JPH09282002A - Master/slave-type controller and controller for refrigeration cycle device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the development load and the operation load of control software, to detect the abnormal state of a controller in an early stage and to restore a system to a normal operation in the early stage. SOLUTION: The controller is divided into the microcomputer 11 of a host control function and the microcomputer 12 of a slave control function. The operation states of the respective microcomputers 11 and 12 are periodically transmitted between the microcomputers by a serial communication means 13. When the host microcomputer 11 detects communication impossibility with the slave microcomputer 12, the host microcomputer 12 compulsorily resets the slave microcomputer 12 by a compulsory resetting means 14. Thus, an operation state as the whole controller can be matched and the stable operation state can be kept.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device for controlling an air conditioner, a refrigeration cycle device such as a refrigerator, and a control device for a refrigeration cycle device, and more particularly to a master device.
The present invention relates to a slave type control device and a control device for a refrigeration cycle device.

[0002]

2. Description of the Related Art FIG. 8 shows a conventional general air conditioner (for example, product model PUY-J2 manufactured by Mitsubishi Electric Corporation).
80M-A) and its control device.

The separate type air conditioner has an outdoor unit A and an indoor unit B separately. Compressor 1 for outdoor unit A
And an outdoor unit side heat exchanger 2, an indoor unit B is provided with a throttle device 3 and an indoor unit side heat exchanger 4, and these are connected to a liquid side refrigerant pipe 5, a gas side refrigerant pipe 6 and the like. By doing so, a refrigeration cycle using a circulation type refrigerant circuit is configured.

This air conditioner is provided with an outdoor unit controller 150, an indoor unit controller 8 and a remote controller 9, and transmits information between them by a transmission line 10.

The outdoor unit controller 150 is mainly composed of a control microcomputer 151 (“microcomputer” is an abbreviation for a microcomputer, and the same applies hereinafter), and the control microcomputer 151 operates to detect its own operating state. State detecting means 153 and inverter 26 for driving the compressor
And an inverter operation abnormality detection means 154 for detecting an operation abnormality of the inverter 26 are connected.

In the conventional air conditioner control device as described above, the operation control of the refrigerant circuit, the control of the inverter 26,
The control microcomputer 151 performs all control such as control of information transmission between the controllers 150, 8 and 9.
When the control microcomputer 151 itself has a malfunction such as a runaway, the control microcomputer-side self-resetting unit 152 can reset the microcomputer to normal.

[0007]

In the conventional air conditioner control device, as described above, all the controls are performed by one control microcomputer. Single control software (program)
If it is a control microcomputer that controls by such software, the operation load of the control software is large and it is difficult to complete a series of control processes within an appropriate time.

Regarding the software configuration itself, it is difficult to completely separate each control block in the internal timer processing, multiple interrupt processing, etc., which causes a problem that the reliability of the software decreases.
Since this control microcomputer operates based on the enormous amount of control software described above, there is a problem that a huge verification load is applied during product development in order to ensure reliability. was there.

Further, when the control microcomputer side self-resetting means becomes ineffective in response to a malfunction of the control microcomputer when it runs out of control, the power is temporarily turned off and the microcomputer is artificially turned off. Need to reset,
I had no choice but to bother him.

The present invention has been made to solve the above-mentioned problems in the conventional control device.
The purpose of the present invention is to obtain a control device and a control device for a refrigeration cycle device, which can reduce the operation load and verification load of software, and can detect the abnormal state of the control device early and restore the normal operation early. The purpose is to achieve the purpose by a master / slave type control device.

[0011]

In order to achieve the above-mentioned object, a master-slave type control device according to the present invention comprises:
It is composed of an upper control device having an upper control function and a lower control device having a lower control function, and performs periodic communication between the upper control device and the lower control device by communication means,
In a master / slave control device that sets the operating state of a lower control device in response to a command from a higher control device, a first communication abnormality detection provided in the higher control device and detecting a communication abnormality with the lower control device Means, communication abnormality forced resetting means for forcibly resetting the lower control device when a communication abnormality is detected by the first communication abnormality detecting means, and the upper control device provided in the lower control device. Second communication abnormality detecting means for detecting a communication abnormality between the lower control device and the lower control device, by detecting the communication abnormality by the second communication abnormality detection means, determines the state of the upper control device to be a stopped state. The lower-level control device is brought into a stopped state.

In the master-slave control device according to the present invention, when the first communication abnormality detection means detects the communication abnormality in the upper control device, the communication abnormality forcible reset means forcibly resets the lower control device. When a communication abnormality is detected by the second communication abnormality detecting means in the lower-level control device, the lower-level control device determines that the state of the higher-level control device is the stopped state, and stops the operation. As a result, a problem that occurs when the lower control device continues to operate as it is in the event of a communication error is prevented, and the consistency of the operating state is ensured when the upper control device performs a forced reset to the lower control device.

