JPH03152336A - Operation control device for air conditioner - Google Patents

Abstract

PURPOSE:To enable a comfortable air conditioning to be attained by a method wherein when a slave device of a second air conditioner is present, a control signal corresponding to the function of the second air conditioner is varied and the control signal is outputted or inputted. CONSTITUTION:As a slave device 3c of a second air conditioner is judged by machine type discrimination means 33c, 33c, slave devices 36, 36... composed of the first air conditioner is provided with input varying means 33e, 33e... for inputting a content of the control signal of a master device 3a in response to a control of the second air conditioner. As the machine type discriminating means 33c, 33c,... judge a connection of the slave machine 3c of the second air conditioner, an output varying means 33d of the master device 3a may vary a content of the control signal of the air conditioning controller means 33a into a control content of the second air conditioner device. With such an arrangement, it is possible to perform a comfortable air conditioning operation.

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to an operation control device for an air conditioner equipped with a plurality of air conditioning units, and particularly relates to control measures when air conditioning units with different functions are installed together. It is.

(Prior Art) Generally, as an example of an air conditioner, Japanese Patent Laid-Open No. 62-10
As disclosed in Japanese Patent No. 2051, there is a device in which a plurality of air conditioning units (slave units) are connected in parallel to a power source, and the convex sub units are operated for air conditioning to cool and heat a room. Further, a master unit, which is a controller, is connected to the slave unit via a signal line, and an individual operation master unit is connected to the base unit via a signal line.

Address signals and control signals are sequentially transmitted and received between the base unit and each slave unit, and the base unit centrally controls each slave unit, while the function changeover switch of the base unit is controlled. When switched, the individual operation master unit can be operated, and each child unit can be individually controlled by the individual operation master unit, thereby increasing the degree of control freedom.

(Problem to be Solved by the Invention) In the operation control device for the air conditioner described above, each slave unit is centrally controlled based on a control signal output from the master unit, and for example, if the set temperature or fan air volume is the same. It is designed to be controlled by

However, if each of the above-mentioned handsets has the same functions, they will be controlled to the same state by the control signal from the base unit, but if each handset has different functions, the content of the control signal will vary depending on each handset. However, there was a problem in that accurate centralized control could not be performed. That is, for example, if a new model and an old model coexist, and the new model has three fans.
In some cases, older models of slave devices operate at two speeds, and even if the parent device outputs a medium-speed control signal, the older model of slave devices cannot read the control details. As a result, in older model slave units, the fan may stop or perform other controls, resulting in malfunctions and a problem in that comfortable air conditioning operation cannot be performed.

The present invention has been made in view of the above, and an object of the present invention is to prevent malfunctions even when air conditioning units with different functions coexist, and to provide comfortable air conditioning. It is.

(Means for Solving the Problems) In order to achieve the above object, the means taken by the present invention are such that the parent unit determines the model of each slave unit and performs centralized control in response to air conditioning units with fewer functions. This is how it was done.

Specifically, as shown in FIG. 1, the measures taken by the invention according to claim (1) first include a main function for executing a predetermined air conditioning operation and a first air conditioning system having an additional function different from the main function. A master unit (3a) consisting of an air conditioning unit, and a plurality of slave units (3b), (3c) consisting of either the first air conditioning unit or a second air conditioning unit having only the main function.
This assumes an air conditioner equipped with...

And the parent device (3a) and each child device (3b).

(3c), ... exchange control signals with each other, and each slave unit (3a) based on the control signal output from the base unit
3b), (3c), . . . are centrally controlled to control air conditioning operation (33a).

(33a), . . . , each air conditioning control means (33a), (33a), . Model classification means (33b) for outputting a classification signal, (
33b), . . . are provided. Furthermore, the first
A master unit (3a) and a slave unit (3b) consisting of an air conditioning unit,
(3b), -... have other handsets (3c), (3c)...
Model determination means (33c), (33c), .
・ is provided. In addition, the base unit (3a) has a model determination means (33c) that is connected to the slave unit (3c) of the second air conditioning unit.
), output changing means (33d) is provided which changes the content of the control signal output by the air conditioning control means (33a) to the control content of the second air conditioning unit. On the other hand, the first
The slave units (3b) (3b), .

