KR100769769B1 - Inverter air-conditioner - Google Patents

Abstract

The inverter air conditioner of the present invention is provided between a capacitor circuit (4, 5) connected between two output terminals of the rectifier circuit (2), between one input terminal of the rectifier circuit (2) and one connection point in the capacitor circuit (4, 5). And a second switch device 8 connected between the connected first switch device 7 and the other input terminal of the rectifier circuit 2 and the connection points in the capacitor circuits 4 and 5; By switching the switch devices 7 and 8 appropriately, both high power factor and harmonic suppression are made compatible, and the maximum capability and efficiency of an air conditioner are improved.

Description

Inverter air conditioner {INVERTER AIR-CONDITIONER}

1A, 1B, 1C are schematic diagrams of an inverter air conditioner according to Embodiment 1 of the present invention;

2A, 2B and 2C are diagrams for explaining the operation of the converter according to Embodiment 1 of the present invention;

3A, 3B and 3C show the power supply voltage, the input current, the output voltage, the midpoint potential of the capacitor and the ON / OFF of the first and second switch devices 7 and 8 according to Embodiment 1 of the present invention. Drawing indicating OFF,

4A, 4B, and 4C are diagrams showing a power supply voltage, an input current, and ON / OFF of the first and second switch devices 7 and 8 according to Embodiment 1 of the present invention;

5A, 5B, and 5C show the power supply voltage, the input current, the output voltage, and the ON / OFF of the first and second switch devices 7 and 8 at the time of switching the operation mode according to Embodiment 1 of the present invention. Drawing,

6 is a configuration diagram of an inverter air conditioner according to Embodiment 2 of the present invention;

7 is a configuration diagram of an inverter air conditioner according to Embodiments 3 and 4 of the present invention;

8 is a configuration diagram of an inverter air conditioner according to Embodiment 5 of the present invention;

9 is a configuration diagram of an inverter air conditioner according to Embodiment 6 of the present invention;

10 is a diagram for explaining compressor rotation speed control according to Embodiment 6 of the present invention;

11 is a view for explaining compressor rotation speed control according to Embodiment 7 of the present invention;

12 is a configuration diagram of an inverter air conditioner for explaining a relationship between an input current and Δt according to Embodiment 9 of the present invention;

13 is a view for explaining the relationship between the rotation speed and Δt according to the tenth embodiment of the present invention;

14 is a configuration diagram of an inverter air conditioner according to Embodiment 11 of the present invention;

15A and 15B are circuit diagrams illustrating an example of a converter in a conventional inverter air conditioner.

It is a figure explaining the compressor rotation speed control in the conventional inverter air conditioner.

The present invention relates to an inverter air conditioner having a converter using a rectifier circuit.

Background Art Conventionally, inverter air conditioners equipped with rectifier circuits using diodes as converters have been known.

15A, 15B, and 15C show an example of a circuit configuration of an inverter air conditioner equipped with a double voltage rectifier circuit using a bridge rectifier circuit, and a current movement. The circuit of the inverter air conditioner is composed of an AC power supply 1, a compressor 11, and an inverter unit 10. This double voltage rectifier circuit is provided with the rectifier circuit 2 which converts an AC power supply voltage into a DC voltage.

FIG. 15A further shows the flow of current between the positive half cycles from the AC power source 1. As indicated by the arrow, the current flows in the order of the AC power supply 1, the rectifier circuit 2, the capacitor 4 and the AC power supply 1, the AC power supply 1, the rectifier circuit 2 and the smoothing capacitor. It is divided into the loop which flows in order of (6), the capacitor | condenser 5, and the alternating current power supply 1, and the positive voltage Vo can be taken out from the both ends of the smoothing capacitor 6. As shown in FIG.

FIG. 15B shows the flow of current between the negative half cycles from the AC power source 1. As indicated by the arrow, the current flows in the order of the AC power supply 1, the capacitor 5, the rectifier circuit 2, and the AC power supply 1, the AC power supply 1, the capacitor 4, and the smoothing capacitor ( 6) divided into a loop flowing through the rectifier circuit 2 and the alternating current power supply 1, and the positive voltage Vo can be taken out. That is, the AC input from the AC power supply 1 is rectified with a double voltage, and a positive DC voltage is obtained.

FIG. 16 has shown the relationship between the output voltage of the converter in the inverter air conditioner shown in FIG. 15A, FIG. 15B, the rotation speed of the compressor 11, and the flow rate to an inverter part. Since the output voltage of the converter is a fixed value determined by the power supply voltage and the load of the compressor, the rotation speed of the compressor 11 is controlled by varying the flow rate of the inverter.

Therefore, the maximum rotational speed of the compressor 11 is the time when the flow rate to the inverter reaches an upper limit (for example, described in Gen Kouchi, "Regulation of High Frequency Distortion and Countermeasure / Measurement Technique in Power Supply System").

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However, in the inverter air conditioner provided with the conventional converter, since the input current flows only during a period in which the voltage of the AC power source 1 is higher than the voltage of the capacitor 4 or the capacitor 5, the power factor is low and the power harmonics become large. Since the output voltage falls as the load rises, there is a problem that the maximum rotation speed of the compressor 11 does not rise.
In order to improve the harmonics, a method of connecting a reactor between the AC power supply 1 and the rectifier circuit 2 is generally used, but since the harmonics can be suppressed, only about 70% of power factor is obtained. There was a challenge to burden.
In addition, as a countermeasure for raising the output voltage, a method of mounting a boost converter of a high frequency switching type is used, but in this system, the cost is increased by using an element for high frequency switching and the noise generated by the high frequency switching is increased. There was a problem.
In general, when the load of the compressor 11 is fixed, it is known that the efficiency of the compressor 11 is improved when the output voltage of the converter is low, that is, when the flow rate to the inverter unit is high. Since the fixed value is determined by the voltage and the load of the compressor 11, it is difficult to increase the efficiency of the inverter air conditioner.

