary side of the transformer, power consumption due to standby power. In addition, there is a problem that the manufacturing cost is increased by the use of a transformer.

That is, the refrigerator internal lamp control circuit according to the first and second embodiments of the prior art had a problem that the manufacturing cost is increased by the use of a transformer. In addition, there is a problem that requires the installation space of the transformer, there is always a problem that unnecessary power consumption caused by the voltage supplied to the primary side.

Accordingly, an object of the present invention is to provide a high light control circuit for a refrigerator that can efficiently control the high light of the refrigerator, reduce manufacturing costs, and prevent unnecessary power consumption.

1 is a high lamp control circuit diagram of a refrigerator according to a first embodiment of the prior art;

2 is a high lamp control circuit diagram of a refrigerator according to a second embodiment of the present invention;

3 is a high lamp control circuit diagram of a refrigerator according to a first embodiment of the present invention;

4 is an operating state when the refrigerating compartment door is opened in the first embodiment of the present invention,

5 is an operating state when the freezer door is opened in the first embodiment of the present invention;

6 is an operation state when the refrigerating compartment and the freezing compartment door in the first embodiment of the present invention,

7 is a high lamp control circuit diagram of a refrigerator according to a second embodiment of the present invention;

8 is an operation state when the refrigerating compartment door is opened in the second embodiment of the present invention;

9 is an operating state when the freezer compartment door is opened in the second embodiment of the present invention;

10 is an operation state when the refrigerating compartment, freezer compartment door is opened in the second embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

113,213: freezer lamp 115,215: cold room lamp

119,221: Freezer door switch 121,216: Refrigerator door switch

117,217: voltage divider capacitor 219: relay

The high-light control circuit of the refrigerator according to the present invention for achieving the above object comprises: a voltage dividing capacitor for generating a voltage of a predetermined size by receiving power; A refrigerator compartment lamp and a freezer compartment lamp connected in parallel to the capacitor; A refrigerator compartment door switch interlocked with a refrigerator compartment door to adjust the divided voltage of the capacitor to be supplied to the refrigerator compartment lamp; It is configured to include a freezer door switch for controlling the divided voltage of the capacitor to be supplied to the freezer compartment lamp in conjunction with the freezer door opening.

A high-light lamp control circuit of a refrigerator according to a second embodiment of the present invention includes a voltage dividing capacitor for generating a voltage having a predetermined magnitude by receiving power; A refrigerator compartment lamp and a freezer compartment lamp connected to a rear end of the capacitor in parallel; A refrigerating compartment door switch and a freezing compartment door switch for detecting the opening of the refrigerating compartment and the freezing compartment door and outputting the same; Control means for recognizing the opening of the refrigerating compartment and the freezing compartment door according to the operation state of the refrigerating compartment door switch and the freezing compartment door switch, and outputting a control signal according thereto; Controlled by the output of the control means, and comprises a relay for forming a current path of the refrigerator compartment lamp and the freezer compartment lamp.

Hereinafter, the interior lamp control circuit of the refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a diagram of a lamp control circuit inside a refrigerator according to a first embodiment of the present invention.

In the high lamp control circuit of the refrigerator according to the first embodiment of the present invention, a voltage dividing capacitor 117 is connected to one side of the power supply voltage 111. The freezer compartment lamp 113 and the refrigerating compartment lamp 115 are connected to the partial pressure capacitor 117 in parallel. The freezer compartment lamp 113 is controlled to be turned on / off by the freezer compartment door switch 119, and the freezer compartment lamp 115 is controlled to be turned on / off by the refrigerator compartment door switch 121.

In addition, a driving unit 131 including a compressor for driving cold air and a defrosting unit 139 operating for defrosting are connected in parallel to the power supply voltage 111, and the power supply voltage 111 is operated. The timer 127 for controlling the supply to the unit 131 or the defrost unit 139 is included. The fan motor 121 and the cooling fan 123 that operate in conjunction with the operation of the driving unit 131 are included. And a thermostat 125 for controlling the operation of the compressor is included.

Next, an operation process of the refrigerator interior lamp control circuit according to the first embodiment of the present invention having the above configuration will be described.

4 is an operation state diagram when the refrigerating compartment door is opened in the first embodiment of the present invention.

When the refrigerating compartment door is opened, the movable terminal b of the refrigerating compartment door switch 121 is turned off, and the movable terminal a is turned on. On the other hand, the movable terminal (b) of the freezer compartment door switch (119) is kept in the on state, the other movable terminal (a) has an off state.

Therefore, the output of the capacitor 117 inputted and divided by the power supply voltage 111 is connected to the movable terminal (a) of the refrigerating compartment door switch 121 through the connection terminal (b) of the freezer compartment door switch 119. Is passed on to the line. The power supply via the connection terminal (a) of the refrigerating compartment door switch 121 is supplied to the lamp 115 to turn on the refrigerating compartment lamp 115.

