JPH0926246A - Control device for refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To restrict a peak value in an inverter circuit temperature in a control method for a control device for controlling the number of rotations of a compressor under an operation of the inverter by a method wherein when a surrounding air temperature of a refrigerator is high, its power supply is turned on, an operation of a refrigerator fan is stopped for a specified period of time after a specified period of time elapses. SOLUTION: When a surrounding air temperature of a refrigerator sensed by a surrounding air temperature sensor 21 is high, a timer A20 turns on a power supply, an operation of a refrigerator fan is stopped for a specified period of time after a specified period of time elapses, then a timer B22 further stops an operation of the refrigerator fan for a specified period of time after specified period of time elapses, thereby a current of a compressor is controlled in such a way that a peak value of an inverter circuit temperature is restored.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device for a refrigerator, and more particularly to a control method for starting a control device for controlling the rotation speed of a compressor by an inverter.

[0002]

2. Description of the Related Art In a refrigerator, the current flowing through the compressor is the largest for several hours after the power is turned on under the condition that the inside temperature and the outside air temperature are high.

Therefore, in general, after the power is turned on for a certain time, the operation of the internal fan is stopped for a certain time so that the current flowing through the compressor is reduced and the temperature protection of the compressor is operated. Instead, the refrigerator is controlled to cool the inside.

Therefore, in the case of controlling the rotation speed of the compressor by the inverter, even when the heat sink of the inverter circuit is determined, the temperature of the semiconductor switch is kept for several hours after the power is turned on under the condition that the inside temperature and the outside air temperature are high. A costly, large heatsink is required unless devised to deactivate the protection.

Such a conventional refrigerator controller is disclosed in, for example, Japanese Patent Laid-Open No. 62-10572.

This feature is that the current flowing through the compressor is reduced by operating the compressor at a low rotation speed for a certain period after the power is turned on.

[0007]

However, in the above-mentioned configuration, if the number of rotations is too low, the refrigerating capacity for cooling the inside of the refrigerator under high temperature and outside air temperature is insufficient. It is not possible to drive at low speeds.

For this reason, the peak current of the compressor cannot be suppressed so much that the heat sink of the inverter circuit needs to be large, which causes a problem of high cost.

In view of the above-mentioned problems, the present invention, when the outside air temperature of the refrigerator is high, stops the operation of the internal fan for a fixed time after the power is turned on, and then stops the operation of the internal fan for a fixed time. By stopping the operation for a certain period of time, the compressor current can be controlled so as to suppress the peak value of the inverter circuit temperature, the heat sink of the inverter circuit can be made small, and the cost can be reduced.

Further, by detecting the temperature of the semiconductor switch,
After turning on the power for a fixed time, after stopping the operation of the internal fan for a fixed time, a predetermined temperature t1
When the temperature becomes higher, by stopping the internal fan until the temperature drops to a predetermined temperature t2, the heat sink can be made smaller, the cost can be reduced, and the internal fan stop time can be shortened. Therefore, the temperature inside the refrigerator can be cooled more quickly.

When the outside air temperature of the refrigerator is high, after the power is turned on for a certain time, the operation of the internal fan is stopped for a certain time, and then the chopping is performed to change the rotation speed of the DC motor for a certain time. By lowering the frequency of the chopping signal for performing, the heat sink can be made smaller, the cost can be reduced, and it is not necessary to stop the fan inside the refrigerator other than preventing the temperature protection operation of the compressor. The temperature can be cooled faster.

Further, by detecting the temperature of the semiconductor switch,
After turning on the power for a certain time, after stopping the operation of the internal fan for a certain time, a predetermined temperature t5 is reached.
When the temperature becomes higher, the frequency of the chopping signal is lowered until the temperature drops to a predetermined temperature t6, so that the heat sink can be made smaller and the cost can be reduced, and the temperature protection operation of the compressor can be prevented. Since it is not necessary to take a fan stop time, the temperature inside the refrigerator can be cooled more quickly, and the time for lowering the frequency of the chopping signal can be shortened, resulting in power saving.

