KR20050055514A - Compressor motor driving and method in using refrigerator - Google Patents

Abstract

The present invention relates to a driving device and a method of a motor for a compressor employed in a refrigerator, in order to appropriately cope with load and voltage fluctuations, instead of adding a tap, by adding a relay to increase the winding mode, thereby changing the load and voltage fluctuations. Accordingly, the compressor motor is operated in the optimum winding mode to improve the operating efficiency. To this end, the present invention includes a current detector for detecting a current applied to the motor; A microcomputer for analyzing the detected current and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; A relay driver for outputting first and second relay driving signals for selecting first and second winding coils having different sizes to vary the number of windings of the motor coil by a control signal output from the microcomputer; ; The first and second relay driving signals are configured to include switching first and second relays to change the size of the motor coil.

Description

Compressor motor driving device and method used in refrigerators {COMPRESSOR MOTOR DRIVING AND METHOD IN USING REFRIGERATOR}

The present invention relates to a driving apparatus and method of a motor for a compressor employed in a refrigerator, and in particular, in order to appropriately respond to load and voltage fluctuations, instead of adding a tab, by adding a relay to increase the winding mode, the load and voltage In accordance with the variation, the present invention relates to a driving apparatus and method for a compressor motor employed in a refrigerator for operating a compressor motor in an optimum winding mode to improve driving efficiency.

In general, a reciprocating compressor (Reciprocating Compressor) has no friction loss because there is no crankshaft (Crankshaft) for converting the rotational motion to linear motion, the compression efficiency is higher than the general compressor in terms of compression efficiency.

When the reciprocating compressor is used in a refrigerator or an air conditioner, the compression ratio of the reciprocating compressor can be varied by varying the stroke voltage input to the reciprocating compressor, thereby freezing. Capacity can be controlled.

1 is a circuit diagram showing a configuration of a drive circuit of a conventional reciprocating compressor, which detects a load of a compressor and outputs a control signal for varying the capacity of the compressor according to the load. 1) and; A relay driver (2) for outputting a relay drive signal for varying the turns ratio of the motor windings (L1, L2) by a control signal output from the microcomputer (1); In accordance with the relay drive signal of the relay driver 2, a relay 3 is switched to switch the winding ratio of the motor windings L1.L2.

The microcomputer 1 detects a voltage and current applied to the compressor Comp, detects a current load using the voltage and current, and controls a control signal for varying the capacity of the compressor Comp based on the detection result. Is applied to the relay driver 2.

Accordingly, the relay driver 2 applies a relay drive signal for varying the winding ratio of the motor windings L1 and L2 to the relay 3 according to the control signal of the microcomputer 1, thereby relaying the relay ( 3) is switched by the relay drive signal to vary the turns ratio of the motor windings L1 and L2.

If the current load is greater than or equal to a certain load, the relay 3 is recognized as a 'S' terminal by recognizing it as a heavy load, and if the current load is less than or equal to the predetermined load, the relay 3 is recognized as a 'P' terminal. do.

That is, the above-described conventional apparatus drives the compressor in accordance with the operating conditions by fixing the capacitance of the capacitor used for LC resonance to a constant value, changing the inductance of the compressor motor by varying the motor windings of the compressor.

However, in the above-described conventional apparatus, in order to vary the inductance of the compressor motor, the winding mode used by configuring a tap on the motor winding is limited to two, and it is difficult to select the optimum winding mode according to the load or the voltage variation. That is, as shown in FIG. 2, when the number of turns of the motor coil is small, the harmonic loss is large and the motor efficiency is lowered. On the contrary, when the number of turns of the motor coil is large, there is a problem in that the stroke is short due to the lack of voltage.

Accordingly, an additional winding mode is required to operate at an appropriate number of turns as shown in (b) of FIG. There is this.

Accordingly, the present invention has been made in view of the above problems, and in order to properly cope with load and voltage fluctuations, instead of adding a tap, by adding a relay to increase the winding mode, according to the load and voltage fluctuations, It is an object of the present invention to provide a driving apparatus and method for a motor for a compressor that is employed in a refrigerator for operating a compressor motor in an optimum winding mode to improve operation efficiency.

The present invention for achieving the above object, the current detection unit for detecting a current applied to the motor; A microcomputer for analyzing the detected current and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; A relay driver for outputting first and second relay driving signals for selecting first and second winding coils having different sizes to vary the number of windings of the motor coil by a control signal output from the microcomputer; ; In response to the first and second relay drive signals, the first and second relays are switched to switch the size of the motor coil.

