KR0182741B1 - An electric power reducting unit of airconditioner - Google Patents

Abstract

The present invention relates to a power saving device of an air conditioner, and more particularly, to a power saving device of an air conditioner, which can reduce power consumption of a compressor by converting a voltage applied to a compressor according to a change in room temperature. will be. In the power saving device, when the indoor temperature detected by the indoor temperature detecting unit 40 is equal to the set temperature, when the driving load of the compressor 20 is small, the power reduction device reduces the voltage applied from the commercial AC power and converts the reduced voltage into the compressor ( A voltage converter 50 connected between the commercial AC power supply and the compressor 20 so as to be supplied to the 20; A first compression driven switch unit 31 connected between the voltage converting unit 50 and the commercial AC power supply so that the commercial AC power can be supplied to the voltage converting unit 50; The front end is connected to the commercial AC power supply in parallel with the first compression driven switch unit 31 so that the commercial AC power can be supplied to the compressor 20, and the second stage driven switch unit connected to the compressor 20 is connected to the rear end of the compressor 20. (32); The control signal of the control unit 100 so that the voltage reduced in the voltage conversion unit 50 and the voltage directly applied from the commercial AC power supply can be selectively supplied to the compressor 20 according to the comparison result between the room temperature and the set temperature. Installed between the first compression drive switch 31 and the second compression drive switch 32 to selectively turn on the first compression drive switch 31 and the second compression drive switch 32 by It characterized in that it comprises a voltage switching switch 33.

Description

Power saving device of air conditioner

The present invention relates to an air conditioner, and more particularly, to a power saving device of an air conditioner that reduces power consumption by varying an input voltage of a compressor according to a difference between an indoor temperature and a set temperature.

In general, an air conditioner forms a refrigeration cycle in which a series of devices such as a compressor, an outdoor heat exchanger, a capillary tube, and an indoor heat exchanger are connected in series through a coolant tube so that the refrigerant repeats the state changes of compression, condensation, decompression, and evaporation. Heat exchange with the air to perform the cooling. In the case of cooling operation, the outdoor heat exchanger is a condenser and the indoor heat exchanger is an evaporator. At this time, the refrigerant is compressed by high temperature and high pressure by a compressor, liquefied by forced cooling through a fan in the condenser, and decompressed through a capillary tube. do. By using such a refrigeration cycle, the indoor air is sucked into the air conditioner by the blower of the indoor unit of the air conditioner and heat exchanged with the refrigerant flowing in the refrigerant pipe of the evaporator to cool the air, and discharge the cooled air back into the room. Let's do it. The air conditioner cools the room by repeating the air cooling process by the freezing cycle as described above.

When the compressor is driven in the refrigeration cycle, the refrigerant circulates along the refrigeration cycle, which consumes 85% of the power consumed in the air conditioner. The compressor is continuously driven until the indoor temperature sensed by the temperature sensor becomes lower than the set temperature input by the user from the time when the operation is started.

The drive control of the compressor as described above will be described with reference to FIG. 1, which shows a circuit diagram showing a schematic configuration of a conventional air conditioner.

As shown in FIG. 1, when a driving command and a set temperature are input through a key input unit (not shown), the controller 10 receives a signal related to the room temperature from the temperature sensor R _TH and is set by the user. Compare with one set temperature. The controller 10 outputs a high signal to one output terminal to drive the transistor Q1 when the indoor temperature is higher than the set temperature. Accordingly, the relay RY1 is turned on and the drive switch MG1 of the compressor 20 is turned on. When turned on, a predetermined commercial AC power supply (220V / 60Hz) is applied to the compressor 20.

In addition, the controller 10 continuously compares the indoor temperature detected by the temperature sensor R _TH with the set temperature even while the compressor 20 is being driven. At this time, if the indoor temperature is lower than the set temperature, The cooling operation is completed by outputting a low signal to turn off the drive switch MG1 of the relay RY1 and the compressor 20 to cut off the power applied to the grain storage 20.

