JP2931654B2 - Air conditioner - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a split-type air conditioner including an outdoor unit and an indoor unit.

(Prior art) As a split type air conditioner, an outdoor unit is connected to an AC power supply, and an indoor unit is connected to the outdoor unit via a power line and a serial signal line.
In some cases, information transmission between an outdoor unit and an indoor unit is performed by a serial signal synchronized with a power supply voltage.

 FIG. 3 shows a control circuit of such an air conditioner.

The three-phase AC power source 1 outdoor unit 2 is continued, the power supply line (connecting wire) to the outdoor unit 2 AC _1, AC _2, and the serial signal line indoor unit 3 via the (connecting wire) SL is connected.

In the outdoor unit 2, the power supply terminal plate 4 is connected to the power supply 1. The terminal plate 4 has terminals R, S, and T corresponding to each phase of the power supply 1.

A drive motor (hereinafter referred to as a compressor motor) 5 of the compressor is connected to terminals R, S, and T of the terminal plate 4 via a contact 9a of an electromagnetic contactor 9 described later.

The outdoor control unit 7 is connected to the terminals R and S of the terminal plate 4 via the step-down transformer 6, and
Terminals are connected.

The outdoor control unit 7 includes a microcomputer and its peripheral circuits, and executes control over the entire outdoor unit 2, for example, energization control of the compressor motor 5 by the electromagnetic contactor 9 while transmitting and receiving information to and from the indoor unit 3. It is.

The direct-current voltage Vd through a series circuit of an input port P ₁ to the resistor 11, 12 of the outdoor control unit 7 is applied, the interconnection point is synchronizing signal generating circuit of a resistor 11 and 12 (photo-coupler) 13 phototransistor Grounded through the collector and emitter of 13b.

A resistor 14 and a forward diode are connected to the terminal R of the terminal plate 4.
The cathode of the light emitting diode 13a of the synchronizing signal generation circuit 13 is connected via the reference numeral 15, and the anode of the light emitting diode 13a is connected to the terminal S of the terminal plate 4.

The synchronizing signal generation circuit 13 includes a light emitting diode 13a and a phototransistor 13b, and the light emitting diode 13a on the primary side turns on the phototransistor 13b on the secondary side, thereby synchronizing with the power supply voltage (R, S line voltage). A power supply voltage synchronizing signal is issued.

A DC voltage Vd is applied to the input port P ₂ of the outdoor control unit 7 via a series circuit of resistors 16 and 17, and an interconnection point of the resistors 16 and 17 is connected to a collector of a phototransistor 18 b of a receiving circuit (photocoupler) 18. -Grounded between emitters.

The light emitting diode 18a of the receiving circuit 18 is connected to the terminal of the terminal plate 8.
And the anode of the light emitting diode 18a is connected to the terminal of the terminal plate 8 via the resistor 19 and the forward diode 20.

The receiving circuit 18 includes a light emitting diode 18a and a phototransistor 18b, and the light emitting diode 18a on the primary side turns on the phototransistor 18b on the secondary side.

DC voltage Vd is applied to the output port P ₃ of the outdoor control unit 7 via a series circuit of resistors 21 and 22, between the base and emitter of the PNP transistor 23 is connected to the resistor 22.

The collector of the transistor 23 is connected to the cathode of the light emitting diode 24a of the transmitting circuit (photo switch) 24, and the anode of the light emitting diode 24a is grounded via the resistor 25.

A resistor 26 and a forward diode are connected to the terminals of the terminal plate 8.
The cathode of the photodiode 24b of the transmission circuit 24 is connected via the 27, and the anode of the photodiode 24b is connected to the terminal of the terminal plate 8.

The transmission circuit 24 includes a light emitting diode 24a and a photodiode 24b.
The secondary-side photodiode 24b conducts.

Furthermore, the DC voltage Vd is applied through a series circuit of resistors 28 and 29 to the input port P ₄ of the outdoor control unit 7, the resistance 28,2
Nine interconnection points are grounded via the collector and emitter of the phototransistor 30c of the abnormality detection circuit (photocoupler) 30.

