KR100513903B1 - Air conditioner - Google Patents

Abstract

It makes it less susceptible to noise, makes it possible to reliably detect the rotor, and makes it possible to rotate the rotor stably.

By providing the voltage feedback capacitors 21 and 22, the hysteresis voltage change is suddenly made to be a desired change amount.

Description

Air Conditioner {AIR CONDITIONER}

The present invention relates to a driving method of a coil of a four-way valve (electromagnetic valve) for switching between cooling and heating.

In recent years, remarkable advances have been made in increasing the efficiency, miniaturization, and low cost of air conditioners. In order to downsize, the invention described in Japanese Patent Laid-Open No. 6-147607 is proposed.

Hereinafter, the conventional air conditioner is demonstrated using FIG.

As shown in FIG. 5, a commercial power supply 1, a rectifier circuit 2, a smoothing capacitor 3, an inverter 4, an inverter control circuit 5, a compressor 6, and a relay ( 7) and the four-way valve coil 8.

The operation will be described below.

The drive of the compressor 6 is controlled by the inverter 4 using a power source rectified by a commercial power source 1 as a rectifier circuit 2 and a smoothing capacitor 3, and a relay ( 7), the four-way valve 8 was controlled.

However, in the above conventional configuration, since the four-way valve 8 is driven by a single DC power source, the driving power of the four-way valve coil (relay 7) increases, which has a problem that the loss is large.

SUMMARY OF THE INVENTION The present invention solves such a conventional problem, by applying a method of switching the power supply voltage proposed in Japanese Patent Laid-Open No. 2001-91013 as a direct current drive of a switchgear to a large-power solenoid valve to reduce losses and at the same time, a direct current power source. To simplify.

In order to solve the above problems, the present invention can reduce the loss by switching the driving power of the four-way valve, and can be miniaturized by supplying the power of the four-way valve and the inverter from the same power source.

According to the present invention described in claim 1, the driving power of the four-way valve can be switched by driving the drive of the four-way valve coil with the first direct current power source and the second direct current power source. By supplying control power, the second DC power supply can be shared.

In addition, the high-voltage side driving power supply of the three-phase inverter is configured as a bootstrap power supply, and the drive sequence in which the initial charging period of the bootstrap power supply and the interruption of the first switch do not occur at the same time is used to maximize the second DC power supply. Since the output can be suppressed, the power supply can be miniaturized.

The present invention described in claim 2 constitutes a first switch composed of a transistor and a relay in series, and the relay bounces by turning the relay on and then turning the transistor on and then turning off the transistor after a predetermined time so as to turn off the relay. The conduction and interruption of the first DC power supply can be prevented from repeating by bouncing or chattering, and the leakage current of the transistor can be interrupted by interrupting the relay.

According to the present invention described in claim 3, by using the first switch as a relay having a magnet near the contact point, it is possible to prevent an arc from flowing to the relay for a long time and to reliably block a large power direct current. .

According to the present invention described in claim 4, by driving the four-way valve during the heating operation, the period of driving the four-way valve as the second direct current power source can be set as the heating time with low ambient temperature. The power supply can be further miniaturized.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings.

(Embodiment 1)

As shown in FIG. 1, the commercial power supply 11, the rectifier circuit 12, and the first direct current power supply 14 rectified by the smoothing capacitor 13, the three-phase inverter 15, and the three-phase inverter control circuit. 16, a compressor 17, a first switch (relay in this embodiment) 19 for supplying the first direct current power source 14 to the four-way valve coil 18, and the second direct current power source 20 (In this embodiment, the power supply voltage is about 18 V), the second switch 21 (relay in this embodiment) for supplying the second DC power supply 20 to the four-way valve coil 18, and a reverse current prevention diode. And a diode 23 for reflux current. Moreover, the drive power supply of the high voltage side in the three-phase inverter 15 is comprised by the bootstrap power supply 15a which consists of the resistor 24, the diode 25, and the electrolytic capacitor 26 (three phase inverter 15 has three). As many bootstrap powers as there are phases, but the description is for one phase and the others are omitted). 27 is a four-way valve, and 27a is a plunger which is an electromagnetic valve in the four-way valve 27.

The operation will be described below.