[0013]

To achieve this object, a refrigerator controller according to the present invention comprises an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected,
A heat sink that cools the inverter circuit, a DC motor that operates by the inverter circuit, a compressor that is driven by the DC motor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, and the cooling. An internal fan for flowing cold air cooled by a container into a freezer, and an internal fan operating means for operating the internal fan,
A timer A that outputs a fan stop signal to the internal fan operating means for a certain time after the power is turned on, a position detecting means that detects the position of the rotor of the DC motor, and the output based on the output of the position detecting means. A commutation unit that outputs a commutation pulse that determines the operation of the semiconductor switch of the inverter circuit,
Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the position detection means, and chopping signal generation means A for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable. A synthesizing means for synthesizing the commutation pulse and the chopping signal, a driving means for turning on / off a semiconductor switch of the inverter circuit by an output of the synthesizing means, and an outside air temperature sensor for detecting an ambient temperature of the refrigeration cycle. And a timer B that outputs a stop signal to the internal operating means for a certain period of time after the fan stop signal of the timer A ends for a certain period of time when the detected outside air temperature is higher than a predetermined temperature. Is.

Further, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and the DC motor. Driven by a compressor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that allows cold air cooled by the cooler to flow into a freezer, and the in-compartment fan And a timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after the power is turned on for a certain period of time.
Position detection means for detecting the position of the rotor of the DC motor, commutation means for outputting commutation pulses for determining the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means, and the position detection Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the means, and chopping signal generation means A for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable.
A synthesizing means for synthesizing the commutation pulse and the chopping signal; drive means for turning on / off a semiconductor switch of the inverter circuit by the output of the synthesizing means; and an inverter temperature sensor for detecting the temperature of the inverter circuit. And an internal fan stop means for outputting a fan stop signal to the internal fan operating means until the inverter temperature becomes higher than a predetermined temperature t1 until the inverter temperature falls to a predetermined temperature t2. Is.

Further, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and the DC motor. Driven by a compressor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that allows cold air cooled by the cooler to flow into a freezer, and the in-compartment fan And a timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after the power is turned on for a certain period of time.
Position detection means for detecting the position of the rotor of the DC motor, commutation means for outputting commutation pulses for determining the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means, and the position detection Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the means, and chopping signal generation means B for generating a chopping signal for performing the chopping that makes the rotation speed of the DC motor variable.
A synthesizing means for synthesizing the commutation pulse and the chopping signal, a driving means for turning on / off a semiconductor switch of the inverter circuit by an output of the synthesizing means, and an outside air temperature for detecting an ambient temperature of the refrigeration cycle. A sensor, and a plurality of chopping frequency storage means for storing different frequency patterns of the chopping signal,
When the detected outside air temperature is higher than a predetermined temperature, the chopping signal generating means B is selected by selecting a pattern having a lower inner frequency of the frequency patterns for a predetermined time after the fan stop signal of the timer A ends. And a chopping frequency selecting means A for outputting to.

Further, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and the DC motor. Driven by a compressor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that allows cold air cooled by the cooler to flow into a freezer, and the in-compartment fan And a timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after the power is turned on for a certain period of time.
Position detection means for detecting the position of the rotor of the DC motor, commutation means for outputting commutation pulses for determining the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means, and the position detection Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the means, and chopping signal generation means B for generating a chopping signal for performing the chopping that makes the rotation speed of the DC motor variable.
A synthesizing means for synthesizing the commutation pulse and the chopping signal; drive means for turning on / off a semiconductor switch of the inverter circuit by the output of the synthesizing means; and an inverter temperature sensor for detecting the temperature of the inverter circuit. And a plurality of chopping frequency storage means for storing different frequency patterns of the chopping signal, and a temperature t at which the inverter temperature is predetermined.
If it becomes higher than 5, the temperature t6 is predetermined.
And a chopping frequency selecting means B for selecting a pattern having a lower frequency out of the frequency patterns and outputting it to the chopping signal generating means B until the frequency falls.

[0017]

According to the present invention, when the outside air temperature of the refrigerator detected by the outside air temperature sensor is high, the operation of the internal fan is stopped for a certain time after the timer A turns on the power for a certain time. After that, the timer B stops the operation of the internal fan for a certain period of time after a certain period of time, so that the compressor current can be controlled so as to suppress the peak value of the inverter circuit temperature.
It is possible to realize the refrigerator control device in which the heat sink of the inverter circuit is made small and the cost can be reduced.

Further, according to the present invention, with the above-mentioned configuration, after the timer A is turned on for a fixed time, the operation of the internal fan is stopped for a fixed time, and then the inverter temperature sensor is set to the semiconductor switch. Detect the temperature,
When the temperature becomes higher than the predetermined temperature t1, the internal fan stop means stops the internal fan until the temperature decreases to the predetermined temperature t2, so that the heat sink can be downsized and the cost can be reduced. At the same time, since the internal fan stop time can be shortened, it is possible to realize a refrigerator controller that can cool the internal temperature more quickly.