The present invention for achieving the above object, the initial start-up, the process of controlling the stroke by selecting the first winding coil and the second winding coil as a motor coil; Detecting a current applied to the motor and controlling a stroke for selecting the first winding coil as the motor coil if a section in which the detected current value is zero does not occur; Detecting a current applied to the motor and determining whether a section in which the detected current value is zero occurs; As a result of the determination, controlling the stroke by selecting the first winding coil and the second winding coil as the motor coil when the zero section is greater than or equal to a predetermined value; As a result of the determination, if a section in which the detected current value is zero does not occur, selecting a second winding coil as a motor coil to control a stroke; When the current applied to the motor is detected and the detected current value is zero, the interval is less than a predetermined value, characterized in that the first winding coil is selected as the motor coil to control the stroke.

The present invention for achieving the above object, the temperature detection unit for detecting the outside air temperature around the refrigerator; A microcomputer analyzing the outside temperature and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; A relay driver for outputting first and second relay driving signals for selecting first and second winding coils having different sizes to vary the number of windings of the motor coil by a control signal output from the microcomputer; ; The first and second relay driving signals may include first and second relays that are switched to change the size of the winding coil.

The present invention for achieving the above object, the process of detecting the outside air temperature of the refrigerator and comparing the outside temperature with the first and second reference temperature as the reference of the load; As a result of the comparison, if the outside temperature is less than the first reference temperature, recognizing a low load and selecting and operating the first winding coil and the second winding coil as motor coils; As a result of the comparison, if the outside temperature is greater than the first reference temperature and less than the second reference temperature, the step of recognizing the heavy load and selecting and operating the first winding coil as the motor coil; As a result of the comparison, when the outside temperature is greater than the second reference temperature, it is recognized as an overload, and the second winding coil is selected as the motor coil to be operated.

Hereinafter, with reference to the accompanying drawings the operation and effects of the embodiment of the driving apparatus and method for a compressor motor employed in the refrigerator of the present invention.

Figure 3 is a circuit diagram showing the configuration of an embodiment of a drive device for a motor for a compressor employed in the refrigerator according to the present invention.

As shown in Fig. 3, a current detecting unit 10 for detecting a current applied to the motor; A microcomputer (11) for analyzing the detected current and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; First and second relays for selecting first and second winding coils L1 and L2 having different sizes in order to vary the number of windings of the motor coil by the control signal output from the microcomputer 11. A relay driver 12 for outputting a driving signal; And the first and second relays 13 and 14 which are switched to switch the size of the motor coil by the first and second relay driving signals. Such operation of the present invention will be described.

First, at initial startup, the microcomputer 11 applies a control signal to the relay driver 12 to control the first winding coil L1 and the second winding coil L2 to be selected as a motor coil. Accordingly, the relay driver 12 receives the first and second relay driving signals for selecting the first and second winding coils L1 and L2 based on the control signal output from the microcomputer 11. 2 is applied to the relays 13 and 14.

Accordingly, the first and second relays 13 and 14 are switched to select the first winding coil L1 and the second winding coil L2 as motor coils.

At this time, the current detection unit 10 detects the current applied to the motor and applies the detected current to the microcomputer 11, and accordingly the microcomputer 11 analyzes the detected current to the analysis result. On the basis of this, a control signal for varying the number of turns of the motor coil is output.

That is, the microcomputer 11 operates by selecting the first winding coil L1 and the second winding coil L2 as a motor coil, and the detected current value is zero (Current Dead Time = 0: CDT) If this does not occur, a control signal for controlling the first winding coil L1 to be selected as a motor coil is output, and the first winding coil L1 is selected as a motor coil to operate. When the section CDT occurs, a control signal for controlling the second winding coil L2 to be selected as the motor coil is output, and the second winding coil L2 is selected as the motor coil to operate. If the section CDT having a value of zero is greater than or equal to the predetermined value α, a control signal for controlling the first winding coil L1 to be selected as the motor coil is output.

The predetermined value α is set to an optimum value for maximizing the driving efficiency of the motor by experiment, and is set to about 0.002 sec.

In detail, referring to FIG. 4, first, during initial startup, the first winding coil L1 and the second winding coil L2 are selected as motor coils to control the stroke (SP1 and SP2).

