KR20010048698A - circuit for controlling starting current for compressor for air conditioner - Google Patents

Abstract

PURPOSE: A start current control circuit of a compressor is provided to prevent a bad effect of other peripheral equipments due to initial excess current by limiting the current through control of voltage waveform supplied to a compressor. CONSTITUTION: A control unit(10) repeats voltage feed and isolation as well as outputs a start control signal for raising a voltage cycle gradually. When the control unit outputs a high signal, a light emitting unit of a phototriac(41) emits light and a light receiving unit receives the light. A triac(42) is turned and power is fed to a contact point(C) therethrough to raise an electric current(I). If the control unit outputs a low signal, the light emitting unit stops emitting light and the triac is turned off. The electric current is divided into two currents(I1,I2) during turning on of the triac but isolated during turning off. Thereby, the electric current flows intermittently. The control unit limits an electric current by controlling waveform of voltage fed to a compressor through repeated feed and isolation of voltage. Therefore, the control unit prevents a bad effect of other peripheral equipments due to initial excess current.

Description

Compressor starting current control circuit of air conditioner {circuit for controlling starting current for compressor for air conditioner}

The present invention relates to a control circuit for reducing the starting current at the start of the compressor of the air conditioner, and in particular, the initial current is limited by the current supplied to the compressor by repeating voltage supply and voltage interruption for a predetermined time. The present invention relates to a starting current control circuit of an air conditioner for preventing adverse effects of peripheral devices.

As shown in FIG. 1, a compressor starting current control circuit of a conventional air conditioner includes a power supply coil RYP through which a current flows in accordance with a compressor control signal of a controller 10, and a power supply open contact SWP connected to one side of a power supply. A power supply unit 20 formed of a power relay; A coil L, a driving capacitor Cr and a starting capacitor Cs connected in parallel to the other side of the power source; A starting opening contact SWS1 connected to the other side of the power supply in parallel with the starting capacitor Cs, and a starting closing contact connected in series between the other side of the starting capacitor Cs and the other side of the power opening contact SWP ( A start relay composed of SWS2) and a start coil (RYS); The drive open contact SWR connected in parallel with the coil L to the other side of the power supply, and the drive coil RRY connected between the other side of the start open contact SWS1 and the other side of the power open contact SWP. A driving relay consisting of; The other side of the drive capacitor Cr is connected to the contact point A between the start close contact SWS2 and the start coil RYS, and is connected between the contact point A and the other side of the power supply open contact SWP. Compressor consisting of a compressor starting coil 31 and a compressor driving coil 32 connected between the coil L and the other side contact B of the driving opening contact SWR and the other side of the power opening contact SWP. It consists of 30.

The operation of the compressor starting current control circuit of the conventional air conditioner is as follows.

First, when the control unit 10 outputs the compressor control signal to drive the compressor 30, current flows through the power supply coil RYP, and when the predetermined voltage is applied to the power supply coil RYP, the power opening contact SWP is' Come on '.

When the power opening contact (SWP) is 'on', power is applied to the compressor driving coil 32 through the coil (L), the compressor starting coil (31) through the driving capacitor (Cr) and the starting capacitor (Cs). And power is supplied to the starting coil (RYS).

When the predetermined voltage is applied to the starting coil RYS, the starting closing contact SWS2 is 'off', and the starting opening contact SWS1 is 'on'.

When the start opening contact SWS1 is 'on', power is supplied to the driving coil RRY, and at the same time, power is supplied to the compressor starting coil 31 and the starting coil RYS only through the driving capacitor Cr. .

When a predetermined voltage is applied to the driving coil RRY, when the driving opening contact SWR is 'on', power is directly supplied to the compressor driving coil 32 to drive the compressor normally.

That is, in the conventional start-up, power is supplied to the compressor driving coil 32 through the coil L, so that the current flowing through the compressor driving coil 32 is reduced to reduce the peak current and flows into the compressor starting coil 31. Increase the starting torque to increase the current. In the normal driving after starting, the coil L is removed by the driving opening contact SWR, and the power is directly supplied to the compressor driving coil 32 without passing through the coil L.

Compressor starting current control circuit of the conventional air conditioner does not significantly reduce the starting current at initial start-up, adversely affects peripheral devices at the initial start, and has a problem in that it does not cope with the limit specification for starting current.

An object of the present invention is to solve the conventional problems, and in particular, by controlling the waveform of the voltage supplied to the compressor by repeating the voltage supply and the voltage interruption for a predetermined time during initial start-up to limit the current and other peripherals due to the initial transient current It is to provide a starting current control circuit of an air conditioner to prevent the adverse effects of the preliminary effect and to cope with the limiting specification for starting current.