Further, according to the present invention, with the above-mentioned structure, after the timer A is turned on, the operation of the internal fan is stopped for a predetermined time, and then the refrigerator detected by the outside air temperature sensor. When the outside air temperature is higher than a predetermined temperature, the chopping frequency selecting means A selects a pattern having a lower inner frequency of the frequency patterns for a predetermined time and outputs it to the chopping signal generating means B. Since the loss of the semiconductor switch can be suppressed, the heat sink can be downsized, the cost can be reduced, and it is not necessary to take the internal fan stop time other than preventing the temperature protection operation of the compressor. A refrigerator control device that can cool the internal temperature faster can be realized.

Further, according to the present invention, with the above-described structure, after the timer A is powered on, the operation of the internal fan is stopped for a fixed time, and then the inverter temperature sensor is set to the semiconductor switch. When the temperature is detected and becomes higher than the predetermined temperature t5, the chopping frequency selecting means B keeps the pattern having a lower inner frequency of the frequency pattern for a predetermined time until the temperature falls to the predetermined temperature t6. By selecting and outputting to the chopping signal generating means B, the loss of the semiconductor switch can be suppressed, so that the heat sink can be downsized, the cost can be reduced, and the temperature protection operation of the compressor can be prevented. Since it is not necessary to stop the internal fan of It is possible, because the time'll lowering the frequency of the chopping signal can be shortened,
A refrigerator control device that saves power can be realized.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A refrigerator controller according to a first embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is an overall configuration diagram of a refrigerator controller according to a first embodiment of the present invention. In FIG. 1, reference numeral 1 denotes an AC power supply. Reference numeral 2 denotes a voltage doubler rectifier circuit for converting an AC voltage of the AC power supply 1 into a DC voltage, and has a configuration in which diodes 2a to 2d and capacitors 2e to 2f are connected.

Reference numeral 3 denotes an inverter circuit, in which semiconductor switches (transistors) 3a to 3f are connected in a three-phase bridge, and diodes 3g to 3l are connected to the respective transistors in parallel and in opposite directions.

A heat sink 4 cools the inverter circuit. Reference numeral 5 is a DC motor, which is driven by the output of the inverter circuit 3. A compressor 6 is driven by the DC motor 5. 7 is the DC motor 5
Is a position detecting means for detecting a rotational position of a rotor (not shown) and generating a rotation pulse, and is a system for detecting a position from a back electromotive voltage of the DC motor 5.

Reference numeral 8 is a commutation means for producing a commutation pulse for commutating the semiconductor switches 3a to 3f of the inverter circuit 3 from the output of the position detection means 7. Reference numeral 9 denotes a rotation speed command means, which outputs a rotation speed command signal for the DC motor 5. Reference numeral 10 is a rotation speed detecting means, which counts the rotation pulse of the position detecting means 7 for a certain period (for example, 0.5 seconds).

Reference numeral 11 denotes a duty setting means, which determines a duty value from the difference between the rotation speed command signal of the rotation speed command means 9 and the actual rotation speed detected by the rotation speed detection means 10 so that they match each other. Is output. Reference numeral 12 is a chopping signal generating means A, which produces a waveform having a different ON / OFF ratio at a constant frequency according to the duty value in order to make the rotation speed of the DC motor 5 variable.

A synthesizing means 13 synthesizes the commutation pulse and the chopping signal.

Reference numeral 14 is a drive means, which turns on / off the semiconductor switches 3a to 3f of the inverter circuit 3 by the output of the synthesizing means 13.

Reference numeral 15 is a condenser, and 16 is a cooler. 17
Is a refrigeration cycle, the compressor 6 and the condenser 1
5. It is composed of the cooler 16.

Reference numeral 18 denotes an internal fan, which is the cooler 16
The cold air cooled by is poured into the freezer. Reference numeral 19 denotes an internal fan operating means for operating the internal fan 18.

Reference numeral 20 denotes a timer A, which outputs a fan stop signal to the internal fan operating means 19 for a fixed time T2 after the power-on fixed time T1.

Reference numeral 21 is an outside air temperature sensor for detecting the ambient temperature of the refrigeration cycle 17. Reference numeral 22 denotes a timer B, and when the detected outside air temperature is higher than a predetermined temperature t3, after the fan stop signal of the timer A20 ends for a fixed time T3, the internal fan operating means 1
A stop signal is output to 9 for a fixed time T4.

Reference numeral 23 denotes an in-compartment fan operating section A which is composed of the in-compartment fan operating means 19, the timer A20 and the timer B22.