According to the invention of Claim 1, it has two input stages and two output stages, The rectifier circuit which is connected to AC power supply through a reactor on one side of the said input terminal, and converts an AC power supply voltage into a DC voltage, and two output stages of the said rectification circuit. A capacitor circuit comprising a plurality of capacitors connected in parallel and connected in series, a first switch device connected between one input point of one of the rectifier circuits and a capacitor in the capacitor circuit, and the rectifier circuit. A converter having a second switch device connected between the other input terminal and the connection point between the capacitor in the capacitor circuit; A power supply phase detection device for detecting a phase of the AC power supply; A control device for controlling the first and second switch devices based on the signal of the power supply phase detection device; An inverter device comprising an inverter part for converting the DC output voltage of the converter into an AC voltage and a compressor rotation speed control device for controlling the inverter part output frequency or the inverter part output voltage by changing the flow rate of the inverter part; And a compressor driven by the inverter device, wherein the control device comprises a first operation mode and a second operation mode, wherein the first operation mode causes the first switch device to operate at the half cycle of the AC power supply voltage. After the delay time DELTA d (0≤d) from the position of the zero cross of the power supply voltage, the ON switch is continuously ON for only the ON period DELTA t (0≤t), and the second switch device is controlled to be always OFF. The second operation mode continuously operates the first switch device only after the delay time DELTA d (0≤d) from the position of the zero cross of the AC power voltage in the half cycle of the AC power voltage for ON period DELTA t (0≤t). To ON, and to control the second switch device to always ON, and to control the harmonics of the input current flowing from the AC power and the DC output voltage of the converter. An inverter air conditioner is provided.
According to the invention of claim 3, in addition to the configuration of claim 1, a converter output voltage detection device for detecting a DC output voltage of the converter; And a storage device storing a predetermined target output voltage in advance in the control device, by increasing Δt if the converter output voltage is less than or equal to the target voltage, and decreasing Δt if the converter output voltage is greater than the target voltage. And Δt is controlled so that the converter output voltage is always close to the target voltage.
According to the invention of claim 4, in addition to the configuration of claim 1, a load detection device for detecting an input current of the converter; And a storage device in which the control device stores a combination of? D and? T according to the input current in advance, and? D and? T according to the input current from the storage device based on the output of the load detection device. Inverter air conditioner, characterized in that for selecting a combination of.
According to the invention of claim 5, in addition to the configuration of claim 1, further comprising a load detection device for detecting the input current of the converter, so that the input current is smaller when the output of the load detection device reaches a constant value An inverter air conditioner is provided which selects a combination of? D and? T.
According to invention of Claim 6, In addition to the structure of Claim 1, the compressor rotation speed detection apparatus which detects the said compressor rotation speed; And a storage device for storing a combination of? D and? T according to the compressor rotation speed in advance in the control device, and? D according to the rotation speed from the storage device based on an output of the compressor rotation speed detection device. An inverter air conditioner is provided, characterized in that the combination of? T is selected.
According to the invention of claim 7, in addition to the configuration of claim 1, the control device further has a storage device that stores a combination of? D and? T corresponding to the compressor command rotation speed in advance, and based on the compressor command rotation speed. An inverter air conditioner is provided which selects a combination of? D and? T.
According to the invention of Claim 8, In addition to the structure of Claim 1, the load detection apparatus which detects the input current of the said converter; And a storage device in which the control device stores a target output voltage of the converter according to at least one of the rotation speed of the compressor, the command rotation speed of the compressor, or the output of the load detection device, wherein the output voltage detection device [Delta] t is selected so as to be close to a target output voltage stored in the storage device based on the output of the controller, and the rotation speed control device of the compressor controls the rotation speed of the compressor by varying the flow rate to the inverter unit. 1 area; A second region in which the flow rate to the inverter unit is fixed, and the control device controls the rotation speed of the compressor by varying the converter output voltage by increasing or decreasing? T based on the output of the compressor rotation speed detection device; And a third region for controlling the rotational speed of the compressor by simultaneously varying? T in the control device and the flow rate to the inverter section.
According to the invention of claim 9, in addition to the configuration of claim 1, a load detection device for detecting an input current of the converter; And a storage device in which the control device stores a target output voltage of the converter according to at least one of the rotation speed of the compressor, the command rotation speed of the compressor, or the output of the load detection device. A first region for controlling the rotational speed of the compressor by selecting? T in the range of 0?? T? T1 so that the converter output voltage becomes a predetermined value predetermined in the storage device and changing the flow rate to the inverter section ; And a second region in which? T is fixed to t1 and the rotational speed of the compressor is varied by varying the flow rate to the inverter section.
According to invention of Claim 10, in addition to the structure of Claim 1, the increase / decrease rate of the flow rate to the said inverter part in the said compressor rotation speed control apparatus always exceeds the increase / decrease rate of (DELTA) t in the said control apparatus. An inverter air conditioner is provided.
According to invention of Claim 11, in addition to the structure of Claim 10, it further has a load detection apparatus which detects an input current, At least one of the increase / decrease rate of said (DELTA) t and the change rate of the flow rate to the said inverter part is said The inverter air conditioner is changed according to at least one of the rotation speed of a compressor, the command rotation speed of the said compressor, or the output of the said load detection apparatus.
According to invention of Claim 12, in addition to the structure of any one of Claim 1, Claim 3, or Claim 10, Furthermore, it has a load detection apparatus which detects an input current, and if the said input current exceeds predetermined value, it will become (triangle | delta) t> 0. An inverter air conditioner is set so as to be in a state of? And not larger than a predetermined value.
