KR20010057481A - Operation control method for linear compressor - Google Patents

Abstract

PURPOSE: A control method of operation of a linear compressor is provided to easily manage a linear compressor by making possible single sale of the compressor. CONSTITUTION: A method for controlling operation of a linear compressor comprises the steps of: detecting stroke and speed of a compressor and phase of current supplied to a compressor; limiting compressor stroke in 18mm if the detected stroke, speed and current phase are less than first reference values; controlling stroke in 19mm or 20mm if the detected values are higher than the first reference values and less than second reference values or higher than the second reference values and less than third reference values; controlling stroke in 20mm if the detected values are higher than the third reference values; and exiting a zone where vibration occurs by controlling clearance between a piston top dead center of the compressor and a discharge valve if vibration occurs in stroke control. As independent control is possible, single sale of a compressor is possible. Therefore, management is easy.

Description

Operation control method of linear compressor {OPERATION CONTROL METHOD FOR LINEAR COMPRESSOR}

The present invention relates to an operation control method of a linear compressor for controlling the stroke of the linear compressor according to the load, and in particular, to estimate the load by detecting the stroke or phase of the speed and current, and to control the stroke according to the estimated load. It relates to a driving control method of a linear compressor for.

Linear compressors are known to have better efficiency than other compressors. In addition, when the linear compressor is used in a refrigerator or an air conditioner, the compression ratio can be varied as the stroke is varied, so that the linear compressor can be used for the variable cooling power control and the instantaneous load estimation is possible.

The operation of the linear compressor used in the refrigerator or the air conditioner is as follows.

1 is a block diagram of a control apparatus of a conventional linear compressor. As shown in FIG. 1, a compressor 10 for adjusting a cooling force by varying a stroke by a vertical movement of a piston, and an AC power input according to a switching signal. An electric circuit unit 20 for controlling the power applied to the compressor 10 by intermittent, a current detector 40 for detecting a current applied to the compressor 10, and a voltage between both ends of the compressor 10 A stroke calculation unit 50 for calculating a stroke using the voltage detection unit 30, the current i detected by the current detection unit 40 and the voltage V detected by the voltage detection unit 30, The microcomputer 60 is configured to control the stroke calculated by the stroke calculating unit 50 according to the outside temperature.

Looking at the prior art configured in this way in detail as follows.

When 220V AC power is supplied from the power supply voltage terminal, the AC power is supplied to the linear compressor 10 through the current sensing resistor R of the electric circuit unit 20 and the switch element SW.

Accordingly, current flows through the linear compressor 10.

Then, the piston of the linear compressor 10 reciprocates, and the reciprocating stroke distance of the piston is a stroke, and the stroke is varied to vary the cooling force.

That is, the cold power of the refrigerator or the air conditioner is adjusted.

At this time, when the user sets the temperature of the refrigerator or the air conditioner, a stroke instruction value proportional to the set temperature information is input to the microcomputer 60.

Then, the microcomputer 60 controls the current supplied to the compressor 10 by turning on or off the switch element SW of the electric circuit unit 20 according to the input stroke instruction value.

At this time, the current detector 40 detects an input current i supplied to the compressor 10 through the current sensing resistor R and provides the stroke current to the stroke calculator 50, and the voltage detector 30 provides the compressor ( The voltage V across both ends is detected and provided to the stroke calculating unit 50.

Accordingly, the stroke calculator 50 calculates a stroke by using the current i and the voltage V provided by the two detectors 30 and 40.

Where V _M is the voltage across the compressor, Rac is the body resistance in the compressor, i is the inrush current, and L is the reactance.

Then, the microcomputer 60 controls the stroke calculated by the stroke calculator 50 according to the outside air temperature of the load, which will be described below with reference to FIG. 2.

First, the outside temperature is read from the temperature sensor installed outside the load.

At this time, the outside temperature read is classified into four stages. That is, when it is 7 degrees or less, when it is between 7 degrees-15 degrees, when it is between 15 degrees-35 degrees, it classifies as 37 degrees or more.

When the outside air temperature classified above is 7 degrees or less, the microcomputer 60 controls the turn-on time of the switch element SW of the electric circuit unit 20 to control the stroke to 18 mm, and is applied to the compressor 10. To control.

When the outside air temperature is between 7 degrees and 15 degrees, the microcomputer 60 checks whether a shaking phenomenon occurs between 18 and 22 mm of the strokes calculated by the stroke calculating section 50.

As a result of the check, if the shaking does not occur, the turn-on time of the switch element SW of the electric circuit unit 20 is increased to increase the voltage supplied to the compressor 10 to control the stroke to 19 mm. To increase.

