JPH10178736A - Protective device for air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the circuit of a protective device and reduce the number of parts of the device and, at the same time, to simplify the software of the device and reduce the operating load of the device by making the device make protective operations upon detecting the abnormality of a power source including the opposite phase and open phase of the power source by comparing a zero-crossing signal with a half-wave signal. SOLUTION: When a phase rotation discriminating means 19 which discriminates the phase rotation of a power supply voltage from an overcurrent discriminating signal from an overcurrent discriminating and detecting means 15 and a zerocrossing signal from a zero-crossing detecting means 16 discriminates that the phase rotation of the power supply voltage is not suitable to the equipment of an air conditioner, a circuit changing means 11 changes the phase rotation of the power supply voltage so that the phase rotation can become suitable to the equipment. When the power supply voltage is in an open phase, the time until the zero-crossing signal rises after the overcurrent discriminating signal rises becomes about the 1/6 of a period. Therefore, the opposite phase of the power supply voltage can be detected by measuring the deviation between the rising timing of the waveforms of the overcurrent discriminating and zero-crossing signals and comparing both signals with each other.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a protection device for an air conditioner which can detect an abnormality such as a reverse phase or an open phase of a power supply voltage without adding a new signal detection circuit.

[0002]

FIG. 9 shows a conventional general air conditioner (for example, product type PUH-J2 manufactured by Mitsubishi Electric Corporation).
FIG. 2 is a configuration diagram showing an 80FA) and its control device.
In FIG. 9, 1 is a compressor, 2 is an outdoor unit side heat exchanger, 3
Denotes a fan for an outdoor unit, 4 denotes a motor for a fan, and 5 denotes a motor for a compressor.
Reference numeral 6 denotes an expansion device, and reference numeral 7 denotes an indoor unit-side heat exchanger, and these constitute an indoor unit B. Reference numeral 8 denotes a liquid-side refrigerant pipe, and reference numeral 9 denotes a gas-side refrigerant pipe. The outdoor unit A and the indoor unit B are connected to each other to form a refrigerant circuit of the air conditioner. 10 is a three-phase AC power supply, 12 is an overcurrent determining means for detecting an overcurrent on the line and opening the B contact, and 13 is for stopping the compressor motor 5 by opening the circuit. The circuit opening / closing means 14 is a phase control means for controlling the rotation speed of the fan motor 4. Reference numeral 15 denotes overcurrent determination detection means provided between the RTs of the three-phase AC power supply 10, and reference numeral 16 denotes zero cross detection means provided between the RS phases. Reference numeral 17 denotes a control circuit of the outdoor unit A, reference numeral 28 denotes first antiphase / open-phase determination signal detection means provided between the ST phases of the three-phase AC power supply 10, and reference numeral 29 denotes a control circuit provided between the TR phases. Second
Of the negative phase / open phase determination signal detecting means.

[0003] The control means of the air conditioner configured as described above will be described with reference to Figs. FIG. 10 shows the overcurrent determination detecting means 1 in FIG.
5 is an example of a circuit that realizes No. 5; Microcomputer input port P
Reference numeral 1 denotes a port to which a signal obtained by the overcurrent determination detection unit 15 is input. When the photocoupler PC1 is not turned on, the voltage level of the microcomputer input port P1 becomes Hi. When the photocoupler PC1 is turned on, a current flows from the collector side of the photocoupler to the emitter side. The voltage level of P1 is L
It becomes o.

The photocoupler PC1 is turned on when a voltage of a certain level or more is applied from the T phase to the R phase.
Therefore, of the power supply voltage input from the three-phase AC power supply 10,
The waveform (a) shown in FIG. 13 shows only the voltage between the TR phases, and when the voltage Va is the reference voltage at which the photocoupler is turned on, the overcurrent determination signal input to the microcomputer input port P1 is as shown in FIG. The waveform (b) of FIG.

As described above, the overcurrent determination signal is output once a cycle as a signal having a width of about a half cycle. If the overcurrent determining means 12 detects an overcurrent on the line,
Since the contact is opened, the overcurrent determination detecting means 15
No R-phase voltage is applied, and no overcurrent determination signal is input to the microcomputer input port P1. Therefore, when no signal is input to the microcomputer input port P1 for one cycle or more, it can be determined that an overcurrent has been detected.

FIG. 11 is an example of a circuit that realizes the zero-crossing detecting means 16 in FIG. The microcomputer input port P2 is a port to which a signal obtained by the zero-cross detecting means 16 is input. When the photocoupler PC2 and the photocoupler PC3 are not both ON, the voltage level of the microcomputer input port P2 becomes Hi, and when one of the photocoupler PC2 and the photocoupler PC3 is ON, the microcomputer input port P2 is turned on. The voltage level of P2 becomes Lo.

The photocoupler PC2 is turned on when a voltage of a certain level or more is applied from the R phase to the S phase, and the PC3 is turned on when a voltage of a certain level or more is applied from the S phase to the R phase. Power supply voltage R-
When the waveform showing only the S-phase voltage is the waveform (c),
The zero-cross signal input to the microcomputer input port P2 has a waveform (d). Thus, the zero cross signal is output once every half cycle. The zero-cross signal is a reference signal for controlling the phase of the fan motor 4.