However, the conventional air conditioners as described above continue to drive the compressor at the same speed even when the room temperature and the set temperature is the same, thereby increasing the power consumption compared to the indoor air cooling effect of the air conditioner. Considering that about 85% of the power consumption of the air conditioner is consumed by the compressor, even when the indoor temperature and the set temperature are the same, it is important to operate the compressor at the same speed, that is, when the room temperature is higher than the set temperature. There is a problem in that unnecessary power is wasted by increasing the power consumption of the air conditioner.

The present invention is to solve the conventional problems as described above, the object of the present invention is to adjust the drive speed of the compressor by applying a voltage reduced by a predetermined size than the commercial AC power supply according to the change in the room temperature, the compressor, To provide a power saving device of the air conditioner to reduce the power consumption of the.

The present invention for achieving the above object, the compressor driven by receiving a voltage from a commercial AC power supply, the indoor temperature sensing unit for detecting the indoor temperature, the indoor temperature detected by the indoor temperature sensing unit compared with the set temperature set by the user In the air conditioner having a control unit for controlling the drive speed of the compressor according to the comparison result, the room temperature detected by the room temperature sensing unit is equal to the set temperature, so that the commercial AC power supply is used when the drive load of the compressor is small. A voltage converter connected between the commercial AC power supply and the compressor to reduce the applied voltage and supply the reduced voltage to the compressor; A first compressor driving switch unit connected between the voltage converting unit and the commercial AC power supply to supply the commercial AC power to the voltage converting unit; A second compressor drive switch unit connected to a commercial AC power supply in parallel with the first compressor drive switch unit so that the commercial AC power can be supplied to the compressor, and a rear end of the second compressor drive switch unit connected to the compressor; According to the comparison result between the room temperature and the set temperature, the first compressor drive switch unit and the first compressor drive switch unit are controlled by a control signal of the controller so that the voltage reduced in the voltage converter and the voltage directly applied from the commercial AC power supply can be selectively supplied to the compressor. And a voltage switching switch unit disposed between the first compressor driving switch unit and the second compressor driving switch unit to selectively turn on the second compressor driving switch unit.

The voltage switching switch may include: a transistor having a base terminal connected to one output terminal of the controller via a resistor so that the voltage switching switch unit can be operated by a control signal of the controller; A coil connected in series between a predetermined DC power supply and a collector terminal of the transistor so that the transistor can form a magnetic field by a current supplied on and supplied by the control signal of the controller; A contact and a first compressor drive switch connecting the second compressor drive switch unit and the commercial AC power source to selectively apply the commercial AC power to the first compressor drive switch unit and the second compressor drive switch unit according to a control signal of the controller. It is characterized by comprising a relay switch having a contact B for connecting a negative current to a commercial AC power supply, and when the current flows through the coil to form a magnetic field, the connection state is switched from the contact a to the contact b.

1 is a control block diagram showing a schematic configuration of a conventional air conditioner.

2 is a control circuit diagram showing a schematic configuration of a power saving device of an air conditioner according to the present invention.

3 is a flowchart showing a control method of an air conditioner according to the present invention.

* Explanation of symbols for main parts of the drawings

20: compressor 31: first compressor drive switch

32: second compressor drive switch 33: voltage switching switch

34: power switch 40: room temperature detection unit

50: voltage conversion unit 100: control unit

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

2 is a control circuit diagram showing a schematic configuration of a power saving device of an air conditioner according to the present invention.

Control circuit of the power saving device of the air conditioner according to the present invention, as shown in FIG. The compressor 20, the voltage converter 50 connected in series between the compressor 20 and the commercial AC power supply, and the first compression driven switch unit 31 connected between the voltage converter 50 and the commercial AC power supply. ), The front end is connected to the commercial AC power supply in parallel with the first compression drive switch unit 31, the rear end is connected to the compressor 20, the second compression drive switch unit 32 and the first compression mechanism switch A voltage switching switch unit 33 provided between the first compression driving switch unit 31 and the second compression driving switch unit 32 to selectively drive the unit 31 and the second compression driving switch unit 32; The control unit 100 is connected to an indoor temperature sensing unit 40 for sensing an indoor temperature, an indoor temperature sensing unit 40, and a voltage switching switch unit 33.