The shaking phenomenon is a phenomenon in which the stroke does not converge well and the stroke continuously changes rather than converges to the value to be controlled.

Therefore, when the microcomputer 60 determines that a tremor has occurred between 18 and 22 mm of stroke, the top clearance between the piston top dead center of the compressor and the discharge valve is set at a predetermined distance so as to escape the area where the tremor occurs. In order to maintain it, the turn-on time of the switch element SW is adjusted to decrease or increase the voltage supplied to the compressor 10 to control the stroke top dead center.

In addition, when the outside air temperature is between 15 degrees and 35 degrees, the microcomputer 60 checks whether a shaking phenomenon occurs between 18 and 22 mm of the strokes calculated by the stroke calculating unit 50.

As a result, if shaking does not occur, the turn-on time of the switch element SW of the electric circuit unit 20 is further increased to control the stroke to 20 mm, thereby increasing the voltage supplied to the compressor 10 to Increase speed

Then, if a tremor occurs, the microcomputer 60 turns on the turn-on time of the switch element SW to maintain the top clearance between the piston top dead center of the compressor and the discharge valve at a constant distance so that the stroke leaves the area. By adjusting the control unit to control the stroke top dead center by reducing or increasing the voltage supplied to the compressor 10.

Finally, when the outside temperature is 37 degrees or more, the microcomputer 60 adjusts the turn-on time of the switch element SW of the electric circuit unit 20 so as to constantly control the stroke calculated by the stroke calculating unit 50 to 20 mm. To control the voltage applied to the compressor 10.

After the voltage applied to the compressor 10 is controlled, it is checked whether the shaking phenomenon occurs. If the shaking phenomenon does not occur, the control is continuously performed with a stroke of 20 mm. When the shaking phenomenon occurs, the region where the shaking phenomenon occurs is generated. In order to maintain the top clearance between the piston top dead center of the compressor and the discharge valve to a certain distance, the turn-on time of the switch element SW is adjusted to decrease or increase the voltage supplied to the compressor 10 Take control to adjust the point.

As described above, the external temperature of the load is sensed, the stroke is controlled according to the sensed ambient temperature, and if a tremor occurs in the stroke, the top clearance is controlled so as to move out of the region where the tremor occurs. Adjust it.

However, in the prior art as described above, the load is sensed by sensing the outside temperature of the load, and the cooling force of the load is adjusted by adjusting the stroke of the linear compressor according to the estimated load. In this case, since the compressor operates according to the load, there is a problem in that it is impossible to sell a single product, and there is a difficulty in managing a single product.

Therefore, an object of the present invention for solving the conventional problems as described above is to provide a method for controlling the operation of a linear compressor to be sold separately of the compressor.

Another object of the present invention is to provide a method for controlling the operation of a linear compressor, which enables the sale of a single unit of the compressor, thereby facilitating management.

1 is a block diagram of a control device of a general linear compressor.

2 is a flowchart illustrating an operation control method of a conventional linear compressor.

3 is a flowchart illustrating an operation control method of the linear compressor according to the present invention.

***** Explanation of symbols for the main parts of the drawing *****

10: linear compressor 20: electric circuit part

30: voltage detector 40: current detector

50: stroke calculation unit 60: microcomputer

The present invention for achieving the above object is a first step of detecting the stroke or speed of the compressor and the phase of the current supplied to the compressor at regular intervals, and the second stroke to be controlled by a predetermined stroke in accordance with the detected phase And a third step of adjusting the top clearance between the piston top dead center of the compressor and the discharge valve so as to be out of the region where the vibration occurs when the vibration occurs during the stroke control.

Hereinafter, with reference to the accompanying drawings in detail as follows.

3 is an operation flowchart of an operation control method of the linear compressor according to the present invention. As shown in FIG. 1, a first step of detecting a stroke or speed of a compressor and a phase of a current supplied to the compressor, and If the phase of the current is less than or equal to the first set value a, the second step of controlling the stroke to 18 mm; and the phase of the stroke or speed and the current is greater than the first set value a and greater than the second set value b. Less than or greater than the second set value (b) and less than the third set value (c), the third step of controlling the stroke to 19 mm or 20 mm; and the phase of the stroke or speed and current is the third set value (c). If abnormal, the fourth step of controlling the stroke to 20mm, and if the vibration phenomenon occurs during the stroke control in the above, by adjusting the top clearance between the piston top dead center and the discharge valve of the compressor to move out of the region where the vibration phenomenon occurs The fifth step is made.