Next, when the current applied to the motor is detected and the section CDT having the value of the detected current is zero, the first winding coil L1 is selected as the motor coil to control the stroke (SP3 and SP4).

Then, the current applied to the motor is detected and it is determined whether a section in which the detected current value is zero occurs (SP5, SP6), and as a result of the determination (SP6), a section in which the detected current value is zero does not occur. When the section having the current value of zero is equal to or greater than a predetermined value (0.002 sec) (SP7), the first winding coil and the second winding coil are selected as motor coils to control the stroke.

On the other hand, if the section in which the detected current value is zero occurs in the determination result SP6, the second winding coil is selected as the motor coil to control the stroke (SP8, SP9), and the current applied to the motor is detected again. If the section in which the detected current value is zero is equal to or greater than the predetermined value α (0.002 sec), the first winding coil is selected as the motor coil to control the stroke.

Figure 5 is a block diagram showing the configuration of another embodiment of a drive device of the compressor-type motor of the present invention.

As shown in FIG. 5, the present invention includes a temperature detector 15 for detecting an outside air temperature around the refrigerator; A microcomputer (11) for analyzing the outside air temperature and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; First and second relays for selecting first and second winding coils L1 and L2 having different sizes in order to vary the number of windings of the motor coil by the control signal output from the microcomputer 11. A relay driver 12 for outputting a driving signal; In order to vary the size of the winding coil by the first and second relay driving signals, the first and second relays 13 and 14 are switched, and thus the operation of the present invention will be described. .

First, the temperature detector 15 detects the outside air temperature around the refrigerator and applies it to the microcomputer 11. Accordingly, the microcomputer 11 analyzes the outside air temperature and analyzes the temperature of the motor coil based on the analysis result. Outputs a control signal for varying the number of turns.

Then, the relay driver 12 may be configured to select first and second winding coils L1 and L2 having different sizes in order to vary the number of windings of the motor coil by the control signal of the microcomputer 11. The first and second relay drive signals are applied to the first and second relays 13 and 14.

Accordingly, the first and second relays 13 and 1 may simultaneously drive the first winding coil L1 or the second winding coil L2 or the first and second winding coils L1 and L2 into the motor coil. Is switched to select.

That is, when the outside temperature is less than the first reference temperature, the microcomputer 11 recognizes the low load, and controls to select the first winding coil L1 and the second winding coil L2 as the motor coil. If the outside temperature is greater than the first reference temperature and less than the second reference temperature, it is recognized as a heavy load and controls to select the first winding coil L1 as the motor coil. Recognize and control to select the second winding coil (L2) as a motor coil.

Here, the first and second reference temperatures are preset by an experiment to an optimum temperature at which the operating efficiency is the highest, and the first reference temperature is set to 30 ° C and the second reference temperature is about 45 ° C.

Referring to FIG. 6 in detail, first, the outside air temperature of the refrigerator is detected and the outside air temperature is compared with the first and second reference temperatures serving as the load reference (SP11, SP12).

As a result of the comparison, when the outside air temperature is lower than the first reference temperature, it is recognized as a low load, and the first winding coil L1 and the second winding coil L2 are selected as motor coils to operate (SP13, SP14). As a result of the comparison, when the outside temperature is greater than the first reference temperature and less than the second reference temperature, it is recognized as a heavy load and is operated by selecting the first winding coil L1 as a motor coil (SP15, SP16). If the outside temperature is greater than the second reference temperature, it is recognized as an overload and the second winding coil L2 is selected as the motor coil to operate (SP17, SP18).

That is, the present invention, in order to properly respond to the load and voltage fluctuations, instead of adding a tab, by adding a relay, by increasing the three winding modes of the conventional two winding mode, the optimum according to the load voltage variation It is operated in winding mode.

As described in detail above, in order to properly cope with load and voltage fluctuations, instead of adding a tap, the present invention increases the winding mode by adding a relay, thereby optimizing the compressor motor according to the load and voltage fluctuations. Operation in winding mode has the effect of improving the operating efficiency.

1 is a block diagram showing the configuration of a drive circuit of a motor for a compressor employed in a refrigerator according to the prior art.

2 is a waveform diagram showing the motor efficiency according to the number of turns of the motor coil.

Figure 3 is a block diagram showing the configuration of one embodiment of a drive device for a motor for a compressor employed in the refrigerator of the present invention.