According to invention of Claim 13, in addition to the structure of Claim 12, the inverter air conditioner is provided in which the predetermined value of the said input current differs at the time of a cooling operation and a heating operation.
According to invention of Claim 14, in addition to the structure of any one of Claim 1, Claim 3, Claim 4, Claim 5, Claim 10, or Claim 11, It further has a rotation speed detection apparatus which detects the rotation speed of the said compressor, When the number of revolutions of the compressor exceeds a predetermined value,? T> 0 is set, and if it is below a predetermined value,? T = 0 is provided.
According to invention of Claim 15, in addition to the structure of Claim 14, the predetermined value of the said compressor rotation speed differs at the time of a cooling operation and a heating operation, The inverter air conditioner is provided.
According to invention of Claim 16, in addition to the structure of any one of Claim 1, Claim 5, Claim 10, or Claim 11, if the command rotation speed of the said compressor exceeds predetermined value, it will be in the state of (triangle | delta) t> 0, and a predetermined value Inverter air conditioners are provided, wherein? T = 0.
According to invention of Claim 17, in addition to the structure of Claim 16, the inverter air conditioner is provided in which the predetermined value of the command rotation speed of the said compressor differs at the time of a cooling operation and a heating operation.
According to invention of Claim 18, In addition to the structure of any one of Claim 1, 5, 10, or 11, AC power source frequency detection apparatus which detects the said AC power source frequency; And a storage device that stores? D in accordance with the compressor rotational speed in advance in the control device, and selects? D in accordance with the AC power frequency based on the output of the AC power frequency detection device. Air conditioning is provided.
According to invention of Claim 19, In addition to the structure of Claim 12, It is an AC power supply frequency detection apparatus which detects the said AC power supply frequency; And a storage device that stores? D in accordance with the compressor rotational speed in advance in the control device, and selects? D in accordance with the AC power frequency based on the output of the AC power frequency detection device. Air conditioning is provided.
According to the invention of claim 20, in addition to the configuration of claim 13, an AC power supply frequency detecting device for detecting the AC power supply frequency; And a storage device that stores? D in accordance with the compressor rotational speed in advance in the control device, and selects? D in accordance with the AC power frequency based on the output of the AC power frequency detection device. Air conditioning is provided.
According to the invention described in claim 21, in addition to the configuration of claim 14, an AC power supply frequency detecting device for detecting the AC power supply frequency; And a storage device that stores? D in accordance with the compressor rotational speed in advance in the control device, and selects? D in accordance with the AC power frequency based on the output of the AC power frequency detection device. Air conditioning is provided.
According to the invention of claim 22, in addition to the configuration of claim 16, an AC power supply frequency detecting device for detecting the AC power supply frequency; And a storage device that stores? D in accordance with the compressor rotational speed in advance in the control device, and selects? D in accordance with the AC power frequency based on the output of the AC power frequency detection device. Air conditioning is provided.
According to the invention described in claim 23, in addition to the configuration of any one of claims 1 and 3 to 11, the control device is used to control the first and second switch devices when Δt becomes larger than a predetermined value. Change the operation mode from the first operation mode to the second operation mode, and when? T becomes smaller than a predetermined value, the operation mode used for controlling the first and second switch devices is changed from the second operation mode. Inverter air conditioner is provided, characterized by switching to one operating mode.
According to the invention of claim 24, in addition to the configuration of claim 12, the control device uses an operation mode that is used to control the first and second switch devices in the first operation mode when? T is larger than a predetermined value. Switching to the second operation mode, and when Δt becomes smaller than a predetermined value, switching the operation mode used for controlling the first and second switch devices from the second operation mode to the first operation mode. An inverter air conditioner is provided.
According to the invention set forth in claim 25, in addition to the configuration of claim 13, the control apparatus uses an operation mode used for controlling the first and second switch apparatuses in the first operation mode when? T is larger than a predetermined value. Switching to the second operation mode, and when Δt becomes smaller than a predetermined value, switching the operation mode used for controlling the first and second switch devices from the second operation mode to the first operation mode. An inverter air conditioner is provided.
According to the invention described in claim 26, in addition to the configuration of claim 14, the control device uses an operation mode used for controlling the first and second switch devices in the first operation mode when? T is larger than a predetermined value. Switching to the second operation mode, and when Δt becomes smaller than a predetermined value, switching the operation mode used for controlling the first and second switch devices from the second operation mode to the first operation mode. An inverter air conditioner is provided.
According to the invention described in claim 27, in addition to the configuration of claim 16, the control device uses an operation mode used for controlling the first and second switch devices in the first operation mode when? T is larger than a predetermined value. Switching to the second operation mode, and when Δt becomes smaller than a predetermined value, switching the operation mode used for controlling the first and second switch devices from the second operation mode to the first operation mode. An inverter air conditioner is provided.
According to the invention described in claim 28, in addition to the configuration of claim 18, the control device uses an operation mode used to control the first and second switch devices in the first operation mode when? T is larger than a predetermined value. Switching to the second operation mode, and when Δt becomes smaller than a predetermined value, switching the operation mode used for controlling the first and second switch devices from the second operation mode to the first operation mode. An inverter air conditioner is provided.
According to the invention described in claim 29, in addition to the configuration of claim 20, the control device uses an operation mode used for controlling the first and second switch devices in the first operation mode when? T is larger than a predetermined value. Switching to the second operation mode, and when Δt becomes smaller than a predetermined value, switching the operation mode used for controlling the first and second switch devices from the second operation mode to the first operation mode. An inverter air conditioner is provided.
(Embodiment 1)