A master / slave control device according to the next invention is the same as the master / slave control device described above,
The first communication abnormality detection means determines that there is a communication abnormality by not receiving a response to the transmission from the upper control device to the lower control device from the lower control device within a predetermined time, and determines the second communication. The abnormality detecting means determines that there is a communication abnormality by not receiving the transmission signal from the host controller for a predetermined time or more.

In the master-slave control device according to the present invention, the first communication abnormality detecting means does not receive a response to the transmission from the upper control device to the lower control device within a predetermined time from the lower control device, so that the communication abnormality occurs. The second communication abnormality detection means determines that there is a communication abnormality by not receiving the transmission signal from the host control device for a predetermined time or more.

The detection of the fact that the lower control device does not receive the transmission signal from the upper control device for a predetermined time or more means that when the lower control device receives the transmission signal, it transmits a response signal to the higher control device. On the basis of the premise, it can also be detected by measuring the interval time at which the lower control device transmits a transmission signal to the upper control device.

A master / slave control device according to the next invention comprises a higher control device having a higher control function and a lower control device having a lower control function, and is connected between the upper control device and the lower control device by communication means. In a master / slave type control unit that periodically communicates with the host control unit and sets the operating state of the lower control unit according to a command from the upper control unit, while the upper control unit is being provided with the upper control unit and is in initial processing. Has an initial forced reset means for performing a forced reset to the lower-level control device.

In the master-slave type control device according to the present invention, when the upper control device is in the initial processing, the lower communication control device is forcibly reset by the communication abnormality forcible resetting means. As a result, a problem that occurs when the lower control device continues to operate when the upper control device is initially processed is prevented.

A master / slave control device according to the next invention is the same as the master / slave control device described above,
The initial processing of the host controller is performed when the host controller is powered on or reset-reset, and during the power-on state or reset-reset state, the initial forced reset means continues the forced reset operation during that period. is there.

In the master / slave control device according to the present invention, when the host control device performs the initial processing when the power supply of the host control device is turned on or at the time of reset recovery, the lower control device is forcibly reset by the initial forced reset means during that time. A problem that occurs when the lower control device continues to operate when the upper control device is initially processed is prevented in advance.

A master / slave control device according to the next invention comprises a higher control device having a higher control function and a lower control device having a lower control function, and is connected between the upper control device and the lower control device by communication means. In the master / slave type control device that periodically communicates with the master control device and sets the operating state of the lower control device according to a command from the higher control device, the control variable provided in the upper control device and used in the lower control device. And a variable setting means for setting the variable to be changeable, and the control variable set by the variable setting means is given to the lower control device by transmitting to the lower control device by the communication means. Is.

In the master / slave control device according to the present invention, the control variable used in the lower control device is set to be changeable by the variable setting means in the upper control device, and the control variable set by the variable setting device is changed. It is transmitted to the lower control device by the communication means, and the control variable is given to the lower control device.

A master / slave control device according to the next invention is the same as the master / slave control device described above,
The control device is provided in the upper control device and has a control variable storage unit for storing the control variable set by the variable setting unit, and the lower control device sends a control variable setting request to the upper control device by the communication unit. When the upper control device transmits the control variable setting request and the upper control device receives the control variable stored in the control variable storage means as a response to the lower control device by the communication means. It is something to send.

In the master / slave control device according to the present invention, the control variable set by the variable setting means in the higher control device is stored in the control variable storage means, and the control variable setting request from the lower control device is sent to the upper control device. Upon reception by the control device, the upper control device transmits the control variable stored in the control variable storage means as a response to the lower control device by the communication means.

A master-slave type control device according to the next invention comprises an upper control device having an upper control function and a lower control device having a lower control function, and is connected between the upper control device and the lower control device by communication means. In a master-slave type control device that periodically communicates with the master control device and sets the operating state of the lower control device in response to a command from the upper control device, the operating state is provided for each of the upper control device and the lower control device. An operation state confirmation means for confirming, and a communication ignoring means provided in each of the upper control device and the lower control device for ignoring a communication signal by the communication means when the operation state confirmation state by the operation state confirmation means is provided,
When the operation state confirmation unit is in the operation state confirmation state, the upper control device and the lower control device can individually operate by ignoring the communication signal by the communication ignoring unit.

In the master / slave control device according to the present invention, the communication ignoring device ignores the communication signal from the communication device when the operation condition confirming means provided in each of the upper controller and the lower controller controls the operating condition. Then, the upper control device and the lower control device can individually operate independently. This operation state confirmation is performed at the time of individual maintenance of the upper control device and the lower control device.

A master / slave control device according to the next invention is the same as the master / slave control device described above,
An operating state confirmation means provided in each of the upper control device and the lower control device for confirming an operating state respectively, and an operating state confirmation state by the operating state confirmation means provided in each of the upper control device and the lower control device Sometimes, the communication ignoring means for ignoring the communication signal by the communication means, and the first and second communication abnormality detection in the operation state confirmation state provided by each of the upper control device and the lower control device by the operation state confirmation means Means for ignoring communication abnormality detection by means, and ignoring the forced reset by the communication abnormality forced reset means in the operation state confirmation state by the operation state confirmation means provided in each of the upper control device and the lower control device. Reset ignore means and
In the operation state confirmation state by the operation state confirmation means, the communication control unit ignores the communication signal by the communication ignoring unit, ignores the communication abnormality by the communication abnormality ignoring unit, and ignores the forced reset by the communication abnormality forced resetting unit. And are individually operable independently.