Figure 4 is a flow chart showing the operation of one embodiment of a method for driving a motor for a compressor employed in the refrigerator of the present invention.

Figure 5 is a block diagram showing the configuration of another embodiment of a drive device for a compressor motor employed in the refrigerator of the present invention.

Figure 6 is a flow chart showing the operation of another embodiment of a method for driving a motor for a compressor employed in the refrigerator of the present invention.

* Description of the symbols for the main parts of the drawings *

10: current detection unit 11: microcomputer

12: relay drive part 13, 14: relay

Claims (11)

A current detector for detecting a current applied to the motor; A microcomputer for analyzing the detected current and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; A relay driver for outputting first and second relay driving signals for selecting first and second winding coils having different sizes to vary the number of windings of the motor coil by a control signal output from the microcomputer; ; And a first relay and a second relay which are switched in order to vary the size of the motor coil by the first and second relay driving signals. The driving device of the compressor motor of claim 1, wherein the number of turns of the first winding coil is larger than that of the second winding coil. The method of claim 1, wherein the microcomputer, A drive device for a compressor motor employed in a refrigerator, characterized in that for outputting a control signal for controlling the first winding coil and the second winding coil to be selected as a motor coil during initial startup. The method of claim 1, wherein the microcomputer, Selecting and operating the first winding coil and the second winding coil as a motor coil, and outputting a control signal for controlling to select the first winding coil as the motor coil when a section in which the detected current value is zero does not occur. A drive device for a motor for a compressor employed in a refrigerator, characterized in that. The method of claim 1, wherein the microcomputer, While operating by selecting the first winding coil as a motor coil, and outputting a control signal for controlling to select the first winding coil and the second winding coil as a motor coil when a section in which the value of the detected current is zero is more than a predetermined value, And a control signal for controlling the second winding coil to be selected as the motor coil if a section in which the value of the detected current is zero does not occur. The method of claim 1, wherein the microcomputer, The second winding coil is operated as a motor coil, and if a section in which the value of the detected current is zero is greater than or equal to a predetermined value, a control signal for controlling to select the first winding coil as the motor coil is output to the refrigerator. Driving device for compressor motor. Controlling the stroke by selecting the first winding coil and the second winding coil as motor coils at initial startup; Detecting a current applied to the motor and controlling a stroke for selecting the first winding coil as the motor coil if a section in which the detected current value is zero does not occur; Detecting a current applied to the motor and determining whether a section in which the detected current value is zero occurs; As a result of the determination, controlling the stroke by selecting the first winding coil and the second winding coil as the motor coil when the zero section is greater than or equal to a predetermined value; As a result of the determination, if a section in which the detected current value is zero does not occur, selecting a second winding coil as a motor coil to control a stroke; When the current applied to the motor is detected and the detected current value is zero, the section of the compressor motor employed in the refrigerator, characterized in that by performing a process of controlling the stroke by selecting the first winding coil as a motor coil. Driving method. A temperature detector detecting an outside air temperature around the refrigerator; A microcomputer analyzing the outside temperature and outputting a control signal for varying the number of turns of the motor coil based on the analysis result; A relay driver for outputting first and second relay driving signals for selecting first and second winding coils having different sizes to vary the number of windings of the motor coil by a control signal output from the microcomputer; ; And a first relay and a second relay which are switched in order to vary the size of the winding coil according to the first and second relay driving signals. The driving device of the compressor motor of claim 8, wherein the number of turns of the first winding coil is larger than that of the second winding coil. The method of claim 8, wherein the microcomputer, If the outside air temperature is less than the first reference temperature, the control to select the first winding coil and the second winding coil as the motor coil, When the outside temperature is greater than the first reference temperature and less than the second reference temperature, the control unit selects the first winding coil as the motor coil, And the second winding coil is selected as the motor coil when the outside temperature is greater than the second reference temperature. Detecting the outside air temperature of the refrigerator and comparing the outside air temperature with the first and second reference temperatures serving as a load reference; As a result of the comparison, if the outside temperature is less than the first reference temperature, recognizing a low load and selecting and operating the first winding coil and the second winding coil as motor coils; As a result of the comparison, if the outside temperature is greater than the first reference temperature and less than the second reference temperature, the step of recognizing the heavy load and selecting and operating the first winding coil as the motor coil; As a result of the comparison, when the outside air temperature is greater than the second reference temperature, it is recognized as an overload and the second winding coil is selected as the motor coil.