The light emitting diodes 30a and 30b of the abnormality detection circuit 30 are connected between the terminals R and S of the terminal plate 4 via a series circuit of a normally closed protective contact 31 and a resistor 32.

The abnormality detection circuit 30 includes light emitting diodes 30a and 30b and a phototransistor 30c. The light emitting diodes 30a and 30b on the primary side emit light, and the phototransistor 3 on the secondary side emits light.
0c turns on.

The protection contact 31 operates (turns off) by detecting an abnormal decrease in the low-pressure side pressure of the refrigeration cycle as an abnormality of the outdoor unit 2.

 The configuration of the outdoor unit 2 has been described so far.

The terminal of the terminal plate 8 of the indoor unit 3 is connected to the terminal of the terminal plate 8 of the outdoor unit 2 via the power lines AC ₁ and AC _2.
Terminal board 33 via the serial signal line SL
Terminals are connected.

An outdoor control unit 35 is connected to terminals of the terminal plate 33 via a step-down transformer 34.

The outdoor control unit 35 includes a microcomputer and its peripheral circuits, and performs overall control of the indoor unit 3 while transmitting and receiving information to and from the outdoor unit 2.

The direct-current voltage Vd through a series circuit of an input port P ₁ to the resistor 36 and 37 of the indoor control unit 35 is applied, the phototransistor 38b of the interconnection points synchronizing signal generating circuit (Fotokara) 38 of the resistance 36 and 37 Is grounded through the collector and the emitter of

The cathode of the light emitting diode 38a of the synchronization signal generating circuit 38 is connected to the terminal of the terminal plate 33, and the light emitting diode 38a
Is connected to the terminal of the terminal plate 33 via the resistor 39 and the forward diode 40.

The synchronizing signal generating circuit 38 includes a light emitting diode 38a and a phototransistor 38b, and the light emitting diode 38a on the primary side turns on the phototransistor 38b on the secondary side to synchronize with the power supply voltage (R, S line voltage). A power supply voltage synchronizing signal is issued.

A DC voltage Vd is applied to the input port P ₂ of the indoor control unit 35 via a series circuit of resistors 41 and 42, and an interconnection point of the resistors 41 and 42 is connected to a collector of a phototransistor 43 b of a receiving circuit (photocoupler) 43. -Grounded between emitters.

The light emitting diode 43a of the receiving circuit 43 is connected to the terminal of the terminal plate 33.
And the anode of the light emitting diode 43a is connected to the terminal of the terminal plate 33 via the resistor 44 and the forward diode 45.

The receiving circuit 43 includes a light emitting diode 43a and a phototransistor 43b, and the light emitting diode 43a on the primary side turns on the phototransistor 43b on the secondary side.

DC voltage Vd is applied to the output port P ₃ of the indoor control unit 35 through a series circuit of resistors 46 and 47, between the base and emitter of the PNP transistor 48 is connected to the resistor 47.

The collector of the transistor 48 is connected to the cathode of the light emitting diode 49a of the transmitting circuit (photo switch) 49, and the anode of the light emitting diode 49a is grounded via the resistor 50.

The cathode of the photodiode b of the transmission circuit 49 is connected to the terminal of the terminal plate 33 via the resistor 51, and the anode of the photodiode 49b is connected to the terminal of the terminal plate 33.

The transmission circuit 49 includes a light emitting diode 49a and a photodiode 49b.
The secondary-side photodiode 49b conducts.

 The operation will be described.

When the power supply 1 is turned on, a voltage between R and S lines, a voltage between S and T lines, and a voltage between T and R lines are generated as shown in FIG.

At this time, the synchronization signal generating circuit 13 on the outdoor unit 2 side
Turns on when the voltage between the R and S lines is at a positive level, and turns off when the voltage is at a negative level. By turning on and off, as shown in FIG. 4, a low-level "L" power supply voltage synchronizing signal is generated when the voltage between the R and S lines is a positive level, and a "H" level "H" is generated when the voltage is a negative level. , it is input to the input port P ₁ of the outdoor control unit 7.