Next, the operation of the internal fan operating section A23 will be described with reference to the flowchart of FIG.

First, if the power source is turned on in STEP 101, the internal fan operating means 19 operates the internal fan 18 in STEP 102.

Next, in STEP 103, the timer A20
Judges whether or not a predetermined time T1 has passed since the power was turned on, and if T1 has passed, the internal fan operating means 19 stops the internal fan 18 in STEP 104. Subsequently, in STEP 105, it is determined whether or not a predetermined time T2 has elapsed since the timer A 20 stopped the internal fan 18, and if T2 has elapsed, STEP
At 106, the internal fan operation means 19 restarts the operation of the internal fan 18.

Next, at STEP 107, the timer B2
2 determines whether the detected outside air temperature is higher than a predetermined temperature t3, and if higher than t3, ST
In EP108, the timer B22 determines whether or not a predetermined time T3 has elapsed after the operation of the internal fan is restarted.
When the time has elapsed, in STEP 109, the internal fan operating means 19 stops the internal fan 18. Then, S
In the TEP110, the timer B22 sets the internal fan 18
It is determined whether or not a predetermined time T4 has elapsed after stopping the operation. If T4 has elapsed, the internal fan operating means 19 restarts the operation of the internal fan 18 in STEP111, and a series of operations ends. To do.

If the detected outside air temperature is lower than t2 in STEP 107, the series of operations is terminated.

FIG. 3A shows a characteristic diagram of changes in the compressor current when performing a series of operations as described above, and FIG. 3B shows a characteristic diagram of changes in the inverter circuit temperature. FIG. 3 (a)
By controlling the compressor current as shown in FIG. 3, it can be seen that the peak value of the inverter circuit temperature is suppressed as compared with the conventional case, as shown in FIG.

Therefore, the heat sink 4 of the inverter circuit 3 can be made small, and the cost can be reduced.

Next, a second embodiment of the present invention will be described with reference to the drawings. FIG. 4 is an overall configuration diagram of the refrigerator control device according to the second embodiment of the present invention. In FIG. 4, components having the same configuration as the overall configuration diagram of the refrigerator control device of the first embodiment shown in FIG. 1 are designated by the same reference numerals, and description thereof will be omitted.

Reference numeral 24 is an inverter temperature sensor, which detects the temperature of the inverter circuit 3. Reference numeral 25 denotes an internal fan stop means, which operates the internal fan operation means 19 until the inverter temperature becomes higher than a predetermined temperature t1 until the inverter temperature drops to a predetermined temperature t2.
The fan stop signal is output to.

Reference numeral 26 denotes an internal fan operating section B, which is composed of the internal fan operating means 19, the timer A20 and the internal fan stopping means 25.

Next, the operation of the internal fan operating section B26 will be described with reference to the flowchart of FIG.

First, if the power source is turned on in STEP 201, the internal fan operating means 19 operates the internal fan 18 in STEP 202.

Next, in step 203, the timer A20
Judges whether or not a predetermined time T1 has passed since the power was turned on, and if T1 has passed, the internal fan operating means 19 stops the internal fan 18 in STEP204. Subsequently, in STEP205, it is determined whether or not a predetermined time T2 has elapsed since the timer A20 stopped the internal fan 18, and if T2 has elapsed, STEP is performed.
At 206, the internal fan operating means 19 restarts the operation of the internal fan 18.

Next, in STEP 207, the internal fan stop means 25 determines whether the detected inverter circuit temperature is higher than a predetermined temperature t1, and t1
If it is higher, in STEP 208, the internal fan operating means 19 stops the internal fan 18. continue,
In STEP 209, the internal fan stop means 25 determines whether the detected inverter circuit temperature is lower than a predetermined temperature t2, and if lower than t2, ST
In EP210, the internal fan operating means 19 restarts the operation of the internal fan 18, and ends a series of operations.

If the detected inverter circuit temperature is lower than t1 in STEP 207, the series of operations is terminated.

As a result, the heat sink 4 can be downsized, the cost can be reduced, and the in-compartment fan stop time can be shortened, so that the in-compartment temperature can be cooled more quickly.

Next, a third embodiment of the present invention will be described with reference to the drawings. FIG. 6 is an overall configuration diagram of a refrigerator control device according to a third embodiment of the present invention. 6, components having the same configuration as the overall configuration diagram of the refrigerator control device according to the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.