In the master / slave control device according to the present invention, the communication neglecting means ignores the communication signal from the communication means when the operation condition confirming means provided in each of the upper control device and the lower control device is in the operating condition confirming state. Communication abnormality by the communication abnormality ignoring means is ignored,
The forced reset by the communication abnormality forced reset means is ignored, and the upper control device and the lower control device are allowed to operate independently.

A master / slave type control device according to the next invention comprises an upper control device having an upper control function and a lower control device having a lower control function, and is connected between the upper control device and the lower control device by communication means. In a master / slave type control device that periodically communicates with the host control device and sets the operating state of the lower control device in response to a command from the upper control device, the master / slave control device may be connected to the upper control device and exchange information with an external service unit. Having possible external service unit connection means, and capable of monitoring internal information of the lower-level control device and changing variable settings through the service unit connection means and the communication means in accordance with a request from the external service unit. Is.

In the master-slave type control device according to the present invention, the upper control device can exchange information with the external service unit by the external service unit connecting means connected to the upper control device, and the service can be provided in accordance with the request from the external service unit. It becomes possible to monitor the internal information of the lower control device and change the variable settings via the unit connecting means and the communication means.

A control device for a refrigeration cycle apparatus according to the next invention comprises the master / slave control device described above.

The refrigeration cycle device mentioned here is all cooling and heating devices that use a refrigeration cycle, such as a cooling device, an air conditioner, a refrigerator, a freezer, and an ice maker.

In the master-slave control device according to the next invention, the higher-order control device controls the entire refrigeration cycle device to determine an inverter control value of the compressor according to the inverter control system of the refrigeration cycle device, The control device is provided with an inverter control value from the host control device to control the inverter of the compressor.

In the controller for the refrigerating cycle device according to the present invention, the upper controller controls the entire refrigerating cycle device to determine the inverter control value of the compressor by the inverter control system of the refrigerating cycle device, and the lower controller is The inverter control value is given from the host controller to control the inverter of the compressor.

[0034]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In the embodiments of the present invention described below, the same components as those of the above-described conventional example are denoted by the same reference numerals as those of the above-described conventional example, and description thereof will be omitted.

(Overall Structure) FIG. 1 shows an embodiment in which a master / slave control device according to the present invention is applied as a control device for an air conditioner.

The master / slave control device according to the present invention is applied to the outdoor unit controller 7 of an air conditioner, and the outdoor unit controller 7 is for controlling a refrigerant as a host controller for controlling the entire refrigerant circuit. Microcomputer 11
And an inverter control microcomputer 12 that controls the inverter as a subordinate device. The refrigerant control microcomputer 11 and the inverter control microcomputer 12 are connected by a serial communication means 13 so as to be capable of bidirectional communication, and information is periodically transmitted by a serial signal. In other words, the serial communication means 13 makes the refrigerant control microcomputer 11 a master and the inverter control microcomputer 12 a slave to cyclically perform data communication between the two at a predetermined time interval.

The refrigerant control microcomputer 11 calculates the cooling / heating operation mode setting, the inverter frequency of the compressor (inverter control value) according to the operation mode, the fan speed, the operation of the solenoid valve for controlling the expansion device, and the like. Make decisions and settings,
The inverter control microcomputer 12 is a serial communication means 13
The inverter control value is given by the refrigerant control microcomputer 11 to control the inverter 26 of the compressor 1.

Further, in the outdoor unit controller 7, when a communication abnormality is detected by a first communication abnormality detecting means 15a, which will be described later, provided in the refrigerant control microcomputer 11, or the refrigerant control microcomputer 11 performs an initial process. A forced reset means 14 is provided for performing a forced reset to the inverter control microcomputer 12 during the period. The forced reset means 14 operates as communication abnormal forced reset means and initial forced reset means.

The initial processing of the refrigerant control microcomputer 11 is performed when the refrigerant control microcomputer 11 is turned on or reset is reset. In the power-on state or the reset return state, the forced reset means 14 performs the forced reset operation during that period. continue.

The refrigerant control microcomputer 11 includes a first communication abnormality detection means 15a for detecting communication failure with the inverter control microcomputer 12 by the serial communication means 13, and an inverter control variable used in the inverter control microcomputer 12. Of the variable setting means 16, a first inverter set value storage means (control variable storage means) 18a for storing the variable set value (inverter set value) set by the variable set means 16, and a refrigerant. A first operating state confirming means 19a that enables the control microcomputer 11 to operate independently, a first communication abnormality ignoring means 20a that ignores communication abnormality between the serial communication means 13 and the inverter control microcomputer 12, and inverter control. Serial communication for ignoring serial communication by the serial communication means 13 with the microcomputer 12 for communication It has means 21a viewing, and a reset release means 22 for releasing the forced reset to the inverter control microcomputer 12.