1A is a diagram showing a schematic of a circuit configuration of an inverter air conditioner according to the present invention. As shown in FIG. 1A, the inverter air conditioner includes a rectifier circuit 2 for rectifying the voltage from the AC power source 1 through the reactor 3, the capacitors 4 and 5, and the rectifier circuit 2. Power supply phase detection for detecting a phase of an AC power supply and a converter having a first switch device 7 and a second switch device 8 for connecting a connection point between the midpoint of the half bridge and the capacitors 4 and 5. The device 14, the control device 9 for controlling the first switch 7 and the second switch 8 based on the signal of the power supply phase detection device 14, and the direct current output voltage of the converter as an alternating voltage An inverter device 10 comprising a compressor rotation speed control device for controlling the inverter output frequency or the inverter output voltage by changing the inverter section to be converted and the flow rate to the inverter section, and the compressor driven by the inverter device 10. Has (11).

The rectifier circuit 2 is comprised by the half bridge of two diodes. In addition, as illustrated in FIG. 1B, the smoothing capacitor 6 may be provided in the capacitor 4 and the capacitor 5 in parallel.

As shown in Fig. 1C, the capacitors are not limited to two capacitors 4 and 5, and can be provided in an even number like the capacitors 12 and 13.

The inverter air conditioner configured as described above operates in two operation modes (mode 1 and mode 2) in accordance with the states of ON and OFF of the first switch device 7 and the second switch device 8.

배 ∼2

배의 범위의 직류 출력 전압이 얻어진다. (1) Mode 1: Based on the instruction of the control apparatus 9, the 1st switch apparatus 7 is pulse-width-controlled in the state which the 2nd switch apparatus 8 is always controlled to OFF. In mode 1, approx. Power supply voltage

2 times

A DC output voltage of twice the range is obtained.

배 이상의 직류 출력 전압까지 얻을 수 있다. (2) Mode 2: Based on the command of the control device 9, the second switch device 8 is always in the ON or pulse width controlled state, and the first switch device 7 is pulse width controlled. In mode 2, the double-voltage rectifier circuit becomes the basic circuit configuration, so that the power supply voltage

Up to twice the DC output voltage can be obtained.

Pulse width control of the first and second switch devices 7 and 8 is performed by controlling the pulse widths of the control pulses output thereto.

Here, only one control pulse is output for every half period of the power supply voltage. Hereinafter, the switching control by the pulse which outputs only one every such half period is called "1 pulse control."

This one-pulse control is equivalent to the control in the case where the carrier period in the pulse width control is set to the half period of the power supply voltage. One-pulse control is based on slow switching operation, such as 100 Hz or 120 Hz, which is twice the supply frequency. Therefore, there is no high-speed switching operation of several tens of kHz as in the active filter method, and the noise generated is small.

Therefore, the circuit for noise countermeasure can be simplified and space and cost can be reduced.

In the first switch device 7, a switch element such as a field effect transistor (FET) can be used.

In the present invention, in any of the operation modes of Mode 1 and Mode 2, the second switch device 8 is controlled by either ON fixed or OFF fixed, and basically performs the switching operation except when switching modes. I don't need it. Therefore, it is possible to use a relatively low speed switch element such as a relay for the second switch device 8.

The operation in each operation mode of the inverter air conditioner will be described using Figs. 2A, 2B and 2C.

FIG. 2A shows the change in the DC output voltage corresponding to the state of each switch, FIG. 2B shows the form of the change in duty ratio of the first switch device 7, and FIG. 2C shows the ON of the second switch device 8. • OFF status is displayed. As shown in Figs. 2A, 2B and 2C, in mode 1, the second switch device 8 is always in the OFF state, and the pulse width control is performed in accordance with the DC output voltage required by the first switch device 7. do.

That is, in mode 1, when the higher DC output voltage is to be obtained, the pulse width of the control pulse of the first switch device 7 is made larger. At that time, the duty ratio for the first switch device 7 reaches a predetermined value (100% in the case of FIG. 2B) (at this time, the first switch device 7 is controlled to be ON during the half cycle of the power frequency). When a higher DC output voltage is required, since the pulse width of the first switch device 7 cannot be controlled more than that, the operation mode is switched from mode 1 to mode 2.

Before and after switching from mode 1 to mode 2, the duty ratio of the first switch device 7 is switched from 100% to 0%, and the second switch device 8 is switched from OFF to ON. At this time, since the circuits before and after the switching are all double voltage rectifier circuits themselves, there is no variation in the DC output voltage before and after the switching.

In addition, in mode 2, the 2nd switch device 8 is always controlled ON, and the 1st switch device 7 is pulse-width-controlled according to a DC output voltage. In mode 2, the circuit configuration of the double-voltage rectifier circuit base is obtained, so that a direct current output voltage about twice as large as that in mode 1 is obtained. In the case of decreasing the DC output voltage in mode 2, when the duty ratio of the first switch device 7 reaches a predetermined value, the second switch device 8 is switched from ON to OFF, and the first switch device ( The mode 2 to mode 1 is switched by setting the duty ratio of 7) from 0% to 100%.

3A, 3B, and 3C show control pulses, power supply voltages, input currents, and direct current output voltages for the first and second switch devices 7 and 8 in mode 1 of the inverter air conditioner according to the first embodiment. The waveform of each voltage of the smoothing capacitor 6) and the voltage of the connection point of the capacitors 4 and 5 is shown. As shown in FIG. 3A, FIG. 3B, FIG. 3C, the control pulse of the 1st switch apparatus 7 is output in the zero crossing position of a power supply voltage, and only one is output for every half period of a power supply voltage.

As shown in the figure, with this control pulse, the input current starts to flow from the time point when the power supply voltage becomes equal to or higher than the midpoint voltage of the capacitors 4 and 5. That is, during period A, the input current can be conducted in excess, and the current conduction period can be extended in this way, so that the power factor can be improved. In addition, since the waveform of the input current can be made close to the waveform of the power supply voltage, harmonic regulation can be cleared.