27 and 28 are chopping frequency storage means A and chopping frequency storage means B, which are frequency pattern A (frequency: f1) and frequency pattern B, respectively.
(Frequency: f2) is stored. Where f1> f2
And

Numeral 29 is a chopping frequency selecting means A, which when the detected outside air temperature is higher than a predetermined temperature t4, keeps the frequency for a predetermined time T5 after the end of the fan stop signal of the timer A20. The frequency pattern B having a lower frequency is selected and output to the chopping signal generating means B30 described later, and in other cases, the frequency pattern A having a higher frequency is selected and output to the chopping signal generating means B30 described later.

Reference numeral 30 denotes a chopping signal generating means B, which produces a waveform having a different on / off ratio in the frequency pattern according to the duty value in order to make the rotation speed of the DC motor 5 variable.

Reference numeral 31 is a chopping frequency selection unit A, which is composed of the chopping frequency storage means A27, the chopping frequency storage means B28, and the chopping frequency selection means A29.

Next, the chopping frequency selection unit A3
The operation of No. 1 will be described with reference to the flowchart of FIG.

First, when the power is turned on in STEP 301, the chopping frequency selecting means A29 selects the frequency pattern A and outputs it to the chopping signal generating means B30.

Next, at STEP 303, the chopping frequency selection means A29 determines whether the fan stop signal of the timer A20 has ended, that is, whether the time elapsed after the power is turned ON has reached (T1 + T2), and the time has elapsed. If so, in STEP 304, it is determined whether the outside air temperature is higher than t4.

If higher than t4, proceed to STEP 305,
The frequency pattern B is selected and output to the chopping signal generator B30.

Next, in STEP 306, it is determined whether or not a predetermined fixed time T5 has passed since the chopping frequency selection means A29 selected the frequency pattern B. If so, the process proceeds to STEP 307. The frequency pattern A is selected and output, and the series of operations is completed.

If the outside air temperature is lower than t4 in STEP 304, the series of operations is terminated.

FIG. 8 shows a characteristic diagram of changes in the inverter circuit temperature when a series of operations are performed as described above. As shown in FIG. 8, the temperature of the inverter circuit of the present embodiment can be lowered because the semiconductor switch is operated at a low chopping frequency of a constant time, so that the loss of the semiconductor switch is suppressed. .

For this reason, the heat sink 4 can be downsized, the cost can be reduced, and it is not necessary to take the in-compartment fan stop time other than preventing the temperature protection operation of the compressor 6, so that the in-compartment temperature can be further improved. However, since the efficiency of the DC motor 5 is lowered at a low chopping frequency, operating the semiconductor switch at a low chopping frequency for a long time increases the power of the refrigerator.

Next, a fourth embodiment of the present invention will be described with reference to the drawings. FIG. 9 is an overall configuration diagram of the refrigerator control device according to the fourth embodiment of the present invention. 9, components having the same configurations as those of the entire configuration diagrams of the refrigerator control devices according to the first, second, and third embodiments illustrated in FIGS. 1, 4, and 6 are denoted by the same reference numerals, and description thereof will be omitted. .

Reference numeral 32 is a chopping frequency selecting means B, which has a predetermined temperature t of the inverter temperature.
If it becomes higher than 1, the predetermined temperature t2
The frequency pattern B having a low frequency is selected and outputted to the chopping signal generating means B30 until the frequency drops to 0. In other cases, the frequency pattern A having a high frequency is selected and outputted to the chopping signal generating means B30.

A chopping frequency selecting section B is composed of the chopping frequency storing means A27, the chopping frequency storing means B28, and the chopping frequency selecting means B33.

Next, the chopping frequency selection unit B3
The operation of No. 3 will be described with reference to the flowchart of FIG.

First, if the power is turned on in STEP 401, the chopping frequency selecting means B32 selects the frequency pattern A and outputs it to the chopping signal generating means B30.

Next, in STEP 403, the chopping frequency selection means B32 determines whether the fan stop signal of the timer A20 has ended, that is, whether the time elapsed after the power is turned ON has reached (T1 + T2), and the time has elapsed. If so, in STEP 404, it is determined whether the inverter circuit temperature is higher than t5.

If higher than t5, proceed to STEP405,
The frequency pattern B is selected and output to the chopping signal generator B30.

Next, in STEP 406, it is judged whether or not the inverter circuit temperature is lower than t4.
The process proceeds to TEP407, the frequency pattern A is selected and output, and a series of operations is ended.

In STEP 404, if the inverter circuit temperature is lower than t5, the series of operations is finished.