The synchronization signal generating circuit 38 on the indoor unit 3 side includes R,
Turns off when the S line voltage is at a positive level and turns on when the voltage is at a negative level. By this on / off, a power supply voltage synchronizing signal of a high level “H” when the voltage between the R and S lines is a positive level and a low level “L” when the voltage is a negative level is generated. is input to the P _1.

The indoor control unit 35 creates a transmission information signal in which one bit is synchronized with one cycle of the power supply voltage synchronization signal, and turns on and off the transistor 8 according to the transmission information signal, thereby turning on and off the transmission circuit 49. Then, a serial signal is generated based on the presence or absence of a half cycle signal (positive level) of the voltage between the R and S lines.

The serial signal thus created is connected to the power line AC ₁
Is transmitted to the outdoor unit 2 via the serial signal line SL, and is received by the receiving circuit 18. The received signal is taken into the input port P ₂ of the outdoor control unit 7.

The outdoor control unit 7 determines the content of the received serial signal, that is, transmission information, in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 13, as shown in the flowchart of FIG.
Execute various controls.

For example, by energizing the electromagnetic contactor 9, the contact
9a is turned on, and the compressor motor 5 is connected to the power supply 1. Thereby, the compressor motor 5 operates and the operation of the compressor is turned on.

When the electromagnetic contactor 9 is deenergized, the contact 9a is turned off, and the compressor motor 5 is cut off from the power supply 1. Thereby, the operation of the compressor motor 5 stops, and the operation of the compressor turns off.

Note that there is also control of an outdoor fan, a four-way valve, and the like by a relay (not shown).

Also, the outdoor control unit 7 creates a transmission information signal in which one bit is synchronized with one cycle of the power supply voltage synchronization signal, turns on / off the transistor 23 according to the transmission information signal, and thereby turns on the transmission circuit 24. , Turn off, and create a serial signal based on the presence or absence of a half cycle signal (negative level) of the voltage between the R and S lines.

The serial signal thus created is connected to the power line AC ₁
Is transmitted to the indoor unit 3 via the serial signal line SL, and is received by the receiving circuit 43. The received signal is taken into the input port P ₂ of the indoor control unit 35.

The indoor control unit 35 determines the content of the received serial signal, that is, transmission information, in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 38, and executes various controls.

On the other hand, in the outdoor unit 2, when the low-pressure side pressure of the refrigeration cycle abnormally decreases, the protection contact 31 operates (opens).

When the protection contact 31 operates, the abnormality detection circuit 30 turns off,
A high-level “H” signal is input to the input port P ₄ of the outdoor control unit 7.

At this time, the outdoor control unit 7 recognizes that the low-pressure side pressure of the refrigeration cycle has abnormally dropped, deactivates the electromagnetic contactor 9, stops the operation of the compressor motor 5, and stops the operation of the compressor. .

Thereafter, the protective contact 31 return back to normal low pressure side pressure (closed), the abnormality detection circuit 30 is turned on, the input signal to the input port P ₄ of the outdoor control unit 7 goes low "L" .
Then, the outdoor control unit 7 urges the electromagnetic contactor 9 to operate the compressor motor 5, and restarts the operation of the compressor.

(Problems to be Solved by the Invention) By the way, in the above, the protection contact 31 and the abnormality detection circuit 30 are used for the abnormality detection in the outdoor unit 2, but the use of such a dedicated circuit complicates the control circuit. It is a major cause of cost increase and cost increase.

The present invention has been made in view of the above circumstances. It is an object of the present invention to accurately detect an abnormality in an outdoor unit without requiring an abnormality detection circuit, thereby simplifying a control circuit and reducing costs. It is to provide an air conditioner.