2A, 2B, and 2C, the output voltage does not increase until the control pulse is somewhat increased. This is because the power supply voltage is small and the input current does not flow in the section where the control pulse is small.

In addition, at the time of mode switching, it is preferable that the 2nd switch device 8 switches ON / OFF at the position of the zero cross of a power supply voltage.

4A, 4B, and 4C are diagrams showing waveforms of control pulses, power supply voltages, and input currents for the first and second switch devices 7 and 8 in mode 2 of the inverter air conditioner according to the first embodiment. to be. In FIG. 4A, FIG. 4B, FIG. 4C, the control pulse of the 1st switch apparatus 7 is output after delaying (DELTA) d from the zero cross position of a power supply voltage.

DELTA d needs to set the harmonic regulation to a value that can be cleared. It is preferable to set Δd to a larger value as the load output decreases, but it is not necessary to clear harmonic regulation, but may be Δd = 0 (ie, the control pulse of the first switch device 7 may be zero. Output at the timing of the cross).

In the mode 1, the input switch 7 does not start to flow even when the control pulse is turned ON unless the power supply voltage is equal to or higher than the midpoint voltage of the capacitors 4 and 5. The control pulse is turned ON and the input current starts to flow.

As described above, by turning on the first switch device 7, it becomes possible to conduct the input current extraly during the period? T of the pulse width, so that the current conduction period can be extended as in the case of the mode 1, and the power factor is increased. It can be improved. In addition, the waveform of the input current can be made close to the waveform of the power supply voltage, and the harmonic regulation can be cleared.

배 이상의 직류 출력 전압이 얻어지고, 게다가 그 출력 전압치가 제어 가능해지므로, 압축기의 최대 회전수의 증가와 고 효율화가 가능해진다.In addition, the suppression of harmonics of the input current and high power factor are compatible, and two to two times the voltage value of the AC power supply.

Since more than twice the direct current output voltage is obtained and the output voltage value can be controlled, the maximum rotation speed of the compressor can be increased and the efficiency can be improved.

5A, 5B, and 5C are diagrams illustrating changes in power supply voltage and input current during mode switching.

As shown in Figs. 5A, 5B and 5C, almost the same current waveforms are obtained immediately before and immediately after mode switching. Thereby, there is no change of the current waveform at the time of mode switching, and the DC output voltage can be changed smoothly within the output voltage range. That is, the sudden change of the voltage at the time of changing the target output voltage can be suppressed.

As described above, when the DC output voltage of the converter is controlled at a low voltage, the compressor can be operated with high efficiency, and the efficiency of the air conditioner is increased. Moreover, when the direct current output voltage is controlled to a high voltage, the maximum rotation speed of the compressor can be increased, and the maximum capacity of the air conditioner is increased. In addition, the maximum input power of the air conditioner is generally

Maximum input power = input voltage x maximum input current x power factor

Is displayed. Since the input voltage is fixed and the maximum input current is limited to the maximum capacity of the outlet, the maximum input power rises by improving the power factor. As a result, the maximum capacity of the air conditioner can be improved. Moreover, since the sudden change of the power supply voltage at the time of mode switching can be suppressed, it becomes possible to operate an air conditioner stably.

(Embodiment 2)

In FIG. 6, the output voltage detection apparatus 15 is added to FIG. 1, and the control apparatus 9 sets ON period (DELTA) t of the 1st switch apparatus 7 based on the output. The stability of the rotational speed control of the compressor is greatly influenced by the variation of the output voltage. Therefore, in the above configuration, the output voltage detecting device 15 detects the output voltage and transfers it to the control device 9. And the control apparatus 9 sets (DELTA) t so that it may become a predetermined output voltage. That is, Δt is controlled so that the converter output voltage is always close to the target voltage by increasing Δt when the converter output voltage is below the target voltage and decreasing Δt when the converter output voltage is above the target voltage. And the speed control apparatus of a compressor controls the rotation speed of a compressor by varying the flow rate to an inverter part.

By the above operation, the output voltage can be made constant regardless of the presence or absence of load fluctuations and power supply voltage fluctuations, and stable compressor rotation speed control is possible.

(Embodiment 3)

FIG. 7 shows the delay time Δd and Δt from the zero crossing of the power supply voltage to the load detection device 16 and the control device 9 from the zero crossing of the first switch device 7 to ON. The storage device 9a for storing the data is added.

In the above structure, the memory | storage device 9a memorize | stores the table which calculated | required the optimal value of (DELTA) d, (DELTA) t in advance according to the magnitude | size of a load, receives the output of the load detection apparatus 16, and receives it to the magnitude | size of a load. The corresponding Δd and Δt are read from the table, and the first switch device 7 is driven based on them.

By the above operation, the optimum power factor, output voltage value, and harmonic suppression effect are obtained for all loads.

(Embodiment 4)

In the structure of FIG. 7, the control apparatus 9 receives the output of the load detection apparatus 16 which detects the input current of a converter, and when output reaches a predetermined magnitude, it increases and decreases (triangle | delta) t or (triangle | delta) d, and outputs it. The combination which becomes smaller than this is selected, and the 1st switch apparatus 7 is driven based on it.

By the above operation, the optimum power factor can be obtained especially at high load, the power supply capacity can be effectively used, and the maximum capability of the air conditioner can be improved.