The commercial power supply 11 was rectified by direct current with the rectifier circuit 12 and the smoothing capacitor 13, and the 1st DC power supply 14 was comprised. As for the driving of the compressor, the first DC power source 14 is converted into a three-phase by the three-phase inverter 15 to drive the compressor 17.

The three-phase inverter 15 is controlled by the three-phase inverter control circuit 16 and has a non-isolated configuration in which the reference potentials of the three-phase inverter 15 and the three-phase inverter control circuit 16 are equal.

Next, the drive of the 4-way valve 27 is demonstrated using FIG.

The first switch 19 is driven for a predetermined time to apply the high voltage first DC power supply 14 to the four-way valve coil 18 to move the plunger 27a which is the solenoid valve in the four-way valve 27. Subsequently, the first switch 19 is shut off and the second DC power supply 20 is supplied to the four-way valve coil 18 as the second switch 21 to maintain the plunger 27a position.

The second switch 21 may be conducted at the timing at which the first switch 19 is cut off, but in this embodiment, the first switch 19 is cut off and the second switch 21 is turned on in consideration of the operation time of the relay. Since a non-energization time is generated between the and the plunger 27a to prevent the position of the plunger 27a from being returned to its original state, the second switch 21 is conducted simultaneously with the first switch 19 at the same time.

In addition, the reference potentials of the three-phase inverter 15 and the three-phase inverter control circuit 16 are the same, so that the power supply and the three-phase power supply of the three-phase inverter control circuit 16 are separated from the second DC power supply 20 having the same reference potential. The bootstrap power supply 15a of the inverter 15 is supplied. Before the operation of the three-phase inverter 15 starts, the voltage at both ends of the electrolytic capacitor 26 of the bootstrap power supply 15a is 0V. First, the bootstrap power supply 15a is charged by conducting a switching element (not shown) on the low voltage side of the three-phase inverter 15 as initial charging.

At this time, as shown in FIG. 2, the initial charging current flows through the electrolytic capacitor 26 as a time constant determined by the resistor 24 and the electrolytic capacitor 26. In this embodiment, a large current of about 0.6 A peak current flows.

In addition, even when the first switch 19 is shut off, the current flowing in the four-way valve coil 18 flows to the second switch 21 by the inductance of the four-way valve coil 18, resulting in a peak. A large current of about 0.6 A current flows.

As the drive sequence, the bootstrap power supply 15a is energized to the four-way valve coil 18 after the initial charging is completed.

As described above, in the present embodiment, the driving power of the four-way valve coil 18 is greatly reduced by switching the voltage applied to the four-way valve coil 18 from the first direct current power source 14 to the second direct current power source ( If the commercial power supply is 200V, the applied voltage is reduced from about 280V to about 18V and power consumption is reduced to less than one hundredth).

In addition, since the power supply of the three-phase inverter control circuit 16 is supplied from the second DC power supply 20, one low-voltage power supply can be configured.

Further, the initial charging period of the bootstrap power source 15a and the first switch 19 are cut off by setting the sequence of driving the four-way valve coil 18 after the initial charging period of the bootstrap power source 15a is completed. The timing can be shifted, and the second DC power supply 20 can be configured with a small power supply having an instantaneous output capacity of up to 0.6 A without overlapping a large peak current of about 0.6 A on both sides.

Moreover, in the present embodiment, the first direct current power source 14 is a power source by full-wave rectification of the commercial power source 11, but the operation also occurs in the double voltage of the commercial power source 11, the output of the converter including the active filter, and the like. Of course the same is true.

In addition, when using the 2nd DC power supply 20 to drive loads other than this embodiment (for example, expansion valve coil etc.), the same effect can be acquired by making into a sequence which shifts a drive timing similarly. Of course.

(Embodiment 2)

3 and 4, components having the same reference numerals as those in the first embodiment are the same in operation and will not be described.

In FIG. 3, the part different from Embodiment 1 consists of the 1st switch 19 comprised in series of the transistor 19a and the relay 19b. In addition, the bootstrap power supply 15a is omitted because it is irrelevant to the present invention.

The driving sequence will be described in FIG. First, the relay 19b and the relay 21 are turned on. At this time, since the transistor 19a is shut off, the second DC power supply 20 is applied to the four-way valve coil 18. However, since the voltage is about 18V, the plunger in the four-way valve does not move.