With the above, the semiconductor switch 3 is
Since the loss of the heat sink 4 can be suppressed,
And the cost can be reduced, and since it is not necessary to take a time to stop the internal fan other than to prevent the temperature protection operation of the compressor 6, the internal temperature can be cooled more quickly and the chopping signal Since the time for lowering the frequency can be shortened, it is possible to realize a refrigerator control device that saves power.

[0073]

As described above, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, and a DC motor operated by the inverter circuit. A compressor driven by the DC electric motor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, a fan inside the refrigerator for flowing cold air cooled by the cooler into the freezer, and the refrigerator Internal fan operating means for operating the internal fan, timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after power is turned on, and position detecting means for detecting the position of the rotor of the DC motor. And a commutation hand that outputs a commutation pulse that determines the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means. And a rotation speed detection means for detecting the rotation speed of the compressor based on the output of the position detection means, and a chopping signal generation means for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable. A, combining means for combining the commutation pulse and the chopping signal, drive means for turning on / off the semiconductor switch of the inverter circuit by the output of the combining means, and outside air for detecting the ambient temperature of the refrigeration cycle. A temperature sensor and a timer B that outputs a stop signal to the in-compartment operating means for a certain period of time after the fan stop signal of the timer A ends for a certain period of time when the detected outside air temperature is higher than a predetermined temperature are provided. As a result, when the outside air temperature of the refrigerator detected by the outside air temperature sensor is high, the timer A turns on the power. After a certain period of time,
After stopping the operation of the internal fan for a certain period of time,
When the timer B stops the operation of the internal fan for a certain time after a certain time, the compressor current can be controlled so as to suppress the peak value of the inverter circuit temperature, and the heat sink of the inverter circuit can be controlled. It is possible to realize a refrigerator control device that can reduce the size and cost.

Further, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and the DC motor. Driven by a compressor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that allows cold air cooled by the cooler to flow into a freezer, and the in-compartment fan And a timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after the power is turned on for a certain period of time.
Position detection means for detecting the position of the rotor of the DC motor, commutation means for outputting commutation pulses for determining the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means, and the position detection Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the means, and chopping signal generation means A for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable.
A synthesizing means for synthesizing the commutation pulse and the chopping signal; drive means for turning on / off a semiconductor switch of the inverter circuit by the output of the synthesizing means; and an inverter temperature sensor for detecting the temperature of the inverter circuit. And by providing internal fan stop means for outputting a fan stop signal to the internal fan operating means until the inverter temperature becomes higher than the predetermined temperature t1 until it falls to the predetermined temperature t2. , A certain time after the timer A is turned on,
After stopping the operation of the internal fan for a certain period of time,
When the inverter temperature sensor detects the temperature of the semiconductor switch and becomes higher than a predetermined temperature t1, the internal fan stop means stops the internal fan until the temperature falls to a predetermined temperature t2. By doing so, the heat sink can be made smaller, the cost can be reduced, and the in-compartment fan stop time can be shortened, so that a refrigerator control device capable of cooling the in-compartment temperature faster can be realized.

Further, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and the DC motor. Driven by a compressor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that allows cold air cooled by the cooler to flow into a freezer, and the in-compartment fan And a timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after the power is turned on for a certain period of time.
Position detection means for detecting the position of the rotor of the DC motor, commutation means for outputting commutation pulses for determining the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means, and the position detection Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the means, and chopping signal generation means B for generating a chopping signal for performing the chopping that makes the rotation speed of the DC motor variable.
A synthesizing means for synthesizing the commutation pulse and the chopping signal, a driving means for turning on / off a semiconductor switch of the inverter circuit by an output of the synthesizing means, and an outside air temperature for detecting an ambient temperature of the refrigeration cycle. A sensor, and a plurality of chopping frequency storage means for storing different frequency patterns of the chopping signal,
When the detected outside air temperature is higher than a predetermined temperature, the chopping signal generating means B is selected by selecting a pattern having a lower inner frequency of the frequency patterns for a predetermined time after the fan stop signal of the timer A ends. By providing the chopping frequency selecting means A for outputting to the refrigerator, the refrigerator detected by the outside air temperature sensor after stopping the operation of the internal fan for a fixed time after the timer A is turned on. When the outside air temperature is higher than a predetermined temperature, the chopping frequency selecting means A selects a pattern having a lower inner frequency of the frequency patterns for a predetermined time and outputs it to the chopping signal generating means B. Since the loss of the semiconductor switch can be suppressed, For reducing the heat sink, the cost reduction can be achieved, there is no need to take the in-compartment fan stop time other than to prevent the temperature protection operation of the compressor,
It is possible to realize a refrigerator control device that can cool the inside temperature more quickly.