The first antiphase / open phase determination signal detecting means 28 and the second antiphase / open phase determination means 29 in FIG.
This can be realized by a circuit having substantially the same configuration as that of the overcurrent determination detection unit 15.

FIG. 12 shows the zero cross detecting means 16, the first
This is an example of a circuit that realizes the antiphase / open phase determination signal detection means 28 and the second antiphase / open phase signal detection means 29 of FIG. The microcomputer input port P3 is a port to which the signal obtained by the first antiphase / open phase determination signal detection means 28 is input, and the microcomputer input port P4 is a second antiphase / open phase determination signal detection means. This is a port to which the signal obtained by 29 is input. When the power supply voltage input from the three-phase AC power supply 10 has the waveform (e) shown in FIG. 13, the signals input to the microcomputer input ports P2 to P4 change from the waveforms (f) to (h) in FIG. .

By measuring the timing at which these signals are inverted, it is possible to determine the reverse phase or open phase of the power supply voltage. When the power supply voltage is normal, signal inversion can be detected in the order of (1) to (4) in FIG. When the power supply voltage is in the opposite phase, the inversion timings of (2) and (3) are opposite, so that the opposite phase can be detected. If the R phase is open, the photocoupler P
Since both C4 and PC2 are turned ON only when a voltage equal to or higher than a certain level is applied from the T phase to the S phase, the waveform (f) and the waveform (g) have the same waveform. Therefore, since the signal inversion timing is simultaneous, it is possible to detect the reverse phase.
Similarly, when the S phase is missing, the waveform (f) and the waveform (h) shown in FIG. 13 are the same, and when the T phase is missing, the waveform (g) and the waveform (g) in FIG. Since h) has the same waveform, the opposite phase can be detected.

[0011]

In the conventional air conditioner as described above, a signal detection circuit is provided for controlling the phase of the fan controller, detecting the overcurrent of the power supply voltage, and determining whether the phase is reversed or open. Since a circuit is required, the number of components is increased, and the operation load of software is increased due to the determination processing of the signal.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has as its object to simplify the circuit and reduce the number of components, and to simplify the software and reduce the operation load. The purpose is to achieve the goal. Another object of the present invention is to obtain a highly reliable air conditioner.

[0013]

According to a first aspect of the present invention, there is provided a protection apparatus for an air conditioner, which detects a power supply abnormality including a reverse phase and an open phase of a power supply by comparing a zero-cross signal and a half-wave signal to protect the power supply. The operation is performed.

In the protection device for an air conditioner according to the second aspect of the present invention, the zero-cross signal and the half-wave signal are processed by the common arithmetic means, thereby detecting an abnormality of the power supply including a reverse phase and an open phase of the power supply. And a protection operation is performed.

In the air conditioner protection device according to a third aspect of the present invention, in the air conditioner operating with a three-phase voltage, a zero cross detection circuit for detecting a voltage zero cross point of a power supply and a pressure switch, a temperature switch, and the like are provided. A protection circuit for stopping the air conditioner in an abnormal state, wherein a detection input circuit of the protection circuit is obtained by opening and closing a half-wave signal of an AC power supply, and the zero-cross signal and the half-wave signal are detected using different power supply phases. It is characterized by doing.

According to a fourth aspect of the present invention, there is provided a protection device for an air conditioner, wherein a shift time detecting means for detecting a shift time between a rising timing of a zero-cross signal and a half-wave signal, and a phase rotation direction of a power supply voltage based on a length of the shift time. Rotation determination means for determining whether the rotation of the air conditioner is not suitable for the rotation direction of a compressor, a blower fan, or the like in the air conditioner, and abnormal stop means for stopping the operation of the air conditioner, and displaying an abnormal state. And an abnormality display means.

According to a fifth aspect of the present invention, there is provided a protection device for an air conditioner, wherein first opening / closing means for opening / closing an A-phase input and an A-phase output and a B-phase input and a B-phase output; A second opening / closing means for opening / closing the B-phase input and the A-phase output is provided, and the phase rotation determining means is disposed at a stage subsequent to the first and second opening / closing means, so that the phase rotation is in a direction desired by the device. like,
The first or the second according to the determination result of the phase rotation determining means.
And a changing means for selectively closing the opening / closing means.

In the protection device for an air conditioner according to a sixth aspect of the present invention, the determination by the phase rotation determining means is performed only once after the power is turned on and after the recovery from the power failure.

In the protection apparatus for an air conditioner according to a seventh aspect of the present invention, when the zero-cross signal is not inputted for more than 1/2 period of the power supply frequency from the zero-cross signal and the half-wave signal, or when the half-wave signal is longer than the power supply frequency period When there is no input, or when the rising edge of the zero-cross signal and the half-wave signal match, the power supply has an open-phase detecting means for detecting the open phase of the power supply. It is characterized by comprising abnormal stop means for stopping the operation of the harmony device and abnormal display means for displaying an abnormal state.

In the air conditioner protection apparatus according to an eighth aspect of the present invention, the phase loss detection of the phase loss detecting means is always performed when the power is turned on.