The inverter control microcomputer 12 includes a second communication abnormality detection means 15b for detecting communication failure with the refrigerant control microcomputer 11 by the serial communication means 13, and an inverter for changing a variable set value of the inverter control microcomputer 12. The setting value changing means 17 and the second inverter setting value storage means 18b for storing the variable setting value (inverter setting value) changed by the inverter setting value changing means 17
A second operating state confirmation means 19b for independently operating the inverter control microcomputer 12, and a second communication abnormality ignoring means 20b for ignoring communication abnormality between the refrigerant control microcomputer 11 by the serial communication means 13. , A second serial communication ignoring means 21b for ignoring serial communication with the refrigerant control microcomputer 11 by the serial communication means 13, a reset ignoring means 23 for ignoring a forced reset from the refrigerant control microcomputer 11, and an inverter control microcomputer. 12
The operation setting permission means 24 for permitting the operation setting of the above and the operation setting means 25 for performing the operation setting of the inverter control microcomputer 12 are provided.

The outdoor unit controller 7 also has external service unit connection means 28 capable of exchanging information with the external service unit 27 connected to the refrigerant control microcomputer 11.

The first communication abnormality detecting means 15a determines that there is a communication abnormality by not receiving a response to the transmission from the refrigerant control microcomputer 11 to the inverter control microcomputer 12 within a predetermined time from the inverter control microcomputer 12. According to this judgment (communication abnormality), the forced resetting means 14 resets the inverter control microcomputer 12 by force.

The second communication abnormality detecting means 15b determines that there is a communication abnormality by not receiving the transmission signal from the refrigerant control microcomputer 11 for a predetermined time (cyclic communication interval time) or more, and this determination is made. Based on the above, the refrigerant control microcomputer 11 is determined to be in the stopped state, and the refrigerant control microcomputer 11 is brought into the stopped state.

In this embodiment, the second communication is based on the premise that when the inverter control microcomputer 12 receives a transmission signal from the refrigerant control microcomputer 11, it sends a response signal to the refrigerant control microcomputer 11. Anomaly detection means 15
In b, the communication abnormality is detected by measuring the interval time at which the inverter control microcomputer 12 transmits a transmission signal (response) to the refrigerant control microcomputer 11.

The inverter control microcomputer 12 transmits a control variable setting request to the refrigerant control microcomputer 11 via the serial communication means 13, and the refrigerant control microcomputer 11 receives the control variable setting request, whereby the refrigerant control microcomputer 11 receives the control variable setting request. Is a response to the first inverter set value storage means 1
8a stores the control variables stored in the serial communication means 13
Is transmitted to the inverter control microcomputer 12.

First and second communication abnormality ignoring means 20a, 2
0b is the first and second operating state confirmation means 19a, 19b.
During the operation state confirmation state according to the above, the communication abnormality detection by the first and second communication abnormality detection means 15a and 15b is ignored.

The first and second serial communication ignoring means ignore the communication signal from the serial communication means 13 in the operation state confirmation state by the first and second operation state confirmation means 19a and 19b.

The reset ignoring means 23 ignores the forced reset by the forced resetting means 14 when the second operating state confirming means 19b confirms the operating state.

Next, the operation of the control device configured as described above will be described with reference to FIGS.

(Forced reset operation when communication is abnormal) FIG. 2
(A), (b) has shown the forced reset operation | movement at the time of communication abnormality of the microcomputer 11 for a refrigerant control, and the microcomputer 12 for an inverter control.

As shown in FIG. 2A, the refrigerant control microcomputer 11 periodically performs a transmission process to the inverter control microcomputer 12 by the serial communication means 13 (step S30), and the transmission process is completed. It is measured whether a predetermined time has elapsed from the time (step S31).

When a predetermined time has elapsed from the completion of the transmission process, the inverter control microcomputer 1 is controlled by the first communication abnormality detecting means 15a for the transmission process in step S30.
It is judged whether or not there is a reception (response) from 2 (step S32), and if there is a reception, this routine is terminated assuming that communication is normally performed.

On the other hand, if no signal is received within the predetermined time, it is determined that the communication is abnormal (communication is not possible), and the compulsory reset means 14 compulsorily resets the inverter control microcomputer 12 (step S33). The operation state of the air conditioner is set to a standby state in which the operation is prohibited for a predetermined time.

Whether or not a predetermined time has elapsed since the start of the forced reset is measured (step S34), and when the predetermined time has elapsed, the forced reset of the inverter control microcomputer 12 is released (step S35). As a result, the standby state of the operating condition of the air conditioner is released, and the processing corresponding to the normal operating condition operation of the air conditioner set by the remote controller 9 is executed.

As shown in FIG. 2B, the inverter control microcomputer 12 measures the elapsed time after transmitting the transmission signal (response) to the refrigerant control microcomputer 11 by the serial communication means 13. (Step S40) When the elapsed time has elapsed, it is determined whether or not there is a reception from the refrigerant control microcomputer 11 (step S41). If there is a reception, this routine is terminated assuming that the communication is normally performed.