Further, the refrigerator control device of the present invention includes an inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and the DC motor. Driven by a compressor, a condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that allows cold air cooled by the cooler to flow into a freezer, and the in-compartment fan And a timer A for outputting a fan stop signal to the internal fan operating means for a certain period of time after the power is turned on for a certain period of time.
Position detection means for detecting the position of the rotor of the DC motor, commutation means for outputting commutation pulses for determining the operation of the semiconductor switch of the inverter circuit based on the output of the position detection means, and the position detection Rotation speed detection means for detecting the rotation speed of the compressor based on the output of the means, and chopping signal generation means B for generating a chopping signal for performing the chopping that makes the rotation speed of the DC motor variable.
A synthesizing means for synthesizing the commutation pulse and the chopping signal; drive means for turning on / off a semiconductor switch of the inverter circuit by the output of the synthesizing means; and an inverter temperature sensor for detecting the temperature of the inverter circuit. And a plurality of chopping frequency storage means for storing different frequency patterns of the chopping signal, and a temperature t at which the inverter temperature is predetermined.
If it becomes higher than 5, the temperature t6 is predetermined.
By providing a chopping frequency selection means B for selecting a pattern having a lower frequency of the frequency patterns until it goes down to a predetermined level and outputting it to the chopping signal generation means B. After the operation of the inner fan is stopped for a certain period of time, the inverter temperature sensor detects the temperature of the semiconductor switch, and when the temperature becomes higher than a predetermined temperature t5, it goes down to a predetermined temperature t6. Since the chopping frequency selecting means B selects a pattern having a lower internal frequency of the frequency patterns for a predetermined time and outputs it to the chopping signal generating means B, the loss of the semiconductor switch can be suppressed. The heat sink can be made smaller and the cost can be reduced. , Since there is no need to take the internal fan stop time other than to prevent the temperature protection operation of the compressor,
Since the temperature inside the refrigerator can be cooled more quickly and the time for lowering the frequency of the chopping signal can be shortened, it is possible to realize a refrigerator control device that saves power.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of a refrigerator control device according to a first embodiment of the present invention.

FIG. 2 is a flowchart of an internal fan operation unit A according to this embodiment.

FIG. 3A is a characteristic diagram of changes in compressor current according to the present embodiment. FIG. 3B is a characteristic diagram of changes in temperature of the inverter circuit according to the present embodiment.

FIG. 4 is an overall configuration diagram of a refrigerator control device according to a second embodiment of the present invention.

FIG. 5 is a flowchart of an internal fan operation unit B of this embodiment.

FIG. 6 is an overall configuration diagram of a refrigerator control device according to a third embodiment of the present invention.

FIG. 7 is a flowchart of a chopping frequency selection unit A of this embodiment.

FIG. 8 is a characteristic diagram of changes in inverter circuit temperature according to the present embodiment.

FIG. 9 is an overall configuration diagram of a refrigerator control device according to a fourth embodiment of the present invention.

FIG. 10 is a flowchart of the chopping frequency selection unit B of this embodiment.

[Explanation of symbols]

 3 Inverter Circuit 4 Heat Sink 5 DC Motor 6 Compressor 7 Position Detection Means 8 Commutation Means 9 Rotation Speed Detection Means 10 Chopping Signal Generation Means A 13 Synthesis Means 14 Drive Means 15 Condenser 16 Cooler 18 Internal Fan 19 Internal Fan Operating means 20 Timer A 21 Outside air temperature sensor 22 Timer B 24 Inverter temperature sensor 25 In-compartment fan stopping means 27 Chopping frequency storage means A 28 Chopping frequency storage means B 29 Chopping frequency selection means A 30 Chopping signal generation means B 32 Chopping frequency selection Means B

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Shuji Ogawara 4-5 Takaida Hondori, Higashi-Osaka City, Osaka Prefecture Matsushita Refrigerator Co., Ltd. (72) Inventor Yasuhiro Tsujii 4-chome, Takaida Hondori, Higashi Osaka 2-5 Matsushita Refrigerator Co., Ltd. (72) Inventor Kazunori Kurimoto 4-2-5 Takaidahondori, Higashi-Osaka City, Osaka Prefecture Matsushita Refrigerator Co., Ltd.