A ninth aspect of the present invention is characterized in that the open-phase detection of the open-phase detecting means is always performed during the operation of the compressor immediately after the start of the compressor.

In the air conditioner protection device according to the tenth aspect of the present invention, a circuit that reacts the half-wave signal to a half-wave rectified voltage of a power supply at a predetermined voltage value or more (for example, a voltage comparison circuit,
Transistor-emitter drive circuit / photocoupler drive circuit, etc.). When the half-wave signal width exceeds a predetermined ratio with respect to the zero-cross signal cycle due to the signal width of the half-wave signal and the zero-cross signal cycle, the power supply voltage A power-supply-voltage-drop detecting means for detecting a drop; when the power-supply-voltage-drop detecting means detects a power-supply-voltage drop, abnormal stopping means for stopping operation of the air-conditioning apparatus, and abnormal displaying means for displaying an abnormal state. It is characterized by having.

In the air conditioner protection device according to the eleventh aspect of the present invention, when the power supply voltage drop detecting means detects the power supply voltage drop, the operation of the air conditioner is temporarily stopped, and thereafter the restart is prevented for a predetermined time. A standby unit, a restart unit that restarts the air conditioner if the detection of the power supply voltage drop detection unit is normal after a predetermined time has elapsed, and an air conditioner that is in a state where the power supply voltage is low even after the predetermined time has passed. And an abnormal display means for displaying an abnormal state.

In the air conditioner protection apparatus according to the twelfth aspect, the detection of the power supply voltage drop is always performed after the power is turned on.

A thirteenth aspect of the present invention is characterized in that the detection of the power supply voltage drop is always performed during the operation of the compressor immediately after the start of the compressor.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. FIG. 1 is a configuration diagram showing an air conditioner and a control configuration thereof as an example of an embodiment of the present invention. In FIG. 1, 1 is a compressor, 2 is an outdoor unit side exchanger,
Reference numeral 3 denotes a fan for an outdoor unit, 4 denotes a motor for a fan, and 5 denotes a motor for a compressor. Reference numeral 6 denotes an expansion device, and reference numeral 7 denotes an indoor unit-side heat exchanger, and these constitute an indoor unit B. And 8
Is a liquid-side refrigerant pipe, and 9 is a gas-side refrigerant pipe. The outdoor unit A and the indoor unit B are connected to each other through these to constitute a refrigerant circuit of the air conditioner.

Reference numeral 10 denotes a three-phase AC power supply,
By selectively closing the circuit opening and closing means,
Circuit changing means for changing the phase rotation direction of the power supply voltage, 12 detects overcurrent on the line and opens overcurrent contact, and 13 sets overcurrent determining means for opening the B contact. Circuit opening / closing means 14 for stopping the rotation of the fan motor 4 is a phase control means for controlling the rotation speed of the fan motor 4. 15 is an overcurrent determination detecting means provided between the RT phases of the three-phase AC power supply 10 for detecting a half-wave signal between the power phases, and 16 is a zero-cross detection provided between the RS phases. Means. 17
Is a control circuit of the outdoor unit A.

As will be described later, a phase rotation determining means 19 for determining a phase rotation of the power supply voltage from the overcurrent determination signal obtained by the overcurrent determination detecting means 15 and the zero-cross signal obtained by the zero-cross detecting means 16. (FIG. 2), and when the phase rotation determining means 19 determines that the phase rotation of the power supply voltage is not suitable for the equipment of the air conditioner, the phase rotation of the power supply voltage is determined by the circuit changing means 11. , To be adapted to the equipment of the air conditioner. This circuit changing means 11 is connected to the R phase of the power supply.
A phase, which is an arbitrary one of S phase and T phase, and R
First opening / closing means for opening / closing an A-phase input and an A-phase output or a B-phase input and a B-phase output in the B-phase which is another phase out of the phase / S-phase / T-phase; B phase output or B
A second opening / closing means for opening / closing a phase input and an A-phase output;
The first or second opening / closing means is selectively closed according to the determination result of the phase rotation determining means 19 so that the phase rotation is in a direction suitable for the device. The phase rotation judging means 19 comprising the overcurrent judging detecting means 15 and the zero-cross detecting means 16 is arranged at a stage subsequent to the circuit changing means 11. That is, the phase rotation determining means 19 is connected to the three-phase circuit on the opposite side of the power supply of the circuit changing means 11.