Next, Figure 5 is an operating state diagram when the freezer door is opened in the first embodiment of the present invention.

When the freezer compartment door is opened, the movable terminal b of the freezer compartment door switch 119 is turned off, and the movable terminal a is turned on. On the other hand, the movable terminal b of the refrigerating compartment door switch 121 is kept in the on state, and the other movable terminal a is in the off state.

Therefore, the output of the capacitor 117 input and divided by the power supply voltage 111 is connected to the movable terminal (b) of the refrigerating compartment door switch 121 through the connecting terminal (a) of the freezing compartment door switch 119. Is passed on to the line. That is, the output of the capacitor 117 is a closed loop through the freezing chamber lamp 113, the connection line (a) of the freezer door switch 119, and the connection line (b) of the freezer door switch 121. While forming, the divided voltage is supplied to the freezer compartment lamp 113. Therefore, the freezer compartment lamp 113 is turned on.

6 is an operation state diagram when the refrigerating chamber and the freezing chamber door are opened in the first embodiment of the present invention.

When both the refrigerating compartment door and the freezing compartment door are opened, the refrigerating compartment door switch 121 has the movable terminal a turned on as the refrigerating compartment door is opened, and the operating terminal (a) of the freezing compartment door switch 119 as the freezing compartment door is opened. Will come on.

Therefore, from the voltage dividing capacitor 117, the freezing chamber lamp 113, the freezing terminal door switch 119 of the operating terminal (a) connection line, the refrigerating chamber door switch 121, the operating terminal (a) connection line, and the refrigerator compartment lamp 115 Closed loops are formed. At this time, the voltage flowing on the formed closed loop turns on the freezer compartment lamp 119 and the refrigerator compartment lamp 115.

In addition, when both the refrigerating compartment door and the freezing compartment door are closed, the movable terminal a of the freezer compartment door switch 119 is in an off state, and the other movable terminal b is in an on state. And the movable terminal (a) of the refrigerating compartment door switch has an off state, and the other movable terminal (b) has an on state.

Therefore, a closed loop connected to the freezer compartment lamp 113 and the refrigerating compartment lamp 115 is not formed, and thus the freezer compartment lamp 113 and the refrigerating compartment lamp 115 are turned off.

That is, in the high lamp control circuit of the refrigerator according to the first embodiment of the present invention, the supply voltage of the freezer compartment lamp 113 and the refrigerating compartment lamp 115 is generated by using the voltage dividing capacitor 117. That is, the voltage is stepped down by the filament resistance of the lamp and the R-C partial voltage, and the power stepped down by the capacitor is supplied to the lamps by a combination of opening and closing of the switch.

Therefore, in the first embodiment of the present invention, there is no standby power consumption by the capacitor 117, and the installation space can be reduced while reducing the manufacturing cost according to the use of the voltage divider capacitor instead of the transformer.

Next, Figure 7 is a high lamp control circuit diagram of a refrigerator according to a second embodiment of the present invention.

The high lamp control circuit of the refrigerator according to the second embodiment of the present invention is used in a microcomputer controlled refrigerator. That is, in the high lamp control circuit of the refrigerator according to the second embodiment of the present invention, the voltage dividing capacitor 217 is connected to one side of the power supply voltage 211. The freezer compartment lamp 213 and the refrigerating compartment lamp 215 are connected in parallel to the partial pressure capacitor 217.

The freezer compartment lamp 213 is controlled to be turned on / off by the freezer compartment door switch 221, and the freezer compartment lamp 215 is controlled to be turned on / off by the refrigerator compartment door switch 216. The freezer compartment door switch 221 detects the door opening of the freezer compartment and outputs a signal according to the door opening to the microcomputer. The refrigerating compartment door switch 216 detects the opening of the refrigerating compartment and outputs a signal according to the opening of the refrigerating compartment to the microcomputer.

In addition, a relay 219 operated by the control of a microcomputer is connected to the rear side of the freezer compartment lamp 213 and the refrigerator compartment lamp 215 which are connected in parallel.

In addition, a driving unit 235 including a compressor for driving cold air and a defrost unit 233 operating for defrosting are connected in parallel to the power supply voltage 211, and the power supply voltage 211 is operated. A timer 231 for controlling supply to the unit 235 or the defroster 233 is included. The fan motor 225 and the cooling fan 227 that operate in conjunction with the operation of the driving unit 235 are included. And a thermostat 229 for controlling the operation of the compressor is included. In addition, a relay 223 for controlling the operation of the fan motor 225 is configured, and the relay 223 is operated under the control of a microcomputer.

Next, an operation process of the refrigerator interior lamp control circuit according to the second embodiment of the present invention having the above configuration will be described.

8 is an operation state diagram when the refrigerating compartment door is opened in the second embodiment of the present invention.

When the refrigerating compartment door is opened, the movable terminals a and b of the refrigerating compartment door switch 216 are both turned off. In addition, the movable terminals a and b of the freezer compartment door switch 221 also have an off state.