When described in detail with respect to the operation and effect of the present invention made of each step as follows.

The switching element SW of the electric circuit unit 20 is turned on or off according to the stroke instruction value input to the microcomputer 60 to adjust the current and voltage supplied to the compressor 10.

Accordingly, current flows through the linear compressor 10.

Then, the piston of the linear compressor 10 reciprocates, and the reciprocating stroke distance of the piston is a stroke, and the stroke is varied to vary the cooling force.

When the piston of the compressor 10 reciprocates and the stroke is varied, the voltage detector 30 and the current detector 40 detect the voltage across the compressor 10 and the current supplied to the compressor to calculate the stroke. Provided by 50.

Therefore, the stroke calculator 50 calculates a stroke by using a current and a voltage, and transfers the calculated stroke to the microcomputer 50.

Then, the microcomputer 60 detects the phase of the stroke (or speed) calculated by the stroke calculating unit 50 and the current flowing through the compressor 10 at predetermined intervals.

If the detected phase of the stroke and current is smaller than the first set value (a), the microcomputer 60 adjusts the turn-on time of the switch element SW of the electric circuit unit 20 to control the stroke to 18 mm. The voltage applied to the compressor 10 is controlled.

When the phase of the stroke (or speed) and the current is larger than the first set value a and smaller than the second set value b, the microcomputer 60 is 18 to 22 mm among the strokes calculated by the stroke calculating unit 50. Check if there is any tremor in between. Here, the first set value a is smaller than the second set value b.

As a result of the check, if the shaking does not occur, the speed of the compressor is increased by increasing the turn-on time of the switch element SW of the electric circuit unit 20 to control the stroke to 19 mm.

In addition, when the vibration occurs, the turn-on time of the switch element SW is adjusted to maintain the top clearance between the piston top dead center of the compressor and the discharge valve at a predetermined distance so as to escape the region where the vibration occurs. The voltage supplied to the compressor 10 is reduced or increased to control the stroke top dead center.

In addition, if the phase of the stroke (or speed) and the current is larger than the second set value (b) and smaller than the third set value (c), the microcomputer 60 performs 18 to 18 of the strokes calculated by the stroke calculating section 50. Check if there is a tremor between 22mm. However, the second set value b is set smaller than the third set value c.

As a result of the check, if the shaking does not occur, the turn-on time of the switch element SW of the electric circuit unit 20 is further increased in order to control the stroke to 20 mm, thereby increasing the speed of the compressor.

Then, if a tremor occurs, the microcomputer 60 turns on the turn-on time of the switch element SW to maintain the top clearance between the piston top dead center of the compressor and the discharge valve at a constant distance so that the stroke leaves the area. By adjusting the control unit to control the stroke top dead center by reducing or increasing the voltage supplied to the compressor 10.

Finally, if the phase of the stroke (or speed) and current is greater than the third set value (c), the microcomputer 60 controls the electric circuit section 20 so as to constantly control the stroke calculated by the stroke calculating section 50 to 20 mm. The stroke of the compressor is controlled to supply a voltage of 3.3V to the compressor 10 by adjusting the turn-on time of the switch element (SW).

After controlling the voltage supplied to the compressor 10, it is checked whether the shaking phenomenon occurs. If the shaking phenomenon does not occur, the control is continuously performed with a stroke of 20 mm. When the shaking phenomenon occurs, the region where the shaking phenomenon occurs is generated. In order to maintain the top clearance between the piston top dead center of the compressor and the discharge valve to a certain distance, the turn-on time of the switch element SW is adjusted to decrease or increase the voltage supplied to the compressor 10 Take control to adjust the point.

As described above, the load is estimated by using the stroke of the compressor and the phase of the current supplied to the compressor (twice), and the compressor follows the load by itself so as to control the stroke of the compressor according to the estimated load. By adjusting according to the load applied, it can operate independently.

As a result, single sale of the compressor is possible.

In addition, since the compressor can be sold separately, it is easy to manage the compressor.

As described in detail above, the present invention detects the phase of the compressor stroke and the current to follow the current load, and controls the compressor stroke according to the following load condition, so that independent control is possible. It is possible to make it easy to manage and to estimate the instantaneous load.

Claims (1)

A first step of detecting a stroke or speed of the compressor and a phase of a current supplied to the compressor at a predetermined cycle, a second step of controlling the stroke by a preset stroke according to the detected phase, and vibration during stroke control And a third step of adjusting the top clearance between the piston top dead center of the compressor and the discharge valve so as to deviate from the region where the vibration occurs when the phenomenon occurs.