On the other hand, when there is no reception, the inverter control microcomputer 12 determines that the refrigerant control microcomputer 11 is in the stopped state (step S42), and this routine is ended.

As described above, in this control device, one air conditioning control device is composed of the refrigerant control microcomputer 11 as the control device of the higher control function and the inverter control microcomputer 12 as the control device of the lower control function. Since the configuration is divided, it is possible to reduce the operating load of the software for each control device (microcomputer), and divide the control configuration for each function to operate with software that suits the individual required processing capacity. As a result, mutual interference on the software can be minimized and the verification load can be reduced.

When the communication abnormality is detected by the first communication abnormality detecting means 15a in the refrigerant control microcomputer 11 in addition to the above effects, the (communication abnormality) forced resetting means 14 causes the inverter to operate. When the control microcomputer 12 is forcibly reset and a communication abnormality is detected by the second communication abnormality detecting means 15b in the inverter control microcomputer 12, the inverter control microcomputer 12 determines that the refrigerant control microcomputer 11 is in the stopped state. Judge and stop operation. As a result, the refrigerant control microcomputer 11
When the communication abnormality with the inverter control microcomputer 12 continues to operate as it is, a problem that occurs when the inverter control microcomputer 12 continues to operate is prevented.
On the other hand, the consistency of the operating state is ensured when the forced reset is performed, and the stable operating state is maintained.

(Forced reset operation at initialization)
FIG. 3 shows the forced reset operation by the refrigerant control microcomputer 11.

The refrigerant control microcomputer 11 determines whether it is in the power-on state or the reset recovery state (step S50). The refrigerant control microcomputer 11 is reset when a runaway detection circuit (not shown) such as a watchdog timer detects a runaway.

In the power-on state or the reset recovery state, the forced reset means 14 performs a forced reset on the inverter control microcomputer 12 (step S51). When this forced reset is applied, the refrigerant control microcomputer 11 executes its own initial processing (step S52). The forced reset of the inverter control microcomputer 12 is continuously performed during the initial processing of the refrigerant control microcomputer 11, and when the initial processing of the refrigerant control microcomputer 11 is completed, the inverter control microcomputer 12 is reset.
The forced reset of is canceled (step S53), and this routine is finished.

By the above operation, the refrigerant control microcomputer 1
When the inverter 1 is subjected to the initial processing, the malfunction that occurs when the inverter control microcomputer 12 continues to operate is prevented, the consistency of the operating state is ensured, and the stable operating state is maintained.

(Inverter setting value transmission setting operation) FIG. 4
(A), (b) has shown the transmission setting operation | movement of the inverter setting value of the microcomputer 11 for a refrigerant control, and the microcomputer 12 for an inverter control.

As shown in FIG. 4A, the refrigerant control microcomputer 11 monitors the reception of the inverter setting request from the inverter control microcomputer 12 (step S6).
0), when the inverter setting request is received, the inverter setting value stored in the first inverter setting value storage means 18a is transmitted to the inverter control microcomputer 12 by the serial communication means 13 (step S61).

As shown in FIG. 4B, the inverter control microcomputer 12 determines whether the power is on (step S70), and if it is on, executes its own initial processing. After the completion of the initial processing (step S71), an inverter setting request is transmitted to the refrigerant control microcomputer 11 by the serial communication means 13 (step S72).

Next, the inverter control microcomputer 12 monitors the reception of the inverter set value from the refrigerant control microcomputer 11 (step S73). When the inverter set value is received, the inverter set value changing means 17 sends it to the second set value. The data is written in the inverter setting value storage means 18b (step S74), and this routine is finished.

As a result, the upper refrigerant control microcomputer 1
Variables used in the inverter control microcomputer 12 lower than 1 can be set to be changeable. For example, even when the variables used in the inverter control microcomputer 12 are different for each air conditioner, the common inverter control microcomputer 12 is used. It becomes possible to do.

(Operation status confirmation operation) FIGS. 5 and 6 show operation status confirmation operations of the refrigerant control microcomputer 11 and the inverter control microcomputer 12, respectively.

As shown in FIG. 5, the refrigerant control microcomputer 11 first determines whether or not the operation state confirmation means 19a is in the confirmation state (step S90). The serial communication ignoring means 21a of No. 1 ignores the serial communication with the inverter control microcomputer 12 by the serial communication means 13 (step S9).
1), followed by the first communication abnormality ignoring means 20a
The detection of the serial communication abnormality by the communication abnormality detection means 15a is ignored (step S92), and the forced reset means 14 is operated.
Then, the inverter control microcomputer 12 is forcibly reset (step S93).