Compressor starting current control circuit of the air conditioner of the present invention is connected to one side of the power supply, the power supply for supplying power in accordance with the first compressor drive signal input from the control unit; A driving capacitor and a starting capacitor connected in parallel to the other side of the power supply; A start relay comprising a start close contact and a start coil connected in series between the other side of the start capacitor and the other side of the power supply; The other side of the drive capacitor is connected to the contact between the starting and closing contact point and the starting coil, and is connected between the compressor starting coil connected between the contact point and the other side of the power supply section, between the other side of the power supply and the other side of the power supply section. In the compressor starting current control circuit of the air conditioner consisting of a compressor consisting of a compressor drive coil, it is connected between the other side of the power supply and the contact (C) of the drive capacitor, the start capacitor and the compressor drive coil, input from the control unit And a voltage variable unit configured to vary a voltage supplied through the contact point C according to the second compressor driving signal, wherein the controller repeats the voltage supply and the voltage cutoff, which are the second compressor driving signal, for a predetermined time. At the same time, the start control signal is outputted so that the voltage period is gradually increased during the supply of voltage, and then the voltage And a characterized in that it outputs a drive control signal.

1 is a circuit diagram showing the configuration of a conventional compressor starting current control circuit;

2 is a circuit diagram showing a configuration of the present invention;

3 is a waveform diagram of each part of FIG. 2;

<Description of the reference numerals for the main parts of the drawings>

10: control unit 20: power supply unit

RYP: Power coil SWP: Power open contact

RYS: Starting coil SWS1: Starting open contact

SWS2: Closed contact RYR: Driven coil

SWR: Drive open contact Cr: Drive capacitor

Cs: Starting Capacitor L: Coil

C: capacitor R: resistance

30 compressor 31 compressor start coil

32: compressor drive coil 40: power supply variable part

41: phototriac 42: triac

An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the compressor starting current control circuit of the air conditioner of the present invention includes a power supply coil RYP through which a current flows according to the first compressor driving signal of the controller 10, and a power supply open contact connected to one side of the power supply. A power supply unit 20 formed of a power relay (SWP); A driving capacitor Cr and a starting capacitor Cs connected in parallel to the other side of the power supply; A start relay comprising a start closing contact SWS2 and a start coil RYS connected in series between the other side of the start capacitor Cs and the other end of the power supply open contact SWP; The other side of the drive capacitor Cr is connected to the contact point A between the start close contact SWS2 and the start coil RYS, and is connected between the contact point A and the other side of the power supply open contact SWP. Compressor starting current control circuit of an air conditioner comprising a compressor starting coil 31 and a compressor 30 consisting of a compressor driving coil 32 connected between the other side of the power supply and the other side of the power opening contact SWP. In the power supply and between the driving capacitor Cr, the starting capacitor Cs, and the contact C of the compressor driving coil 32, in accordance with the second compressor driving signal of the controller 10. And a voltage variable part 40 for varying the voltage supplied through the contact point C. The controller 10 repeats the voltage supply and the voltage cutoff, which are the second compressor driving signals, for a predetermined time. A starting agent for gradually increasing the voltage period during the voltage supply Outputting the signal, and then outputs a drive control signal for the supply voltage continuously.

In addition, the voltage variable part 40 is connected to a light emitting part that emits light according to the second compressor driving signal of the controller 10, and when the light emission signal is received, one side is connected to the contact point C through a resistance. The phototrial liquid 41 which consists of a light receiving part, the 1st terminal T1 connected to the other side of the said power supply, the 2nd terminal T2 connected to the said contact point C, and the said phototrial liquid 41 Between the triac 42 made up of a gate G connected to the other side of the light receiving unit and connected to the other side of the power supply through a resistor, and between the second terminal T2 and the first terminal T1 of the triac 42. It consists of a capacitor C and a resistor R connected in series.

The operation of the present invention will be described in detail with reference to FIGS. 2 and 3 as follows.

First, when the starting and closing contact SWS2 is 'on' (when initial starting) and when the starting and closing contact SWS2 is 'off' (normally driving), the compressor starting coil 3 and the compressor driving coil 31 are used. Comparing the current flowing in is as follows.

When start closing contact (SWS2) is 'on' (initial start) The resistance value of drive capacitor (Cr) and start capacitor (Cs) is the value when start closing contact (SWS2) is 'off' (normal drive) It is smaller than the resistance value of the driving capacitor Cr. Therefore, the current I1 flowing through the starting coil RYS and the compressor starting coil 31 at the time of initial startup is larger than during normal driving. Accordingly, the current I2 flowing through the compressor drive coil 32 at the initial startup is smaller than during normal driving.

The control unit 10 applies a first compressor driving signal to the power supply unit 20 through the first output terminal P1 to drive the compressor 30. Accordingly, when a current flows through the power supply coil RYP of the power supply unit 10 and a predetermined voltage is applied to the power supply coil RYP, the power supply opening contact SWP is 'on'.

In the state where the power opening contact SWP is 'on', the controller 10 controls the second compressor to the voltage variable part 40 through the second output terminal P2 to change the voltage supplied to the compressor 30. The driving signal is output, and the current I flowing through the contact C, which is the sum of the current I1 and the current I2, is varied.