The present invention relates to an air conditioner including an outdoor unit connected to an AC power supply and an indoor unit connected to the outdoor unit via a power supply line and a serial signal line. , Provided in the indoor unit, generates a serial signal for information transmission in synchronization with a power supply voltage, transmits the serial signal to the outdoor unit, and synchronizes the content of the serial signal received from the outdoor unit with the power supply voltage. A normally closed protective contact that operates in the event of an abnormality in the outdoor unit; and a power supply voltage synchronization signal provided in the outdoor unit and taken in via the protective contact and synchronized with the power supply voltage. A synchronizing signal generation circuit that emits a power supply voltage, and a power supply voltage synchronizing signal generated from the synchronizing signal generation circuit. Means for determining the content of the serial signal received from the indoor unit in synchronization with the power supply voltage synchronization signal, and transmitting information to the indoor unit by a serial signal synchronized with the power supply voltage synchronization signal; When the power supply voltage synchronization signal is not issued from the synchronization signal generation circuit provided in the outdoor unit, a protection operation for abnormality is performed, and a serial for information transmission is performed in synchronization with the serial signal received from the indoor unit. Means for generating a signal and transmitting the serial signal to the indoor unit.

(Operation) If there is no abnormality in the outdoor unit, a power supply voltage synchronization signal is issued from the synchronization signal generation circuit. In the outdoor unit,
A serial signal for information transmission is created in synchronization with the power supply voltage synchronization signal and transmitted to the indoor unit.

When an abnormality occurs in the outdoor unit, the power supply voltage synchronization signal is no longer generated from the synchronization signal generation circuit, and the outdoor unit detects the occurrence of the abnormality and performs a protection operation. At this time,
The outdoor unit creates a serial signal for information transmission in synchronization with the serial signal received from the indoor unit, and transmits the serial signal to the indoor unit.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the drawings, the same parts as those in FIG. 3 are denoted by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 1, in the outdoor unit 2, a protective contact 31 is inserted into and connected to an energizing line extending from the terminal plate 4 to the synchronization signal generating circuit 13. That is, the configuration is such that the power supply voltage is taken into the synchronization signal generation circuit 13 via the protection contact 31.

With the movement of the protection contact 31, the conventional abnormality detection circuit 30
And its peripheral circuits are removed.

 The outdoor control unit 7 has the following functional means.

Means for determining the content of the serial signal received from the indoor unit 3 in synchronization with the power supply voltage synchronization signal when the power supply voltage synchronization signal is issued from the synchronization signal generation circuit 13.

Means for performing operation control in accordance with the content of the determination.

Means for transmitting information to the indoor unit 3 by a serial signal synchronized with the power supply voltage synchronization signal.

Means for executing a protection operation against abnormality (abnormal drop in low-pressure side pressure) when the power supply voltage synchronization signal is not issued from the synchronization signal generation circuit 13.

Means for generating a serial signal for information transmission (for anomaly notification) in synchronization with the serial signal received from the indoor unit and transmitting the serial signal to the indoor unit when the protection operation is performed.

 The indoor control unit 35 has the following functional means.

Means for generating a serial signal for information transmission in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 38 and transmitting the serial signal to the outdoor unit 2.

Means for determining the content of the serial signal received from the outdoor unit 2 in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 38.

Means for executing operation control in accordance with the above-mentioned discrimination contents and displaying the contents of the discrimination on a display unit (not shown).

Next, the operation of the above configuration will be described with reference to FIG.

When the power supply 1 is turned on, the voltage between the R and S lines, the voltage between the S and T lines,
An R line voltage is generated.

At this time, if the low-pressure side pressure of the refrigeration cycle is normal, the voltage between the R and S lines enters the synchronization signal generation circuit 13, and the synchronization signal generation circuit 13 issues a power supply voltage synchronization signal.

In the indoor unit 3, the voltage between the R and S lines enters the synchronization signal generation circuit 38, and the synchronization signal generation circuit 38 issues a power supply voltage synchronization signal.