(Embodiment 5)

FIG. 8 adds the compressor rotation speed detection apparatus 17 and the memory | storage device 9a which stores (DELTA) d and (DELTA) t in the control apparatus 9 in FIG. In the above structure, the memory | storage device 9a memorize | stores the table which calculated | required the value of optimal (D) and (D) in advance according to the rotation speed of the compressor 11, and outputs the output of the compressor rotation speed detection device 17. And Δd and Δt corresponding to the rotational speed are read from the table, and the first switch device 7 is driven based on them. Alternatively, the storage device 9a may store a combination of? D and? T corresponding to the compressor command rotation speed in advance, and select a combination of? D and? T based on the compressor command rotation speed.

By the above operation, the optimum power factor, output voltage value, and harmonic suppression effect are obtained for all rotation speeds.

Embodiment 6

FIG. 9 adds the output voltage detection device 15 and the compressor rotation speed detection device 17 to FIG. 1. In addition, in the configuration of FIG. 10, the controller 9 sets? T according to the rotational speed of the compressor 11 to drive the first switch device 7 to control the output voltage to a predetermined value. A first region for controlling the rotational speed of the compressor 11 by varying the flow rate of the negative flow, a second region for controlling the rotational speed of the compressor 11 by varying the output voltage by fixing the flow rate of the inverter section; The relationship between the output voltage, the flow rate to the inverter section, and the compressor rotation speed when the output voltage and the flow rate to the inverter section are provided together to control the rotation speed of the compressor 11 are shown.

In the above configuration, in the first region, the output voltage detecting device 15 detects the DC output voltage of the converter and transfers it to the control device 9. And the control apparatus 9 drives (DELTA) t so that it may become a predetermined output voltage, and will drive the 1st switch apparatus 7. As shown in FIG. In the second region, the compressor rotation speed detection device 17 detects the rotation speed of the compressor 11 and transmits it to the control device 9.

And the control apparatus 9 sets (DELTA) t so that the compressor 11 may predetermined speed, and will drive the 1st switch apparatus 7. As shown in FIG.

In the third region, the compressor rotation speed detection device 17 detects the rotation speed of the compressor 11 and transmits it to the control device 9. And the control apparatus 9 sets (DELTA) t so that the compressor 11 may predetermined | prescribed rotation speed, will drive the 1st switch apparatus 7, and the flow rate to the inverter part in inverter control will increase and decrease by (DELTA) t. Increase or decrease according to

As described above, by setting DELTA t to control the first switch device 7, the output voltage can be made constant in the first region regardless of the presence or absence of load fluctuations and output voltage fluctuations. Becomes possible. In addition, high efficiency of the air conditioner can be realized by determining an output voltage at which the overall efficiency of the converter and the inverter device is optimal at each rotation speed in advance.

In the second region, the rotation speed of the compressor 11 can be controlled in a state where the flow rate to the inverter section is 100%, so that the loss of switching elements of the inverter section can be reduced, resulting in high efficiency and at the same time output voltage. Since the rotation speed can be increased by raising, the maximum rotation speed of the compressor 11 is raised, and the maximum capacity of the air conditioner is raised.

In the third region, the flow rate to the inverter unit and the output voltage are raised together to control the rotation speed of the compressor 11 only by the flow rate to the inverter unit, and to control the rotation speed of the compressor 11 only by the output voltage. By setting the changeover period of the region, the rotation speed of the compressor 11 can be smoothly changed even during the transition between the regions.

(Embodiment 7)

In the configuration of FIG. 9, the control device 9 sets? T at 0 ≦ Δt ≦ t1 so that the output voltage is always constant, and changes the flow rate to the inverter section. Δt and output voltage when the first region for controlling the rotational speed, and the second region for controlling the rotational speed of the compressor 11 by fixing Δt to t1 and varying the flow rate to the inverter section, and The relationship of the flow rate to an inverter part is shown. The target output voltage is determined according to at least one of the revolution speed of the compressor, the command revolution speed of the compressor, or the input current of the converter.

In the above configuration, the output voltage detecting device 15 detects the DC output voltage of the converter and transfers it to the control device 9. And the control apparatus 9 sets (DELTA) t in the range of 0 <= (triangle | delta) t <= t1 so that an output voltage may become predetermined predetermined value.

In the first region, the output voltage of the converter is controlled to a predetermined predetermined value, and the rotation speed of the compressor 11 is controlled by varying the flow rate of the inverter. When the load goes up, the DC output voltage of the converter is controlled to a predetermined value by increasing? T, so that under some loads,? T = t1 is reached and the process shifts to the second region.

In the second region, the output voltage of the converter is lower than a predetermined value, but regardless of this, the control device 9 is fixed at Δt = t1 and the compressor 11 is rotated by varying the flow rate to the inverter unit. Control the number. When the output voltage of the converter rises by lowering the load while Δt is fixed to t1 and reaches a predetermined value, the transition from the second area to the first area occurs.

By the above configuration, by setting the upper limit value of Δt, the output voltage can be prevented from rising more than necessary while appropriately suppressing the harmonic current.

In addition, since the maximum capacity of the first switch device 7 depends on the maximum value of Δt, by setting the upper limit of Δt, the maximum capacity of the first switch device 7 can be limited, resulting in miniaturization and cost of elements. Reduction is possible. In addition, since the rotation speed of the compressor can be controlled only by the flow rate to the inverter section in the region where Δt is fixed, the rotation speed control of the compressor can be simplified.

Embodiment 8

In the structure of FIG. 6, the control apparatus 9 sets (DELTA) t so that it may become a predetermined output voltage, and controls the rotation speed of a compressor by increasing or decreasing the flow-through rate to an inverter part. In this case, the influence of the increase / decrease rate of the flow rate to the inverter unit for controlling the rotational speed of the compressor and the increase / decrease speed of? T for controlling the DC output voltage of the converter will be described on the rotational speed of the compressor.

For example, when the flow rate to the inverter section is increased to increase the number of revolutions of the compressor, the load increases at the same time, so that the output voltage decreases. Therefore, the control apparatus 9 raises (DELTA) t so that it may become a predetermined output voltage, and raises an output voltage.