The control of the controller 10 with respect to the voltage variable unit 40 is divided into an initial start time and a normal drive time as follows.

First, at initial startup, the controller 10 repeats the voltage supply and the voltage cutoff for a predetermined time as the second compressor drive signal, and outputs a start control signal for gradually increasing the voltage period during the voltage supply.

When the control unit 10 outputs a high signal to the second output terminal P2, the light emitting portion of the phototriac 41 emits light, and the light is received by the light receiving portion to supply a voltage to the gate G of the triac 42. This is applied to the triac 42 'on'. As a result, power is supplied to the contact point C through the triac 42 so that the current I increases.

In addition, when the control unit 10 outputs a low signal to the second output terminal P2, the light emitting part of the phototriac 41 stops emitting light, and thus no voltage is applied to the gate G of the triac 42. The liquid 42 is 'off'.

As shown in FIG. 3A, at initial startup, the controller 10 transmits a high signal for n1 cycles, a low signal for t1 hours, a high signal for n2 cycles, and a t2 time through the second output terminal P2. Output a low signal.

Accordingly, upon initial start-up, as shown in FIG. 3 (b) through the triac 42 according to the 'on' / 'off' of the triac 42, a voltage of n1 cycles is applied for t1 hours. The voltage is cut off, n2 cycles of voltage are applied again, and the voltage is cut off for t2 hours.

Accordingly, the current I supplied to the contact point C at the initial startup is divided into the current I1 and the current I2 while the triac 42 is' on ', and the triac 42 is' While it is off, it is interrupted so that the current I flows intermittently.

At the initial startup, the start control signal of the control unit 10 varies the number of cycles of voltage n and the cutoff time t so that a constant voltage is applied to the start coil RYS to open the start closing contact SWS2. Set the same as or before / after.

As described above, the present invention limits the current by controlling the waveform of the voltage supplied to the compressor by repeating the voltage supply and the voltage interruption for a predetermined time during the initial startup, thereby preventing the adverse effect of other peripheral devices caused by the initial transient current and preventing the startup. Can cope with the current limit specification.

On the other hand, during normal driving, the controller 10 outputs the start control signal as described above for a predetermined time as the second compressor drive signal, and then outputs the drive control signal for supplying voltage continuously.

That is, the controller 10 continuously outputs a high signal to the second output terminal P2, whereby the phototriac 41 is 'on' and the triac 42 is 'on' so that the triac 42 As shown in FIG. 3 (b) through), a continuous voltage is supplied to allow the compressor 30 to operate normally.

In addition, when the compressor 30 is stopped, the control unit 10 outputs a first compressor driving signal for stopping the compressor to the power supply unit 20 to 'off' the power opening contact (SWP), and then the voltage variable unit. A second compressor driving signal for stopping the compressor is output to 40 to stop the light emission of the phototrial liquid 41 to turn off the triac 42 to stop the compressor 30.

Compressor starting current control circuit of the air conditioner of the present invention is a control circuit for reducing the starting current at the start of the compressor of the air conditioner, in particular during the initial start-up of the voltage supplied to the compressor by repeating the voltage supply and voltage cutoff for a predetermined time By limiting the current by controlling the waveform, it is useful to prevent the adverse effects of other peripheral devices due to the initial transient current and to cope with the limit on the starting current.

Claims (2)

A power supply unit connected to one side of the power supply and supplying power according to the first compressor driving signal input from the control unit; A driving capacitor and a starting capacitor connected in parallel to the other side of the power supply; A start relay comprising a start close contact and a start coil connected in series between the other side of the start capacitor and the other side of the power supply; The other side of the drive capacitor is connected to the contact between the starting and closing contact point and the starting coil, and is connected between the compressor starting coil connected between the contact point and the other side of the power supply section, between the other side of the power supply and the other side of the power supply section. In the compressor starting current control circuit of the air conditioner consisting of a compressor consisting of a compressor driving coil, It is connected between the other side of the power supply and the contact (C) of the drive capacitor, the starting capacitor and the compressor driving coil, and varies the voltage supplied through the contact (C) in accordance with the second compressor driving signal input from the control unit It is configured to include a voltage variable part, The control unit repeats the voltage supply and the voltage cut-off, which are the second compressor driving signals, for a predetermined time, and outputs a start control signal for gradually increasing the voltage period when the voltage is supplied, and then continuously supplies the voltage. Compressor starting current control circuit of the air conditioner, characterized in that for outputting a control signal. The method of claim 1, wherein the voltage variable portion A phototriac including a light emitting unit emitting light according to the second compressor driving signal of the control unit, a light receiving unit which is turned on when the light emitting signal is received, and is connected to the contact point C through one side of the resistor; A triac consisting of a first terminal connected to the other side of the power supply, a second terminal connected to the contact point C, and a gate connected to the other side of the light receiving portion of the phototriac and connected to the other side of the power supply through a resistor; Compressor starting current control circuit of the air conditioner, characterized in that consisting of.