FIG. 2 is a block diagram showing a control configuration of a part corresponding to the present invention in the control circuit 17 of the outdoor unit A. In FIG. 2, reference numeral 18 denotes power-on determining means for detecting that the power is turned on, 19 denotes a zero-cross signal obtained by the zero-cross detecting means 16 when the power is turned on, and an overcurrent obtained by the overcurrent determination detecting means 15. Phase rotation determining means for determining the phase rotation direction of the power supply voltage from the determination signal. 20
Denotes operation setting means for setting the operation state of the air conditioner, and 21 denotes operation / stop determination means for judging the operation state of the air conditioner. Reference numeral 22 denotes an open phase detecting means for determining an open phase of the power supply voltage from the zero cross signal and the overcurrent determination signal. Reference numeral 23 denotes a power supply voltage drop detection unit that determines a drop in the power supply voltage based on the overcurrent determination signal. Reference numeral 24 denotes whether the detection is a first detection or a second detection when the reduction in the power supply voltage is detected. And a power supply voltage drop control unit that controls the air conditioner based on the determination result. 25
Is a standby means for stopping the operation of the air conditioner when the detection of the power supply voltage drop is performed for the first time, and preventing the restart for a predetermined time thereafter. Reference numeral 26 denotes abnormal stop means for stopping the operation of the air conditioner when an abnormality occurs, and reference numeral 27 denotes abnormal display means for displaying an abnormal state.

An example of an embodiment of the invention in the air conditioner configured as described above will be described with reference to FIG. FIG. 3 is an example of a circuit that implements the overcurrent determination unit 15 and the zero-cross detection unit 16 according to Embodiment 1 of the present invention. PC1, PC2, and PC3 are photocouplers, and P1 and P2 are microcomputer input ports provided in common arithmetic means including a microcomputer. The signal obtained by the overcurrent determination means 15 is input to the microcomputer input port P1, and the signal obtained by the zero-cross detection means 16 is input to the microcomputer input port P2.

The microcomputer input port P1 is a port to which a signal obtained by the overcurrent determination detecting means 15 is input. When the photocoupler PC1 is not turned on, the voltage level of the microcomputer input port P1 becomes Hi. When the photocoupler PC1 is turned on, a current flows from the collector side of the photocoupler to the emitter side. The voltage level of P1 becomes Lo.

The microcomputer input port P2 is a port to which a signal obtained by the zero-cross detecting means 16 is input. When the photocoupler PC2 and the photocoupler PC3 are not both ON, the voltage level of the microcomputer input port P2 becomes Hi, and when one of the photocoupler PC2 and the photocoupler PC3 is ON, the microcomputer input port P2 is turned on. The voltage level of P2 becomes Lo.

FIG. 4 is a waveform chart showing waveforms of the respective parts.
The power supply voltage input from the three-phase AC power supply 10 has a waveform (a)
, The waveform (e) indicates only the TR inter-phase voltage, and when the voltage Va is the reference voltage at which the photocoupler is turned on, the waveform Va is obtained by the overcurrent determination means 15 input to the microcomputer input port P1. An overcurrent determination signal composed of a half-wave signal between power supply phases has a waveform (f). Similarly, when the power supply voltage has the waveform (a), the zero-cross signal input to the microcomputer input port P2 has the waveform (c).

The waveform (b) is the same overcurrent determination signal as the waveform (f). Comparing the waveform (b) and the waveform (c),
Since the phase of each inter-phase voltage of the three-phase AC power supply is shifted by one-third cycle, it can be seen that the time from the rise of the overcurrent determination signal to the rise of the zero-cross signal is about one-third cycle. .

When the power supply voltages are out of phase, the zero cross signal has a waveform (d). In this case, the time from the rise of the overcurrent determination signal to the rise of the zero-cross signal is about 1/6 cycle. Therefore, it is possible to detect the opposite phase of the power supply voltage by measuring the difference between the rising timings of the waveforms of the overcurrent determination signal and the zero-cross signal and comparing the two.

When the R phase is lost, PC1
Since both PC2s are turned ON only when a voltage of a certain level or more is applied from the T phase to the S phase, the zero cross signal and the overcurrent determination signal have the same waveform. Therefore, the R-phase missing phase can be detected by measuring the waveform shift and comparing the two. Further, in the case of the S phase open phase, the zero cross signal is not detected, and in the case of the T phase open phase, the overcurrent determination signal is not detected, so that the open phase can be detected.

If the voltage waveform during the normal TR phase is waveform (e), the voltage waveform becomes waveform (g) when the power supply voltage is reduced. At this time, since the time during which the voltage value becomes equal to or lower than the reference level becomes longer, the overcurrent determination signal becomes a waveform (h), and the time during which the signal rises becomes longer. Therefore, by measuring the time during which the overcurrent determination signal rises, it is possible to detect a drop in the power supply voltage.

FIG. 5 is a flowchart showing the processing at the time of turning on the power. First, in step 30, the timer t
1 is reset, and in step 31, if the rising of the overcurrent determination signal can be detected by the overcurrent determination detecting means 15, the process proceeds to step 33; otherwise, the process proceeds to step 32. In step 32, the value of the timer t1 is compared with the value of the predetermined time T. The predetermined time T is a period of one cycle of the power supply voltage. If the value of the timer t1 is equal to or less than the predetermined time T, the process returns to step S31. When the value of the timer t1 is larger than the predetermined time T, the process proceeds to Step 38.

At step 33, the timer t1 is reset, and the routine proceeds to step 34. In step 34, if the zero-cross detecting means can detect the rising edge of the zero-cross signal, the process proceeds to step 36; otherwise, the process proceeds to step 35. In step 35, the value of the timer t1 is compared with the value of the predetermined time T / 2. If the value of the timer t1 is equal to or less than the predetermined time T / 2, the process returns to step S34. If the value of the timer t1 is longer than the predetermined time T / 2, the process proceeds to step S38. In step 36, the value of the timer t1 is compared with a predetermined time T / 4. Timer t1
Is larger than T / 4, this process ends.