At this time, if the rate of increase and decrease of the flow rate to the inverter section is slow, the decrease in the flow rate to the inverter section is slow with respect to the increase in the output voltage, and the rotation speed of the compressor is further increased, resulting in a case where the predetermined rotation speed is exceeded. As stable rotation speed control becomes difficult, there is a possibility that the DC output voltage control of the converter and the compressor rotation speed control of the inverter device interfere with each other. Therefore, by setting the increase / decrease rate of the flow rate of the inverter portion to a speed which sufficiently exceeds the rise / fall rate of the DC output voltage due to the increase / decrease of Δt, the rotation speed of the compressor corresponds to the change of the DC output voltage very short time. It becomes possible, and stable rotation speed control is attained. In addition, the load detection device 16 is added, and at least one of the increase / decrease speed of Δt and the change rate of the flow rate of the inverter is at least one of the rotation speed of the compressor, the command rotation speed of the compressor, or the output of the load detection device. By changing according to one, stable rotation speed control is attained.

(Embodiment 9)

FIG. 12 shows the relationship between the input current and Δt when Δt = 0 when the input current value is equal to or smaller than the predetermined value and Δt> 0 when the predetermined value is exceeded. When the load is small, by setting? T = 0, there is a possibility that the DC output voltage rises more than necessary.

In the above configuration, the control device 9 selects? T = 0 when the input current transmitted from the load detection device 16 is equal to or less than a predetermined value, and selects? T> 0 when exceeding the predetermined value, thereby providing a direct current. Abnormal rise of the output voltage can be prevented.

Embodiment 10

FIG. 13 shows the relationship between the rotational speed of the compressor and Δt when Δt = 0 when the rotational speed of the compressor is less than or equal to the predetermined value and Δt> 0 when the predetermined value is exceeded.

In the above structure, the control apparatus 9 selects (triangle | delta) t = 0 when the rotation speed transmitted from the compressor rotation speed detection apparatus 17 is below a predetermined value, and selects (triangle | delta) t> 0 when it exceeds the predetermined value, Abnormal rise of the DC output voltage can be prevented.

(Embodiment 11)

In FIG. 14, the AC power source frequency detecting device 14a is added to FIG. 7, and the control device 9 sets Δd based on the output. In the specific load fluctuation range, Δd can obtain an appropriate power factor and harmonic suppression effect even if the value is constant without fine adjustment according to the load. On the other hand, it is necessary to switch to an appropriate value with respect to an AC power supply frequency according to 50Hz and 60Hz, respectively.

Therefore, in the above configuration, the AC power supply frequency detecting device 14a detects the AC power supply frequency and transmits it to the control device 9. And the control apparatus 9 sets predetermined (D) d according to an AC power supply frequency, and drives the 1st switch apparatus 7 based on it.

By the above operation, Δd can be made constant in a specific load region, so that control can be simplified, and an appropriate power factor, output voltage value, and harmonic suppression effect can be obtained regardless of the AC power supply frequency. .

In addition, although the compressor of an inverter air conditioner was demonstrated in said each embodiment of this application, even if it is another motor, for example, the motor of a blower, it is technically the same and there is no problem.

As described above, according to the inverter air conditioner, the first and second switch devices are provided between the connection points between the plurality of capacitors connected to the DC output terminal of the rectifier circuit of the converter and the AC input terminal of the rectifier circuit, respectively. By appropriately driving the two-switch device and appropriately switching the rotational speed control method of the compressor, both high power factor and harmonic suppression can be achieved, and the maximum capacity and efficiency of the air conditioner can be improved.

According to the present invention, the DC output voltage of the converter is prevented from rising more than necessary at light load, and breakdown voltage breakdown of each element in the electronic control device of the inverter air conditioner can be prevented.

In addition, the present invention is that the predetermined value of the input current, the compressor rotational speed or the command rotational speed of the compressor is different in the cooling operation and the heating operation, and it is possible to drive the converter at the optimum switching point in each operation. The power consumption of the air conditioner can be reduced.

Claims (29)