Then, the transistor 19a is turned on, and the first direct current power source 14 is applied to the four-way valve coil 18 to move the plunger in the four-way valve. After a predetermined time, the transistor 19a is cut off and the application of the first DC power supply 14 to the four-way valve coil 18 is stopped, and the four-way valve coil 18 is provided through the second switch 21. 2 DC power supply 20 is applied. After that, the relay 19b is shut off.

Since the transistor 19a is turned on after the relay 19b is turned on and the transistor 19a is turned off after the relay 19b is turned off, the chattering and bounce of the relay 19b do not occur. The first DC current 14 can be turned on and off at a non-timing timing, and the large current flowing from the second DC power supply 20 can be made only once when the transistor 19a is shut off.

Therefore, the maximum current capacity of the second DC power supply 20 can be reduced by simply adding an electrolytic capacitor having a predetermined capacity or more to the second DC power supply 20. Specifically, by configuring the second DC power supply 20 as a switching power supply and adding a capacitor of 470 kW to the output, the maximum current capacity of the power supply can be suppressed to 200 mA.

In addition, since the leakage current of the transistor 19a can be cut off by shutting off the relay 19b, the energization to the four-way valve coil 18 can be made 0V, and a four-way valve can be reliably cut off.

Although the drawings are omitted, by using a relay in which magnets are arranged in the vicinity of the contact point of the first switch 19 and the relay 19b in the first and second embodiments, the arc discharge does not continue for a predetermined time and the durability of the relay is improved. It is greatly improved.

In addition, by conducting the energization of the four-way valve coil 18 during heating operation with low ambient temperature, the temperature rise allowance of the second DC power supply 20 can be alleviated, and each component of the second DC power supply 20 can be relaxed. Can be miniaturized.

As is evident from the above embodiment, according to the present invention, by providing a voltage feedback capacitor, it is possible to abruptly change the voltage of hysteresis.

Further, by providing the second voltage feedback resistor, the amount of change in hysteresis can be set as the desired amount of change, and an arbitrary hysteresis waveform can be made in accordance with the connection position of the voltage feedback capacitor.

By constructing the above hysteresis, the noise can be made stronger.

In addition, by connecting a capacitor having a time constant of 5 ms or less to the neutral point detecting circuit, it is possible to perform a position detection that is strong against noise and stable.

In addition, by configuring the voltage conversion circuit, even when the comparison circuit and the microcomputer have the same reference potential, they can operate with different power supply voltages, and position detection with high detection accuracy can be performed at low cost.

The 3-phase DC brushless motor can be stably rotated by the position detection which is strong against the above noise and has high detection accuracy.

1 is a circuit diagram of an air conditioner showing an embodiment of the present invention.

2 is an operational waveform diagram of the circuit of FIG.

3 is a circuit diagram of an air conditioner showing an embodiment of the present invention.

4 is an operational waveform diagram of the circuit of FIG.

5 is a circuit diagram of an air conditioner showing a conventional example.

* Explanation of symbols for main parts of the drawings

8: 4-way valve coil 14: 1st DC power

19: first switch 20: second DC power

21: second switch 17: compressor

15: three-phase inverter 15a: bootstrap power

Claims (4)

A four-way valve coil, a first switch and a first switch for applying the first direct current to the four-way valve coil, a second direct current and the second direct current are applied to the four-way valve coil. A second switch, a compressor, and a three-phase inverter for driving the compressor, wherein the first switch is turned on for a predetermined time of several seconds, and then the second switch is continuously turned on. An air conditioner which drives a directional valve and configures the high-voltage side driving power of the three-phase inverter as a bootstrap power supply, so that a drive sequence does not occur simultaneously between the initial charger of the bootstrap power supply and the first switch. . A first switch comprising a series of four-way valve coils, a first direct current power source, a transistor for applying a first direct current power source to the four-way valve coil, and a relay; a second direct current power source; and a second direct current power source; And a second switch applied to the directional valve coil, wherein the first switch turns on the transistor after conducting the relay, and turns off the relay after a predetermined time. group. The air conditioner according to claim 1 or 2, wherein the first switch is a relay provided with a magnet near the contact point. The air conditioner according to claim 1 or 2, wherein the four-way valve is driven during the heating operation.