The compressor 20 compresses the refrigerant flowing into the compressor on a refrigeration cycle at high temperature and high pressure when power is applied. The driving speed of the compressor 20 changes according to the magnitude of the applied voltage, and the lower the voltage, the lower the moving speed.

The voltage converter 50 converts a voltage when a commercial AC power is applied and applies the voltage to the compressor 20. By the way, the design of the compressor is set to allow the voltage stability, that is, the voltage variation rate within ± 15%. Therefore, the voltage conversion unit 50 is preferably implemented as a voltage conversion transformer for converting the voltage of the 220V / 60Hz commercial AC power supply to a range of 187V / 60Hz within the allowable limit.

The first compression driven switch unit 31 is turned on / off by the operation of the voltage switching switch unit 33, the first compression driven switch unit 31 supplies a commercial AC power supply to the voltage conversion unit 50 or It is preferably implemented as a magnet switch MG1 to block.

The second compression driven switch unit 32 is preferably implemented as a magnet switch MG2 like the first compression driven switch unit 31 to supply or block commercial AC power to or from the compressor 20.

The voltage switching switch unit 33 selectively drives the first compression driving switch unit 31 and the second compression driving switch unit 32 according to the control signal of the control unit 100, thereby providing a commercial AC power supply to the compressor 20. This may be applied directly, or the voltage reduced in the voltage converter 50 may be supplied to the compressor 20.

The voltage switching switch 33 includes a transistor Q1 through which resistors R1 and R2 are connected to one output terminal of the control unit 100, and a base terminal thereof is connected, a predetermined DC power supply (+ 12V) and a transistor Q1. Is installed between the coil (L1) connected between the collector terminal of the < RTI ID = 0.0 >) < / RTI > and the first compression drive switch portion 31 and the second compression drive switch portion 32. A relay switch for selectively connecting the 31 or the second compression driven switch portion 32 is provided. The relay contact RY1 includes a contact b for connecting the commercial AC power supply and the first compression driven switch unit 31, and a contact for connecting the commercial AC power supply and the second compression driven switch unit 32.

Accordingly, the transistor Q1 of the voltage switching switch 33 is turned on when a high signal is input from the controller 100 to the base terminal, and when the transistor Q1 is turned on, a DC power supply 12V flows to the coil, thereby relaying. The connection state of the switch is switched from contact a to contact b. Then, the second compression driven switch unit 32 is turned off and the first compression driven switch unit 31 is turned on by the conversion of the contact state. When the first compression driven switch unit 31 is turned on as described above, a commercial AC power is applied to the voltage converter 50, and a voltage of 220V is converted to 187V from the voltage converter 50 and applied to the compressor 20. do.

The room temperature sensing unit 40 includes a temperature resistance, that is, thermistor R _TH , and the thermistor R _TH is connected to the control unit 100 via the resistor R4.

When the control unit 100 receives a signal related to the room temperature from the room temperature sensing unit 40 through the input terminal, the controller 100 compares the signal with the set temperature set by the user, and the voltage switching switch unit when the room temperature and the set temperature are the same. By turning on the transistor Q1 by inputting a high signal to the base terminal of the transistor Q1 of (33), the first compression drive switch unit 31 is driven to cause the voltage converter 50 to reduce the reduced voltage. The control is applied to the compressor 20.

Hereinafter, the effect of the power saving device of the air conditioner according to the present invention having the configuration as described above will be described in detail with reference to FIG.

3 is a flowchart showing the operation of the air conditioner according to the present invention.

First, if it is determined that the power is applied in step S10 and the power is applied, the process proceeds to step S12 where the desired type and temperature of the desired operation, and the air volume and wind direction of the discharged air are set.

In step S14, the current indoor temperature is detected through the temperature sensor R _TH of the indoor temperature detecting unit 40. The controller 100 compares the input and detected values detected by the temperature sensor with the set temperature set by the user. That is, if it is determined in step S16 that the indoor temperature and the set temperature are the same, the flow advances to step S18.