If the value of the timer t1 is equal to or less than T / 4,
Proceed to step 37. In step 37, after the circuit is changed by the circuit changing means 11, this processing is ended. In step 38, after the operation is prohibited by the abnormal stop means 26, the process proceeds to step 39. In step 39, the abnormality display is performed by the abnormality display means 27, and then the present process is terminated.

FIG. 6 is a flowchart showing a normal process. First, in step 40, a flag F indicating the history of the power supply voltage drop is defined as F = 0, and the process proceeds to step 41. In step 41, the operation state is judged by the operation / stop judgment means 21, and if the compressor is just before starting or is operating, the process proceeds to step 42. If the compressor is not running immediately before starting or during operation, the process ends.

At step 42, the timer t1 is reset, and the routine proceeds to step 43. In step 43, if the rise of the overcurrent determination signal can be detected by the overcurrent determination detection means 15, the process proceeds to step 45; otherwise, the process proceeds to step 44. In step 44, the timer t
The value of 1 and the value of the predetermined time T are compared. The predetermined time T is one cycle of the power supply voltage. If the value of the timer t1 is equal to or less than the predetermined time T, the process returns to step 43. Timer t
If the value of 1 is greater than the predetermined time T, the process proceeds to step 55. In step 45, the timer t1 is reset,
Proceed to step 46.

In step 46, the zero-cross detecting means 1
If the rising edge of the zero-cross signal can be detected by step 6, the process proceeds to step 48;
Proceed to. In step 47, the value of the timer t1 is compared with the value of the predetermined time T / 2. If the value of the timer t1 is equal to or less than the predetermined time T / 2, the process returns to step 46. When the value of the timer t1 is larger than the predetermined time T / 2, the process proceeds to Step 55. At step 48, the value of the timer t1 is substituted for the variable X, and the routine proceeds to step 49.

In step 49, the overcurrent determination detecting means 1
If the fall of the overcurrent determination signal can be detected by step 5, the process proceeds to step 50;
Return to In step 50, the value of the timer t1 is compared with the value of the predetermined time Y. The predetermined time Y is a time from the rising to the falling of the overcurrent determination signal, which is a reference for determining the power supply voltage drop. If the value of the timer t1 is smaller than the predetermined time Y, the process proceeds to step 54. Timer t1
Is equal to or longer than the predetermined time Y, the routine proceeds to step 51.
In step 51, the value of the flag F is determined. Flag F
If = 0, go to step 52. If the flag F = 1, the process proceeds to step 55.

At step 52, the flag F = 1 is set, and the routine proceeds to step 53. In step 53, the operation state of the air conditioner is set to the standby state by the standby unit 25, and the process proceeds to step 41 after a predetermined time has elapsed. In step 54, the value of the variable X is compared with the value of the predetermined time T / 12. If the value of the variable X is equal to or less than the predetermined time T / 12, the process proceeds to step 55. The value of the variable X is a predetermined time T / 1
If it is larger than 2, this process ends.

In step 55, after the operation of the air conditioner is stopped by the abnormal stopping means 26, step 56
Proceed to. In step 56, after the abnormality display means 27 displays an abnormality, the process is terminated.

By operating as described above, the following effects can be obtained. In the control configuration configured as described above, the signals obtained by the existing signal input circuit are used and the signals are processed by the arithmetic unit including the common microcomputer without adding a new circuit. As a result, it is possible to detect a negative or negative power supply voltage drop of the power supply voltage, thereby simplifying the circuit, reducing the number of parts,
Simplification of software and reduction of operation load can be realized.

Further, the detection of the phase loss of the power supply voltage and the detection of the decrease in the power supply voltage are performed only during the operation of the compressor immediately after the start of the compressor. Occurrence of abnormalities can be suppressed.

Further, when the reverse phase of the power supply voltage is detected, the circuit is changed by the circuit changing means 11, and when the power supply voltage drop is detected for the first time, the standby means 25 inhibits the predetermined time. After that, it is determined again that the power supply voltage has dropped, and if the voltage has not dropped, the operation can be restarted, so that a stable operation state can be maintained.

The determination by the phase rotation determining means is performed only once after the power is turned on and after the recovery from the power failure, whereby
When the power supply voltage is out of phase, a problem that occurs when the air conditioner continues to operate can be prevented beforehand, and by performing this determination only once, the operating load of software is reduced. It can be reduced.

Embodiment 2 Another example of the embodiment of the present invention will be described with reference to the flowchart of FIG. FIG. 7 is a flowchart showing the processing at power-on. First, at step 60, the timer t1 is reset, and the routine proceeds to step 61. In step 61,
If the rise of the overcurrent determination signal can be detected by the overcurrent determination detection means 15, the process proceeds to step 63; otherwise, the process proceeds to step 62. In step 62, the value of the timer t1 is compared with the value of the predetermined time T. The predetermined time T is one cycle of the power supply voltage. If the value of the timer t1 is equal to or less than the predetermined time T, the process returns to step 61. When the value of the timer t1 is longer than the predetermined time T, the process proceeds to step 71. In step 63, the timer t1 is reset, and the process proceeds to step 64.