The indoor control unit 35 generates a transmission information signal in which one bit is synchronized with one cycle of the power supply voltage synchronization signal based on load information corresponding to a difference between the indoor temperature and the set indoor temperature, and responds to the transmission information signal. Then, the transistor 48 is turned on and off, whereby the transmission circuit 49 is turned on and off, and a serial signal is generated based on the presence or absence of a half cycle signal (positive level) of the voltage between the R and S lines.

The serial signal thus created is connected to the power line AC ₁
Is transmitted to the outdoor unit 2 via the serial signal line SL, and is received by the receiving circuit 18.

The outdoor control unit 7 determines the content of the received serial signal, that is, transmission information, in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 13 and performs various controls.

For example, by energizing the electromagnetic contactor 9, the contact
9a is turned on, and the compressor motor 5 is connected to the power supply 1. Thereby, the compressor motor 5 operates and the operation of the compressor is turned on.

When the electromagnetic contactor 9 is deenergized, the contact 9a is turned off, and the compressor motor 5 is cut off from the power supply 1. Thereby, the operation of the compressor motor 5 stops, and the operation of the compressor turns off.

Note that there is also control of an outdoor fan, a four-way valve, and the like by a relay (not shown).

Also, the outdoor control unit 7 creates a transmission information signal in which one bit is synchronized with one cycle of the power supply voltage synchronization signal, turns on / off the transistor 23 according to the transmission information signal, and thereby turns on the transmission circuit 24. , Turn off, and create a serial signal based on the presence or absence of a half cycle signal (negative level) of the voltage between the R and S lines.

The serial signal thus created is connected to the power line AC ₁
Is transmitted to the indoor unit 3 via the serial signal line SL, and is received by the receiving circuit 43.

The indoor control unit 35 determines the content of the received serial signal, that is, transmission information, in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 38, and executes various controls.

On the other hand, in the outdoor unit 2, when an abnormal decrease occurs in the low-pressure side pressure of the refrigeration cycle, the protection contact 31 operates (opens).

When the protection contact 31 operates, the power supply to the synchronization signal generation circuit 13 is cut off, and the power supply voltage synchronization signal is not generated.

At this time, the outdoor control unit 7 elapses the time when there is no input of the power supply voltage synchronization signal by the internal timer, and when the elapse of time reaches a certain value, determines that the low pressure side pressure of the refrigeration cycle is abnormal, and performs the protection operation. Execute.

That is, the operation of the compressor motor 5 is stopped by deenergizing the electromagnetic contactor 9, and the operation of the compressor is stopped.

At the time of execution of this protection operation, the outdoor control unit 7 creates a serial signal for abnormality notification in synchronization with the serial signal received from the indoor unit 3 because there is no input of the power supply voltage synchronization signal, and outputs the serial signal to the indoor. Transmit to unit 3.

The indoor control unit 35 determines the content of the received serial signal, that is, abnormal data, in synchronization with the power supply voltage synchronization signal of the synchronization signal generation circuit 38, and displays the determination result on the display unit.

Thereafter, when the low-pressure side pressure returns to normal and the protection contact 31 returns (closes), the power supply to the synchronization signal generation circuit 13 is restarted, and the power supply voltage synchronization signal is generated.

When the input of the power supply voltage synchronization signal resumes, the outdoor control unit 7 determines that the low-pressure side pressure of the refrigeration cycle has returned to normal, and cancels the protection operation. That is, the electromagnetic contactor 9 is energized to operate the compressor motor 5, and the operation of the compressor is restarted.

As described above, the configuration is such that the presence / absence of an abnormality is determined based on the presence / absence of the power supply voltage synchronizing signal. Therefore, an abnormality in the outdoor unit 3 can be accurately detected without requiring a dedicated circuit such as a conventional abnormality detection circuit. The control circuit can be simplified and the cost can be reduced.

In addition, when there is no power supply voltage synchronizing signal, the transmission of the serial signal to the indoor unit 3 is continued while synchronizing with the serial signal from the indoor unit 3, so that it is possible to determine the reason for the stoppage of the operation on the indoor side. And it can be grasped accurately, and sufficient reliability is secured.