At this time, the microcomputer (not shown) recognizes the state of the refrigerator compartment door switch 216 and the freezer compartment door switch 221, and recognizes that the refrigerator compartment door is opened. The microcomputer controls the operation of the relay 219 such that a connection line through the terminal a of the relay 219 is formed.

Accordingly, a closed loop is formed from the output of the voltage dividing capacitor 217 to the refrigerating chamber lamp 215 and the terminal a of the relay 219. Therefore, the output of the capacitor 217 is supplied to the refrigerator compartment lamp 215, thereby lighting the refrigerator compartment lamp.

9 is an operation state diagram when the freezer door is opened in the second embodiment of the present invention.

When the freezer compartment door is opened, both the refrigerating compartment door switch 216 and the movable terminals a and b of the freezer compartment door switch 221 are in an on state. At this time, the microcomputer inputs the on state of the movable terminal b of the refrigerator compartment door switch 216 and the movable terminal b of the freezer compartment door switch 221. The freezer door is opened from the state of the two terminals.

Thus, the microcomputer forms a connection line through the terminal b of the relay 219. Therefore, the movable terminal a of the refrigerating compartment door switch 216, the freezer compartment lamp 213, the movable terminal a of the freezer compartment door switch 221, and the terminal b of the relay 219 from the voltage dividing capacitor 217. Closed loops are formed.

As the output of the voltage dividing capacitor 217 flows on the closed loop thus formed, a voltage is supplied to the freezer compartment lamp 213, and the freezer compartment 213 is turned on.

Next, FIG. 10 is an operation state diagram when the refrigerator compartment and the freezer compartment door are opened in the second embodiment of the present invention.

When both the refrigerating compartment door and the freezing compartment door are opened, the refrigerating compartment door switch 216 is switched off and the freezing compartment door switch 221 is switched on. The operating states of the two switches 216 and 221 are transmitted to the microcomputer.

When the microcomputer inputs the off state of the movable terminal b of the refrigerating compartment door switch 216 and the on state of the movable terminal b of the freezer compartment door switch 221, both the refrigerating compartment door and the freezer compartment door are opened. To judge. Therefore, the microcomputer forms a connection line to the terminal b side of the relay 219.

Therefore, a closed loop connected from the voltage dividing capacitor 217 to the refrigerating compartment lamp 215, the freezer compartment lamp 213, the movable terminal a of the freezer compartment door switch 221, and the terminal b of the relay 219. Is formed. The voltage flowing in the closed loop thus formed is supplied to the refrigerating chamber lamp 215 and the freezing chamber lamp 213 to control the lighting of the two lamps.

Next, when both the refrigerating compartment door and the freezing compartment door are closed, the refrigerating compartment door switch 216 has an on state, and the freezing compartment door switch 221 has an off state. At this time, the microcomputer is connected to the terminal (b) side of the relay 219.

Accordingly, the refrigerating compartment lamp 215 is blocked by the relay 219, the current path is blocked, the freezer compartment lamp 213 is blocked by the freezer door switch 221, the current path is to be kept off.

That is, the refrigerator internal lamp control circuit according to the second embodiment of the present invention connects the voltage dividing capacitor 217 to one side of the power supply voltage 211. A freezer compartment lamp 213 and a refrigerating compartment lamp 215, and a refrigerating compartment door switch 216, a freezer compartment door switch 221, and a relay 219 operated at the rear end of the partial pressure capacitor 217. Are connected in parallel and in parallel.

As described above, the refrigerator high lamp control circuit according to the present invention generates the necessary power for the refrigerator compartment lamp and the freezer compartment lamp by using one of the voltage dividing capacitors. Therefore, the manufacturing cost can be lowered and the installation space can be reduced compared with the use of the conventional transformer. In addition, since a capacitor is used, there is an advantage that the generation of power consumption due to standby power can be suppressed.

Claims (2)

A voltage divider capacitor for generating a voltage having a predetermined magnitude by receiving power; A refrigerator compartment lamp and a freezer compartment lamp connected in parallel to the capacitor; A refrigerator compartment door switch interlocked with a refrigerator compartment door opening so that the divided voltage of the capacitor is supplied to the refrigerator compartment lamp; And a freezer compartment door switch configured to control the divided voltage of the capacitor to be supplied to a freezer compartment lamp in conjunction with a freezer compartment door opening. A voltage divider capacitor for generating a voltage having a predetermined magnitude by receiving power; A refrigerator compartment lamp and a freezer compartment lamp connected to a rear end of the capacitor in parallel; A refrigerating compartment door switch and a freezing compartment door switch for detecting the opening of the refrigerating compartment and the freezing compartment door and outputting the same; Control means for recognizing the opening of the refrigerating compartment and the freezing compartment door according to the operation state of the refrigerating compartment door switch and the freezing compartment door switch, and outputting a control signal according thereto; And a relay controlled by an output of the control means, the relay forming a current path of the refrigerator compartment lamp and the freezer compartment lamp.