Further, as shown in FIG. 6, the inverter control microcomputer 12 first operates the operation state confirmation means 19b.
It is determined whether or not it is in the confirmation state (step S11).
0), if it is in the confirmation state, the second serial communication ignoring means 21b ignores the serial communication with the refrigerant control microcomputer 11 by the serial communication means 13 (step S1).
11), and then the second serial communication abnormality ignoring means 20b
Thus, the detection of the serial communication abnormality by the second communication abnormality detecting means 15b is ignored (step S112), and the forced reset processing from the refrigerant controlling microcomputer 11 is ignored by the reset ignoring means 23 of the inverter controlling microcomputer 12 (step S113). ).

Then, the inverter control microcomputer 12
The operation setting permitting means 24 permits the operation operation (single operation on the inverter control side) by the operation setting means 25 (step S114), and the present routine ends.

By the above-mentioned operation, when it is desired to individually confirm the operating state of each of the refrigerant control microcomputer 11 and the control device inverter control microcomputer 12, both microcomputers can operate independently. When a problem occurs in the, it is possible to quickly determine which microcomputer is in the failure state.

(Variable Setting Change / Monitoring Operation by Request from External Service Unit) FIGS. 7A and 7B show variable setting change in the refrigerant control microcomputer 11 and the inverter control microcomputer 12 by request from the external service unit. -Indicates monitor operation.

As shown in FIG. 7A, the refrigerant control microcomputer 11 first determines whether or not the external service information is received from the external service unit 27 (step S120). If so, it is determined whether or not the external service information includes inverter information (step S121). This inverter information includes the operating / stopped state of an inverter cooling fan (not shown) whose operation is regulated by the refrigerant control microcomputer 11, sensor readings such as inverter current and inverter temperature, and the like. If there is no inverter information, this routine is unquestioned (step S125), and this routine ends.

On the other hand, if there is inverter information, serial communication means 13 performs serial communication transmission processing to the inverter control microcomputer 12 (step S122), and receives serial communication information from the inverter control microcomputer 12. (Step S123).

When the serial communication information is received from the inverter control microcomputer 12, the inverter information included in the received serial communication information is sent to the external service unit 2.
7 (step S124), and this routine ends.

As shown in FIG. 7B, the inverter control microcomputer 12 determines whether or not the serial communication information is received from the refrigerant control microcomputer 11 (step S130). For example, Refrigerant control microcomputer 1
It is determined whether or not there is external service information in the serial communication information received from 1 (step S131). If there is no external service information, this routine is unquestioned (step S135), and this routine ends.

On the other hand, if there is external service information,
The response information to the external service information is provided (step S132), and the serial communication means 13 performs a serial communication transmission process to the refrigerant control microcomputer 11 (step S133).

By the above-described operation, the external service unit 27 is connected to the upper refrigerant control microcomputer 11 by the external service unit connecting means 28, so that the lower inverter control microcomputer 12 can operate in accordance with the request from the external service unit 27. It is possible to monitor internal information and change variable settings.

In the above embodiment, the example of the control device for the air conditioner has been described. However, the control device according to the present invention can be used for refrigerating equipment such as air conditioners, air conditioners, refrigerators, freezers, and ice makers. It can be used in the same manner as in the above-described embodiment as a cooling / heating device that uses a cycle, other various devices, and a device control device.

[0082]

As can be understood from the above description, according to the master / slave type control device of the present invention, the conventional control device has only one control device for the upper control function and the control for the lower control function. As it is divided into devices,
The operation load and verification load of software created for each control device can be reduced, and reliability can be improved. In addition, the upper-level control device detects the operating state (communication abnormality) of the lower-level control device, and when it recognizes a defect in the operating state, the lower-level control device automatically resets it forcibly so that the lower-level control device continues to operate. It is possible to avoid problems that may occur when the operation is continued, match the operating conditions of the control device such as the air conditioner, and maintain a stable operating condition.

When the lower control device detects that communication with the upper control device is impossible, it is determined that the upper control device is in a stopped state, so it is said that the lower control device cannot communicate with the upper control device. Quickly get out of the abnormal state,
It can enter a normal state or a protection state as a control device such as an air conditioner.

According to the master / slave control device of the next invention, the communication abnormality detecting means of the upper control device does not receive a response from the lower control device to the transmission from the upper control device to the lower control device within a predetermined time. It is determined that there is a communication error, and the communication error detection means of the lower control device determines that there is a communication error by not receiving a transmission signal from the higher control device for a predetermined time or longer. The forced reset of the control device is appropriately performed, and when the communication is abnormal, the operating condition of the control device such as the air conditioner can be matched and the stable operating condition can be maintained.

According to the master / slave type control device of the next invention, it is possible to reduce the operation load and the verification load of the software created corresponding to each of the upper control device and the lower control device to improve the reliability. Of course you can
The upper-level control device detects the operating state of the lower-level control device and forcibly resets the lower-level control device when the lower-level control device is in the initial process, so there is a problem that occurs when the lower-level control device continues to operate. It was avoided before it happened,
It is possible to match the operating state as a control device such as an air conditioner and maintain a stable operating state.