Also, in normal (normal) time, the serial signal is transmitted from the outdoor unit 2 to the indoor unit 3 in synchronization with the power supply voltage. Therefore, at the time of maintenance service, a command is issued from the outdoor unit 2 to turn on the indoor unit. Such operations can be performed, work efficiency can be improved, and the burden on maintenance personnel can be reduced.

In the above-described embodiment, an example of the abnormality in the outdoor unit 2 is described as an abnormal decrease in the low-pressure side pressure. However, various abnormalities such as an abnormal increase in the high-pressure side pressure may be considered.

[Effects of the Invention] As described above, according to the present invention, the indoor unit 3
A means for generating a serial signal for information transmission in synchronization with the power supply voltage, transmitting the serial signal to the outdoor unit, and determining the content of the serial signal received from the outdoor unit in synchronization with the power supply voltage; A normally closed protection contact that operates when an abnormality occurs in the outdoor unit, and a synchronization signal generation circuit that is provided in the outdoor unit, takes in the power supply voltage via the protection contact, and issues a power supply voltage synchronization signal synchronized with the power supply voltage, When the power supply voltage synchronization signal is provided from the synchronization signal generation circuit provided in the outdoor unit,
Means for determining the content of the serial signal received from the indoor unit in synchronization with the power supply voltage synchronization signal, and transmitting information to the indoor unit by a serial signal synchronized with the power supply voltage synchronization signal, provided in the outdoor unit; When the power supply voltage synchronizing signal is not issued from the synchronizing signal generation circuit, a protection operation against an abnormality is performed, and a serial signal for information transmission is created in synchronization with the serial signal received from the indoor unit, and the serial signal is converted to an indoor state. With means for transmitting to the unit, it is possible to accurately catch the abnormality in the outdoor unit without the need for an abnormality detection circuit,
An air conditioner capable of simplifying a control circuit and reducing costs can be provided.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a control circuit according to an embodiment of the present invention, FIG. 2 is a flowchart for explaining the operation of the embodiment, and FIG. 3 is a configuration of a control circuit of a conventional air conditioner. FIG. 4 is a waveform diagram showing a relationship between a power supply voltage and a power supply voltage synchronizing signal in an embodiment of the present invention and a conventional air conditioner, and FIG. 5 is a view for explaining the operation of the conventional air conditioner. It is a flowchart of FIG. 1 ... three-phase AC power supply, 2 ... outdoor unit, 3 ... indoor unit, 7 ... outdoor control unit, 13 ... synchronization signal generation circuit, 18 ... reception circuit, 24 ... transmission circuit, 31 ... Protective contact, 35 ... Indoor control unit, 38 ... Synchronous signal generation circuit, 43 ...
... Reception circuit, 49 ... Transmission circuit.

Claims (1)

(57) [Claims] 1. An air conditioner comprising an outdoor unit connected to an AC power supply and an indoor unit connected to the outdoor unit via a power supply line and a serial signal line, wherein the air conditioner is provided in the indoor unit and synchronizes with the power supply voltage. Means for generating a serial signal for information transmission and transmitting the serial signal to the outdoor unit, and determining the content of the serial signal received from the outdoor unit in synchronization with a power supply voltage, and an abnormality in the outdoor unit. A normally-closed protective contact that operates at the time, and is provided in the outdoor unit,
A synchronization signal generation circuit that takes in a power supply voltage via the protection contact and issues a power supply voltage synchronization signal synchronized with the power supply voltage;
When the power supply voltage synchronization signal is output from the synchronization signal generation circuit, the content of the serial signal received from the indoor unit is determined in synchronization with the power supply voltage synchronization signal, and the power supply voltage synchronization is determined. Means for transmitting information to the indoor unit by a serial signal synchronized with a signal; and a means provided in the outdoor unit for executing a protection operation against abnormality when a power supply voltage synchronization signal is not issued from the synchronization signal generation circuit. Means for generating a serial signal for transmitting information in synchronization with the serial signal received from the indoor unit and transmitting the serial signal to the indoor unit.