In step 64, the zero-cross detecting means 1
If the rising edge of the zero-cross signal can be detected by step 6, the process proceeds to step 66;
Proceed to. In step 65, the value of the timer t1 is compared with the value of the predetermined time T / 2. If the value of the timer t1 is equal to or less than the predetermined time T / 2, the process returns to Step 64. If the value of the timer t1 is longer than the predetermined time T / 2, the process proceeds to step 71. In step 66, the value of the timer t1 is substituted for the variable X, and the process proceeds to step 67.

In step 67, the overcurrent determination detecting means 1
If the fall of the overcurrent determination signal can be detected by step 5, the process proceeds to step 68;
Return to In step 68, the value of the timer t1 is compared with the value of the predetermined time Y. The predetermined time Y is a time from the rising to the falling of the overcurrent determination signal, which is a reference for determining the power supply voltage drop. If the value of the timer t1 is smaller than the predetermined time Y, the process proceeds to step 69. Timer t1
Is greater than or equal to the predetermined time Y, the routine proceeds to step 71.
In step 69, the value of the variable X is compared with the value of the predetermined time T / 12. If the value of the variable X is equal to or less than the predetermined time T / 12, the process proceeds to step 71. If the value of the variable X is larger than the predetermined time T / 12, the process proceeds to step 70.

In step 70, the value of the timer t1 is compared with a predetermined time T / 4. The value of the timer t1 is T / 4
If it is larger, the process ends. If the value of the timer t1 is equal to or less than T / 4, the process proceeds to step 71. In step 71, after the operation is prohibited by the abnormal stop means 26, the process proceeds to step 72. In step 72, after the abnormal display is performed by the abnormal display means 27, the present process is terminated.

FIG. 8 is a flowchart showing a normal process. First, at step 80, the timer t1 is reset, and the routine proceeds to step 81. In step 81,
If the rise of the overcurrent determination signal can be detected by the overcurrent determination detection means 15, the process proceeds to step 83; otherwise, the process proceeds to step 82. In step 82,
The value of the timer t1 is compared with the value of the predetermined time T. The predetermined time T is a period of one cycle of the power supply voltage. Timer t
If the value of 1 is equal to or less than the predetermined time T, the process returns to step 81. If the value of the timer t1 is larger than the predetermined time T,
Go to step 90. In step 83, the timer t1
Is reset, and the routine proceeds to step 84.

In step 84, the zero-cross detecting means 1
If the rising edge of the zero-cross signal can be detected by step 6, the process proceeds to step 86;
Proceed to. In step 85, the value of the timer t1 is compared with the value of the predetermined time T / 2. If the value of the timer t1 is equal to or less than the predetermined time T / 2, the process returns to step S84. If the value of the timer t1 is larger than the predetermined time T / 2, the process proceeds to step 90. At step 86, the value of the timer t1 is substituted for the variable X, and the routine proceeds to step 87.

In step 87, the overcurrent determination detecting means 1
If the fall of the overcurrent determination signal can be detected by step 5, the process proceeds to step 88, and if not, the process proceeds to step 87.
Return to In step 88, the value of the timer t1 is compared with the value of the predetermined time Y. The predetermined time Y is a time from the rising to the falling of the overcurrent determination signal, which is a reference for determining the power supply voltage drop. If the value of the timer t1 is smaller than the predetermined time Y, the process proceeds to step 89. Timer t1
Is greater than or equal to the predetermined time Y, the routine proceeds to step 90.
In step 89, the value of the variable X is compared with the value of the predetermined time T / 12. If the value of the variable X is equal to or less than the predetermined time T / 12, the process proceeds to step 90. When the value of the variable X is a predetermined time T
If it is larger than / 12, this processing is terminated.

In step 90, after the operation is stopped by the abnormal stopping means 26, the routine proceeds to step 91. In step 91, after the abnormal display is performed by the abnormal display means 27, the present process is terminated.

By operating as described above, the following effects can be obtained. In the control configuration configured as described above, the software simplification can be realized by always performing the power supply voltage open phase determination and the power supply voltage drop detection when the power is turned on.

[0060]

Since the present invention is configured as described above, it has the following effects. According to the first aspect of the invention, by comparing the zero-cross signal and the half-wave signal, the abnormality of the power supply including the negative phase and the open phase of the power supply is detected and the protection operation is performed to detect the negative phase and the open phase of the power supply voltage. Can be obtained accurately.

According to the second aspect of the present invention, the zero-cross signal and the half-wave signal are processed by the common arithmetic means, thereby detecting an abnormality of the power supply including a reverse phase and an open phase of the power supply, and performing the protection operation. Thus, it is possible to obtain a protection device for an air conditioner that can accurately detect a reverse phase and an open phase of the power supply voltage.