A rectifier circuit having two input terminals and two output terminals connected to an AC power supply through a reactor on one side of the input terminal and converting an AC power supply voltage into a DC voltage, and connected in parallel between the two output terminals of the rectifying circuit and connected in series A capacitor circuit comprising a plurality of connected capacitors, a first switch device connected between one input terminal of the rectifier circuit and one connection point between the capacitors in the capacitor circuit, the other input terminal of the rectifier circuit and the capacitor circuit A converter having a second switch device connected between the connection points between condensers within; A power supply phase detection device for detecting a phase of the AC power supply; A control device for controlling the first and second switch devices based on the signal of the power supply phase detection device; An inverter device comprising an inverter part for converting the DC output voltage of the converter into an AC voltage and a compressor rotation speed control device for controlling the inverter part output frequency or the inverter part output voltage by changing the flow rate of the inverter part; And Having a compressor driven by the inverter device, The control device is composed of a first operation mode and a second operation mode, In the first operation mode, the first switch device is turned ON only after the delay time DELTA d (0≤d) from the position of the zero cross of the AC power voltage in the half cycle of the AC power voltage. Continuously control to ON, and control the second switch device to always OFF, In the second operation mode, the first switch device is turned ON only after the delay time DELTA d (0≤d) from the position of the zero cross of the AC power voltage in the half cycle of the AC power voltage. Continuous ON control, and the second switch device is always ON, Inverter air conditioner, characterized in that to control the harmonics of the input current flowing from the AC power source and the DC output voltage of the converter. delete The method of claim 1, A converter output voltage detection device for detecting a DC output voltage of the converter; And The control device further has a storage device that stores a predetermined target output voltage in advance, Controlling? T so that the converter output voltage is always close to the target voltage by increasing? T if the converter output voltage is below the target voltage and decreasing? T if the converter output voltage is above the target voltage. Inverter air conditioner, characterized in that. The method of claim 1, A load detection device for detecting an input current of the converter; And The control device further has a storage device in which a combination of? D and? T corresponding to the input current is stored in advance, And a combination of? D and? T according to the input current is selected from the storage device based on the output of the load detection device. The method of claim 1, It further has a load detection device for detecting the input current of the converter, And a combination of? D and? T is selected so that the input current becomes smaller when the output of the load detection device reaches a certain value. The method of claim 1, A compressor rotation speed detection device for detecting the compressor rotation speed; And The control device further has a storage device for storing a combination of? D and? T corresponding to the compressor rotational speed in advance, And a combination of? D and? T corresponding to the rotational speed from the storage device based on the output of the compressor rotational speed detection device. The method of claim 1, The control device further has a storage device for storing a combination of? D and? T according to the compressor command rotation speed in advance, A combination of? D and? T is selected based on the compressor command rotation speed. The method of claim 1, A load detection device for detecting an input current of the converter; And The control apparatus further has a storage device which previously stored a target output voltage of the converter according to at least one of the rotation speed of the compressor, the command rotation speed of the compressor, or the output of the load detection device, Δt is selected to be close to a target output voltage stored in the storage device based on the output of the output voltage detection device, and the rotation speed of the compressor is changed by the rotation speed control device of the compressor changing the flow rate to the inverter unit. A first area for controlling the number; A second region in which the flow rate to the inverter unit is fixed, and the control device controls the rotation speed of the compressor by varying the converter output voltage by increasing or decreasing? T based on the output of the compressor rotation speed detection device; And An inverter air conditioner having a third region for controlling the rotation speed of the compressor by simultaneously varying? T in the control device and a flow rate of the inverter. The method of claim 1, A load detection device for detecting an input current of the converter; And The control apparatus further has a storage device which previously stored a target output voltage of the converter according to at least one of the rotation speed of the compressor, the command rotation speed of the compressor, or the output of the load detection device, The control device selects Δt in a range of 0 ≦ Δt ≦ t1 so that the converter output voltage becomes a predetermined value predetermined in the storage device, and further changes the rotation speed of the compressor by varying the flow rate to the inverter unit. A first area to control; And An inverter air conditioner having a second region in which? T is fixed to t1 and the rotation speed of the compressor is varied by varying the flow rate of the inverter. The method of claim 1, The increase / decrease rate of the flow rate to the said inverter part in the said compressor rotation speed control apparatus always exceeds the increase / decrease rate of (DELTA) t in the said control apparatus. The method of claim 10, Further has a load detection device for detecting an input current, At least one of the increase / decrease speed of the? T and the change rate of the flow rate to the inverter unit is changed according to at least one of the rotation speed of the compressor, the command rotation speed of the compressor, or the output of the load detection device Inverter air conditioner. The method according to any one of claims 1, 3 or 10, Further has a load detection device for detecting an input current, An inverter air conditioner if the input current exceeds a predetermined value, the state is Δt> 0, and if the input current is less than the predetermined value, the state is Δt = 0. The method of claim 12, And a predetermined value of the input current is different in a cooling operation and a heating operation. The method according to any one of claims 1, 3, 4, 5, 10 or 11, It further has a rotation speed detection device for detecting the rotation speed of the compressor, Δt> 0 if the rotation speed of the compressor exceeds a predetermined value, and Δt = 0 if less than the predetermined value. The method of claim 14, And a predetermined value of the compressor rotational speed is different in a cooling operation and a heating operation. The method according to any one of claims 1, 5, 10 or 11, The inverter air conditioner is set to the state of (triangle | delta) t> 0 when the command rotation speed of the said compressor exceeds predetermined value, and (triangle | delta) t = 0 when it is below a predetermined value. The method of claim 16, Inverter air conditioner, characterized in that the predetermined value of the command rotational speed of the compressor is different in the cooling operation and the heating operation. delete delete delete delete delete The method according to any one of claims 1 or 3 to 11, The control device switches the operation mode used for controlling the first and second switch devices from the first operation mode to the second operation mode when Δt becomes larger than the predetermined value, and Δt is smaller than the predetermined value. When switched off, the inverter air conditioner for switching the operation mode used for controlling the first and second switch device from the second operation mode to the first operation mode. The method of claim 12, The control device switches the operation mode used for controlling the first and second switch devices from the first operation mode to the second operation mode when Δt becomes larger than the predetermined value, and Δt is smaller than the predetermined value. When switched off, the inverter air conditioner for switching the operation mode used for controlling the first and second switch device from the second operation mode to the first operation mode. The method of claim 13, The control device switches the operation mode used for controlling the first and second switch devices from the first operation mode to the second operation mode when Δt becomes larger than the predetermined value, and Δt is smaller than the predetermined value. When switched off, the inverter air conditioner for switching the operation mode used for controlling the first and second switch device from the second operation mode to the first operation mode. The method of claim 14, The control device switches the operation mode used for controlling the first and second switch devices from the first operation mode to the second operation mode when Δt becomes larger than the predetermined value, and Δt is smaller than the predetermined value. When switched off, the inverter air conditioner for switching the operation mode used for controlling the first and second switch device from the second operation mode to the first operation mode. The method of claim 16, The control device switches the operation mode used for controlling the first and second switch devices from the first operation mode to the second operation mode when Δt becomes larger than the predetermined value, and Δt is smaller than the predetermined value. When switched off, the inverter air conditioner for switching the operation mode used for controlling the first and second switch device from the second operation mode to the first operation mode. delete delete

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