According to the master-slave type control device of the next invention, when the host control device performs the initial processing when the power supply of the host control device is turned on or when the reset control is resumed, the host control device performs the initial forced resetting means during that time. Since it is forcibly reset by the above, troubles that occur when the lower control device continues to operate when the upper control device is initially processed are prevented in advance, and the operating state as a control device such as an air conditioner is matched. It is possible to maintain a stable operating condition.

According to the master / slave control device according to the next invention, it is possible to reduce the operation load and verification load of the software created corresponding to each of the upper control device and the lower control device, and increase the reliability. In addition to being able to do, the upper control device can set the variable used in the lower control device so that it can be changed, so, for example, when the variable used in the lower control device is different for each control target model, for example, for each air conditioner. However, a common lower controller can be used.

According to the master / slave type control device of the next invention, the control variable set by the variable setting means in the upper control device is stored in the control variable storage means, and the control variable setting by the lower control device is performed. When the upper control device receives the request, the upper control device sends the control variable stored in the control variable storage means to the lower control device through the communication means as a response. Even when different for each model to be controlled, for example, for each air conditioner, a common lower control device can be used.

According to the master / slave control device according to the next invention, it is possible to reduce the operation load and verification load of the software created corresponding to the upper control device and the lower control device, and to improve the reliability. In addition to being able to do, the communication signal by the communication means is ignored by the communication ignoring means in the operation state confirmation state, and the upper control device and the lower control device can individually operate independently. When it occurs, it is possible to quickly determine which control device is in a failure state.

According to the master / slave control device of the next invention, in the operation state confirmation state, the communication ignoring means ignores the communication signal from the communication means, the communication abnormality ignoring means ignores the communication abnormality, and the communication abnormality is forced. Since the forced reset by the reset means is ignored, the upper control device and the lower control device can individually operate independently,
For example, when a failure occurs in the control device, it is possible to quickly determine which control device is in the failure state.

According to the master / slave control device according to the next invention, it is possible to reduce the operation load and verification load of the software created corresponding to the upper control device and the lower control device, and to improve the reliability. In addition to being able to do, by connecting the external service unit to the host controller, according to the request from the external service unit,
Via the service unit connection means and the serial communication means, the internal information of the control device of the lower control function can be monitored and the variable settings can be changed.

According to the refrigerating cycle controller according to the next invention, the effects of the master / slave type controller described above are obtained in the refrigerating cycle controller, and good refrigerating cycle control is performed.

According to the control device for a refrigerating cycle device of the next invention, the upper control device controls the entire refrigerating cycle device to determine the inverter control value of the compressor by the inverter control system of the refrigerating cycle device, Since the control device is given an inverter control value from the upper control device to control the inverter of the compressor, the operation load and verification load of software created corresponding to the upper control device and the lower control device are reduced. In addition to being capable of achieving high reliability, good refrigeration cycle control is performed.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment in which a master / slave control device according to the present invention is applied as a control device for an air conditioner.

FIG. 2A is a flowchart of forced resetting of the refrigerant control microcomputer, and FIG. 2B is a flowchart of communication abnormality detection of the inverter control microcomputer.

FIG. 3 is a flowchart of a forced reset of the refrigerant control microcomputer at the time of initialization.

FIG. 4A is a flowchart of an inverter setting value transmission setting operation by the refrigerant control microcomputer, and FIG. 4B is a flowchart of an inverter setting value transmission setting operation by the inverter control microcomputer.

FIG. 5 is a flowchart of an operation state confirmation operation of the refrigerant control microcomputer.

FIG. 6 is a flowchart of an operation state confirmation operation of the inverter control microcomputer.

FIG. 7A is a flowchart for connecting an external service unit in the refrigerant control microcomputer, and FIG. 7B is a flowchart for connecting an external service unit in the inverter control microcomputer.

FIG. 8 is a block diagram showing a conventional control device for an air conditioner.

[Explanation of symbols]

1 compressor, 2 outdoor unit side heat exchanger, 3 expansion device, 4
Indoor unit heat exchanger, 5 Liquid side refrigerant pipe, 6 Gas side refrigerant pipe, 7 Outdoor unit controller, 8 Indoor unit controller, 9 Remote controller, 10 Transmission line, 11
Refrigerant control microcomputer, 12 Inverter control microcomputer, 13 Serial communication means, 14 Forced reset means, 15a First communication abnormality detecting means, 15b Second communication abnormality detecting means, 16 variable setting means, 17 Inverter setting value changing means , 18a first inverter set value storage means, 18b second inverter set value storage means,
19a First operating state confirming means, 19b Second operating state confirming means, 20a First communication abnormality ignoring means, 20
b second communication abnormality ignoring means, 21a first serial communication ignoring means, 21b second serial communication ignoring means,
22 reset releasing means, 23 reset ignoring means, 2
4 operation setting permitting means, 25 operation setting means, 26 inverter, 27 external service unit, 28 external service unit connecting means

Claims (11)