According to the third aspect of the present invention, the zero-cross signal and the half-wave signal are detected using different power supply phases, so that these signals can be detected for the purpose of detecting the reverse phase / open phase of the power supply voltage and detecting the power supply voltage drop. It is possible to obtain a protection device for an air conditioner that can be used for a vehicle.

According to the fourth aspect, when the opposite phase of the power supply voltage is detected, the operation of the air conditioner is stopped and an abnormal state is displayed, thereby causing a case where the air conditioner continues to operate as it is. Problems can be prevented beforehand, and a highly reliable air conditioner can be obtained.

According to the fifth aspect, when the reverse phase of the power supply voltage is detected, the air conditioner continues to operate as it is by changing the phase rotation direction of the power supply voltage by selecting switching means for the circuit. In this case, it is possible to prevent a problem that may occur in the event that the operation is performed, and to maintain a stable operation state.

According to the sixth aspect, the determination by the phase rotation determining means is performed only once after the power is turned on and after the recovery from the power failure, so that when the power supply voltage is in the opposite phase, the air conditioner operates as it is. Can be prevented beforehand, and by making this determination only once, the operation load of software can be reduced.

According to the seventh aspect, when an open phase of the power supply voltage is detected, the operation of the air conditioner is stopped and an abnormal state is displayed, thereby causing a case where the air conditioner continues to operate as it is. Problems can be prevented beforehand, and a highly reliable air conditioner can be obtained.

According to the eighth aspect, simplification of the software can be realized by always performing the phase loss determination of the phase loss detecting means after the power is turned on.

According to the ninth aspect of the present invention, the phase loss determination of the phase loss detecting means is always performed during the operation of the compressor immediately after the start of the compressor. It is possible to limit the occurrence of unnecessary abnormalities.

According to the tenth aspect, when the power supply voltage drop detecting means detects the power supply voltage drop, the operation of the air conditioner is stopped and an abnormal state is displayed, so that the air conditioner continues to operate as it is. In this case, it is possible to prevent a problem that may occur in the case where the air conditioner is used, and to obtain a highly reliable air conditioner.

According to the eleventh aspect, when the power supply voltage detecting means detects the power supply voltage drop, the operation of the air conditioner is temporarily stopped, and after restarting for a predetermined time, the power supply voltage drop detecting means is turned off. If the detection is normal, by restarting the air conditioner, it is possible to prevent a problem occurring when the air conditioner continues to operate as it is, and to maintain a stable operation state. Further, after the restart is prevented for a predetermined time, when the power supply voltage is in a low state, the air conditioner is stopped and an abnormal state is displayed, thereby causing a case where the air conditioner continues to operate as it is. Problems can be prevented beforehand, and a highly reliable air conditioner can be obtained.

According to the twelfth aspect, the simplification of the software can be realized by always detecting the power supply voltage drop after the power is turned on.

According to the thirteenth aspect, the detection of the power supply voltage drop is always performed during the operation of the compressor immediately after the start of the compressor, so that the protection detection is limited to a period in which the protection is really required. Unnecessary abnormalities can be suppressed.

[Brief description of the drawings]

FIG. 1 is a configuration diagram illustrating an air conditioner and a control configuration thereof according to Embodiment 1 of the present invention.

FIG. 2 is a block diagram showing a control configuration of a part corresponding to the present invention in a control circuit 17 of an outdoor unit A according to Embodiment 1 of the present invention.

FIG. 3 is a diagram illustrating an example of a circuit that implements an overcurrent determination unit 15 and a zero-cross detection unit 16 according to the first embodiment of the present invention.

FIG. 4 is a waveform chart according to the embodiment of the present invention.

FIG. 5 is a diagram showing a flowchart showing processing at power-on according to the first embodiment of the present invention.

FIG. 6 is a diagram showing a flowchart illustrating a normal process according to the first embodiment of the present invention;

FIG. 7 is a flowchart showing processing at power-on according to Embodiment 2 of the present invention;

FIG. 8 is a diagram showing a flowchart showing a normal process according to the second embodiment of the present invention.

FIG. 9 is a configuration diagram showing a conventional general air conditioner and its control device.

FIG. 10 is a diagram illustrating an example of a circuit that implements an overcurrent determination detection unit in a conventional general air conditioner.

FIG. 11 is a diagram illustrating an example of a circuit that realizes a zero-crossing detection unit 16 in a conventional general air conditioner.

FIG. 12 is a circuit diagram of a circuit realizing the zero-cross detecting means 16, the first anti-phase / open-phase determination signal detecting means 28, and the second anti-phase / open phase determining signal detecting means 29 in a conventional general air conditioner. It is a figure showing an example.

FIG. 13 is a waveform diagram in a conventional general air conditioner.