In step S18, the control unit 100 outputs a high signal to the base terminal of the transistor Q1 of the voltage switching switch unit 33 to switch the contact of the relay switch RY1 from contact a to contact b. Accordingly, since the coil of the magnet switch MG1 of the first compression actuated switch unit 31 connected to the contact b of the relay switch RY1 becomes energized, the coil installed between the voltage converter 50 and the commercial AC power supply. 1 The compression driven switch unit 31 is turned on. Therefore, the voltage converter 50 converts the commercial AC power supply 220V to 187V and applies it to the compressor 20. As described above, when 187V is applied to and driven by the compressor 20, the power consumed by the compressor 20 is reduced by about 27% compared with when the commercial AC power source 220V is applied and the compressor 20 is driven. That is, when the input voltage of the compressor 20 drops by about 15%, the driving speed is lowered and the load current is reduced by about 13%. In this case, power consumption, P = 0.85 [V] * 0.87 [I] = 0.73 [VI]. Therefore, when the voltage of 187V is applied to the compressor 20, it has a power saving effect of about 27% compared to 220V.

If it is determined in step S16 that the room temperature and the set temperature are not the same value, the process proceeds to step S20 to determine whether the room temperature is equal to or greater than the set temperature. If the room temperature is equal to or higher than the set temperature, the process proceeds to step S22 where a low signal is input to the base terminal of the transistor Q1 of the voltage switching switch 33 with the power switch MG3 turned on. As a result, the contact state of the relay switch RY1 is switched from the b contact to the a contact so that the magnet switch MG1 of the first compression driven switch part 31 is turned off, and the magnet switch of the second compression driven switch part 32 is turned off. MG2 is turned on. Accordingly, a voltage of 220 V is supplied to the compressor 20.

When the indoor temperature is lower than the set temperature in step S20, the driving of the compressor 20 is stopped by turning off the power switch 34 to cut off the power applied to the compressor 20.

As described in detail above, the power saving device of the air conditioner according to the present invention has the effect of reducing the power consumption of the air conditioner by varying the voltage applied to the compressor in accordance with the change in the room temperature.

Claims (2)

The compressor 20 driven by receiving a voltage from a commercial AC power source, an indoor temperature sensing unit 40 for sensing an indoor temperature, and an indoor temperature detected by the indoor temperature sensing unit 40 and a set temperature set by a user are compared. In the air conditioner having a control unit 100 for controlling the drive speed of the compressor 20 according to the comparison result, the room temperature detected by the room temperature detection unit 40 is equal to the set temperature When the driving load of the compressor 20 is small, a voltage connected between the commercial AC power supply and the compressor 20 to reduce the voltage applied from the commercial AC power supply and supply the reduced voltage to the compressor 20. A conversion unit 50; A first compression driven switch unit 31 connected between the voltage converting unit 50 and the commercial AC power supply so that a commercial AC power can be supplied to the voltage converting unit 50; The front end is connected to the commercial AC power in parallel with the first compressor drive switch unit 31 so that the commercial AC power can be supplied to the compressor 20, and the second stage of the second compressor connected to the compressor 20. Drive switch unit 32; According to a comparison result between the room temperature and the set temperature, the control unit 100 may selectively supply the voltage reduced in the voltage conversion unit 50 and a voltage directly applied from a commercial AC power supply to the compressor 20. The first compression driven switch unit 31 and the second compression driven switch to selectively turn on the first compression driven switch unit 31 and the second compression driven switch unit 32 by a control signal of A power saving device for an air conditioner, characterized in that it comprises a voltage switching switch section 33 provided between the section (32). The method of claim 1, wherein the voltage switching switch 33, via the resistors (R1, R2) via one output terminal of the control unit 100 to be operated by the control signal of the control unit 100. A transistor of a predetermined DC power source and the transistor Q1 are formed such that a base Q is connected to the transistor Q1 and the transistor Q1 forms a magnetic field by a current supplied on and supplied by a control signal of the controller 100. The coil L1 connected to the collector terminal by a direct force and the control signal of the control unit 100 supply commercial AC power to the first compression drive switch unit 31 and the second compression drive switch unit 32. A contact point for connecting the second compression driven switch unit 32 and a commercial AC power supply and a b contact point for connecting the first compression driven switch unit 31 and a commercial AC power supply to Current flows in the coil L1 When the power saving device of the air conditioner which is characterized in that it comprises the connection relay switches (RY1) which state is switched to the contact b from the contact a.