[Claims] 1. A high-order control device comprising a high-order control device having a high-order control function and a low-order control device having a low-order control function, wherein communication means performs periodic communication between the high-order control device and the low-order control device to obtain a high-order control. A master / slave control device for setting an operating state of a lower control device according to a command from the device, comprising: first communication abnormality detection means provided in the upper control device for detecting a communication abnormality with the lower control device. A communication abnormality forced reset means for forcibly resetting the lower-level control device when a communication abnormality is detected by the first communication abnormality detection means, and a higher-order control device provided in the lower-level control device. A second communication abnormality detecting means for detecting a communication abnormality, wherein the lower control device detects the communication abnormality by the second communication abnormality detecting means. Master-slave control device, which comprises the low order control device in the stopped state to determine the state of the device stopped. 2. The first communication abnormality detection means determines that there is a communication abnormality by not receiving a response to the transmission from the upper control device to the lower control device from the lower control device within a predetermined time, 2. The master / slave system according to claim 1, wherein the second communication abnormality detection means determines that there is a communication abnormality by not receiving a transmission signal from the upper control device for a predetermined time or more. Control device. 3. A high-order control device comprising a high-order control device having a high-order control function and a low-order control device having a low-order control function, wherein communication is performed between the high-order control device and the low-order control device to perform periodic communication. In a master-slave type control device that sets the operating state of a lower control device according to a command from the device, a forced reset is provided to the lower control device while the upper control device is provided in the upper control device and initial processing is being performed. A master / slave type control device having an initial forced resetting means for performing. 4. The initial process of the host controller is performed when the host controller is powered on or reset-reset.
4. The master / slave control device according to claim 3, wherein the initial forced reset means continues the forced reset operation during that period. 5. A high-order control device comprising a high-order control device having a high-order control function and a low-order control device having a low-order control function, wherein communication is performed between the high-order control device and the low-order control device at regular intervals. In a master / slave control device that sets the operating state of a lower-level control device in response to a command from the device, a variable setting means that is provided in the higher-level control device and that can set a variable for control used in the lower-level control device is changeable. A master / slave control device having the control variable set by the variable setting means to the lower control device by transmitting the control variable to the lower control device by the communication means. . 6. A control variable storage means is provided in the upper control device for storing a control variable set by the variable setting means, wherein the lower control device sends a control variable setting request by the communication means. When the upper control device transmits to the upper control device and the upper control device receives the control variable setting request, the upper control device responds by the communication means with the control variable stored in the control variable storage means. The master / slave control device according to claim 5, wherein the master / slave control device transmits to the lower control device. 7. A high-order control device comprising a high-order control device having a high-order control function and a low-order control device having a low-order control function, wherein communication is performed between the high-order control device and the low-order control device to perform periodic communication. In a master-slave type control device that sets the operating state of a lower-level control device in response to a command from the device, an operating-state checking unit that is provided in each of the upper-level control device and the lower-level control device to check the operating state, The control device and the subordinate control device are provided respectively with communication ignoring means for ignoring a communication signal by the communication means when the operation state confirmation means is in the operation state confirmation state, and when the operation state confirmation means is in the operation state confirmation state. The upper control device and the lower control device can individually operate independently by ignoring the communication signal by the communication ignoring means. Master / slave type control device. 8. The master / slave control device according to claim 1, wherein the upper control device is provided in each of the upper control device and the lower control device, and the operating condition confirmation means confirms an operating condition. A device for disabling a communication signal from the communication unit when the operation status confirmation unit is in an operation state confirmation state, and a communication disregard unit provided to each of the apparatus and the lower control unit; and each of the upper control unit and the lower control unit. Communication abnormality ignoring means for ignoring the communication abnormality detection by the first and second communication abnormality detecting means when the operation state confirming means is in the operation state confirming state, and each of the upper control device and the lower control device are provided with the communication abnormality ignoring means. Reset error ignoring the forced reset by the communication error forced reset means when the operating status is confirmed by the operating status confirmation means In the operation state confirmation state by the operation state confirmation means, the communication signal is ignored by the communication ignoring means, the communication abnormality is ignored by the communication abnormality ignoring means, and the forced reset is ignored by the communication abnormality forced resetting means. A master / slave type control device characterized in that the lower control device can individually operate independently. 9. A high-order control device comprising a high-order control device having a high-order control function and a low-order control device having a low-order control function, wherein communication is performed between the high-order control device and the low-order control device to perform periodic communication. A master / slave control device for setting an operating state of a lower control device according to a command from the device, having an external service unit connecting means connected to the upper control device and capable of exchanging information with an external service unit. A master / slave control device capable of monitoring internal information of the lower-level control device and changing variable settings via the service unit connection means and the communication means in accordance with a request from the external service unit. . 10. A control device for a refrigeration cycle device, comprising the master / slave control device according to any one of claims 1 to 9. 11. The upper control device controls the entire refrigeration cycle device to determine an inverter control value of a compressor according to the inverter control method of the refrigeration cycle device, and the lower control device controls the inverter control from the upper control device. The control device for the refrigeration cycle apparatus according to claim 10, wherein the control device controls the inverter of the compressor by being given a value.