Claims (4)

[Claims] 1. An inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and a compressor driven by the DC motor. A condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that flows cold air cooled by the cooler into a freezer, and an in-compartment fan operating means that operates the in-compartment fan, A timer A that outputs a fan stop signal to the internal fan operating means for a certain time after the power is turned on, a position detecting means that detects the position of the rotor of the DC motor, and the output based on the output of the position detecting means. A commutation unit that outputs a commutation pulse that determines the operation of the semiconductor switch of the inverter circuit; Rotation speed detection means for detecting the rotation speed of the compressor, chopping signal generation means A for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable, and the commutation pulse and the chopping signal. Synthesizing means, drive means for turning on / off the semiconductor switch of the inverter circuit by the output of the synthesizing means, an outside air temperature sensor for detecting the ambient temperature of the refrigeration cycle, and the detected outside air temperature A refrigerator control device comprising a timer B which outputs a stop signal to the in-compartment operating means after a predetermined time when the fan stop signal of the timer A ends when the temperature is higher than a predetermined temperature. 2. An inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and a compressor driven by the DC motor. A condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that flows cold air cooled by the cooler into a freezer, and an in-compartment fan operating means that operates the in-compartment fan, A timer A that outputs a fan stop signal to the internal fan operating means for a certain time after the power is turned on, a position detecting means that detects the position of the rotor of the DC motor, and the output based on the output of the position detecting means. A commutation unit that outputs a commutation pulse that determines the operation of the semiconductor switch of the inverter circuit; Rotation speed detection means for detecting the rotation speed of the compressor, chopping signal generation means A for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable, and the commutation pulse and the chopping signal. Synthesizing means, a driving means for turning on / off a semiconductor switch of the inverter circuit by an output of the synthesizing means, an inverter temperature sensor for detecting a temperature of the inverter circuit, and a temperature at which the inverter temperature is predetermined. If it becomes higher than t1,
A refrigerator control device comprising an internal fan stop means for outputting a fan stop signal to the internal fan operation means until the temperature falls to a predetermined temperature t2. 3. An inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and a compressor driven by the DC motor. A condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that flows cold air cooled by the cooler into a freezer, and an in-compartment fan operating means that operates the in-compartment fan, A timer A that outputs a fan stop signal to the internal fan operating means for a certain time after the power is turned on, a position detecting means that detects the position of the rotor of the DC motor, and the output based on the output of the position detecting means. A commutation unit that outputs a commutation pulse that determines the operation of the semiconductor switch of the inverter circuit; Rotation speed detection means for detecting the rotation speed of the compressor, chopping signal generation means B for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable, and the commutation pulse and the chopping signal. Synthesizing means, driving means for turning on / off the semiconductor switch of the inverter circuit by the output of the synthesizing means, an outside air temperature sensor for detecting the ambient temperature of the refrigeration cycle, and different frequency patterns of the chopping signal. And a plurality of chopping frequency storing means for storing the internal frequency of the frequency pattern, when the detected outside air temperature is higher than a predetermined temperature, a predetermined fixed time after the fan stop signal of the timer A ends. Pattern having a low level is selected and output to the chopping signal generating means B. Refrigerator control device comprising a chopping frequency selection means A. 4. An inverter circuit in which a plurality of semiconductor switches and diodes are bridge-connected, a heat sink for cooling the inverter circuit, a DC motor operated by the inverter circuit, and a compressor driven by the DC motor. A condenser that constitutes a refrigeration cycle including the compressor, a cooler, an in-compartment fan that pours cold air cooled by the cooler into a freezer, and an in-compartment fan operating means that operates the in-compartment fan, A timer A for outputting a fan stop signal to the internal fan operating means for a fixed time after power-on, a position detecting means for detecting the position of the rotor of the DC electric motor, and the output based on the output of the position detecting means. A commutation unit that outputs a commutation pulse that determines the operation of the semiconductor switch of the inverter circuit, and the pressure based on the output of the position detection unit. Rotation speed detection means for detecting the rotation speed of the compressor, chopping signal generation means B for generating a chopping signal for performing chopping that makes the rotation speed of the DC motor variable, and the commutation pulse and the chopping signal. Synthesizing means, a driving means for turning on / off a semiconductor switch of the inverter circuit by the output of the synthesizing means, an inverter temperature sensor for detecting the temperature of the inverter circuit, and a different frequency pattern of the chopping signal. A plurality of stored chopping frequency storage means, and when the inverter temperature becomes higher than a predetermined temperature t5, a pattern having a lower inner frequency of the frequency patterns is selected until the temperature drops to a predetermined temperature t6. Chopping to be output to the chopping signal generating means B Wavenumber selection means B
Refrigerator control device consisting of.