[Explanation of symbols]

1 compressor, 2 outdoor unit heat exchanger, 3 outdoor unit fan, 4 fan motor, 5 compressor motor, 6 throttle device, 7 indoor unit side heat exchanger, 8 liquid side refrigerant piping, 9
Gas-side refrigerant piping, 10 three-phase AC power supply, 11 circuit changing means, 12 overcurrent judging means, 13 circuit opening / closing means, 1
4 phase control means, 15 overcurrent determination detection means comprising half-wave signal detection means, 16 zero-cross detection means, 17
Control circuit of outdoor unit A, 18 power-on determination means, 19
Phase rotation determination means, 20 operation setting means, 21 operation / stop determination means, 22 phase loss determination means, 23 power supply voltage drop determination means, 24 power supply voltage reduction control means, 25 standby means, 26 abnormal stop means, 27 abnormality display means , 2
8 First anti-phase / open phase determination signal detection means, 29 second anti-phase / open phase determination signal detection means.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI H02H 7/00 H02H 7/00 J

Claims (13)

[Claims] 1. An air conditioner operating with a three-phase power supply, comprising: a zero-cross detection means for detecting a voltage zero-cross point of the power supply; and a half-wave signal detection means for detecting a half-wave signal between power supply phases. Detecting an abnormality in the power supply including a reverse phase / open phase of the power supply by comparing the signal output of the zero-cross detection means and the signal output of the half-wave signal detection means,
A protection device for an air conditioner, which performs a protection operation. 2. An air conditioner operating with a three-phase power supply, comprising: a zero-crossing detecting means for detecting a voltage zero-crossing point of the power supply; and a half-wave signal detecting means for detecting a half-wave signal between power supply phases. The signal output of the zero-crossing detection means and the signal output of the half-wave signal detection means,
A protection device for an air conditioner, characterized in that an abnormality of a power supply including a reverse phase and an open phase of the power supply is detected by performing processing by a common arithmetic unit, and a protection operation is performed. 3. An air conditioner operating with a three-phase power supply, comprising: a zero cross detection means for detecting a voltage zero cross point of the power supply; and a protection means for stopping the air conditioner in response to an abnormal state, wherein the protection is provided. A protection device for an air conditioner, wherein a detection input of the means is obtained based on the presence / absence of a half-wave signal of a power supply, and the zero-cross signal and the half-wave signal are detected using different power phases. 4. A lag time detecting means for detecting a lag time between rising timings of a zero-cross signal and a half-wave signal,
Phase rotation determining means for determining the phase rotation direction of the power supply voltage based on the length of the shift time, and abnormal stopping means for stopping the operation of the air conditioner when the phase rotation does not match the rotation direction of the device in the air conditioner The protection device for an air conditioner according to claim 3, further comprising: an abnormality display unit that displays an abnormal state. 5. A first opening / closing means for opening and closing an A-phase input, an A-phase output, a B-phase input and a B-phase output, and an A-phase input and a B-phase output.
A second opening / closing means for opening / closing the B-phase input and the A-phase output;
By disposing the phase rotation determining means at a stage subsequent to the first and second opening / closing means, the first rotation is determined in accordance with the determination result of the phase rotation determining means so that the phase rotation is in a direction suitable for the device.
4. The protection device for an air conditioner according to claim 3, further comprising a change unit that selectively closes the second opening / closing unit. 5. 6. The protection device for an air conditioner according to claim 4, wherein the determination by the phase rotation determination means is performed only once after the power is turned on and after the power is restored. 7. A zero-cross signal and a half-wave signal, when the zero-cross signal is not input for more than 期間 period of the power supply frequency, when a half-wave signal is not input for more than the power supply frequency period, or a zero-cross signal and a half-wave signal When the rises of the power supply coincide, the power supply has an open phase detecting means for detecting an open phase of the power supply, and when the open phase is detected by the open phase detecting means, an abnormal stop means for stopping the operation of the air conditioner, A protection device for an air conditioner, comprising an abnormality display means for displaying an abnormal state. 8. The protection device for an air conditioner according to claim 7, wherein the determination of the phase loss of the phase loss detecting means is always performed when the power is turned on. 9. The protection device for an air conditioner according to claim 7, wherein the determination of the phase loss by the phase loss detecting means is performed at all times during the operation of the compressor immediately after the start of the compressor. 10. A circuit for reacting a half-wave signal to a half-wave rectified voltage of a power supply at a predetermined voltage value or more, wherein a half-wave signal width is zero-crossed by a signal width of the half-wave signal and a zero-cross signal period. It has a power supply voltage drop detection means for detecting a power supply voltage drop when the ratio becomes equal to or more than a predetermined ratio with respect to the signal cycle. Abnormal stopping means to
The protection device for an air conditioner according to claim 3, further comprising abnormality display means for displaying an abnormal state. 11. When the power supply voltage drop detecting means detects a power supply voltage drop, the operation of the air conditioner is temporarily stopped,
Thereafter, standby means for preventing a restart for a predetermined time, restart means for restarting the air conditioner if the detection of the power supply voltage drop detection means is normal after a predetermined time has elapsed, and power supply voltage reduction state even after a predetermined time has elapsed. 4. The protection device for an air conditioner according to claim 3, further comprising: an abnormal stop unit that stops the air conditioner when there is an error, and an abnormal display unit that displays the abnormal state. 12. The protection device for an air conditioner according to claim 10, wherein the detection of the power supply voltage drop is always performed after the power is turned on. 13. The method according to claim 1, wherein the detection of the power supply voltage drop is always performed during the operation of the compressor immediately after the start of the compressor.
The protection device for an air conditioner according to claim 10 or 11.