(33c), ... are slave units of the second air conditioning unit (3c)
When it is determined, the air conditioning control means (33a), (33a
), . . . input change means (33e), (33e), . .

Further, the means taken by the invention according to claim (2) is that in the invention of the two companies according to claim (1), the output changing means (33d) of the main unit (3a) is connected to the first air conditioning unit and the second air conditioning unit. It is configured to change the content of a control signal for a function with the same purpose that operates differently from the unit.

(Operation) With the above configuration, in the invention according to claim (1), the base unit (
3a) and each slave unit (3b), (3c), -, each air conditioning control means (33a), (33a),...
transmits and receives control signals, and when transmitting and receiving this control signal, the model classification means (33b), (33b), ... outputs a classification signal when outputting a preset control signal, for example, when the power is turned on. Each air conditioning control means (33a) outputs a classification signal at different times.

(33a), . . . output model signals corresponding to the functions of their respective air conditioning units.

This model signal is used for the base unit (3a) and slave unit (3b).
, (3b), . . . each air conditioning control means (33a), (3
3a), . . . receive data, and the main unit (3a) and slave units (3b) (3b), .
In , model discrimination means (33c), (33c)
, . . . determine whether or not the child unit (3c) of the second air conditioning unit exists. According to this determination, if the slave unit (3c) of the second air conditioning unit is not connected, the air conditioning control means (3) of the base unit (3a) and each slave unit (3b), .
3a), (33a), . . . transmit and receive control signals without changing them in any way, and control the air conditioning operation.

On the other hand, the model discrimination means (33c), (33c)
... determines that the child unit (3c) of the second air conditioning unit is connected, the output changing means (3a) of the main unit (3a)
3d) converts the control signal content of the air conditioning control means (33a) into a second
Change the control details of the air conditioning unit. That is, in the invention according to claim 2, among the functions of the first air conditioning unit and the second air conditioning unit, the control content of the second air conditioning unit is changed for the same purpose function that operates differently. Each received handset (3b), (3c),
..., the input changing means (33e) changes the control content of the second air conditioning unit to the slave unit (3b) of the first air conditioning unit and imports it, while the slave unit (3b) of the second air conditioning unit changes and imports the control content of the second air conditioning unit.
c) is taken in as is and the air conditioning operation is controlled.

(Effect of the invention) Therefore, according to the invention of claim (1), the base unit (3a
) and each slave unit (3b), (3c), - output a model signal, and when there is a slave unit (3c) of the second air conditioning unit, a control signal corresponding to the function of the second air conditioning unit is output. Since the control signal is changed to be output or taken in, even when air conditioning units with different functions coexist, each slave unit (3b), (3c), . . . can be accurately and centrally controlled. In particular, since the child unit (3c) of the second air conditioning unit does not malfunction, comfortable air conditioning can be performed. Furthermore, there is a handset (3b) with different functions.

Since (3c),... can coexist,
It is possible to add or change slave units, and it is possible to improve the degree of freedom in installation.

In addition, according to the invention according to claim 2, since the content of the control signal is changed for the same purpose function that operates differently in the first air conditioning unit and the second air conditioning unit, the function added to the second air conditioning unit is operated in the child units (3b), (3b)1, . . . of the first air conditioning unit, and accurate centralized control can be performed without degrading functionality.

(Example) Hereinafter, an example of the present invention will be described in detail based on the drawings.

As shown in FIGS. 2 and 3, (1) is a multi-type air conditioner, in which one outdoor unit (2) has a base unit (3a) which is an indoor unit, and multiple units ( Second
In the figure, two handset units (3b) and (3c) are connected, and the base unit (3a) and the handsets (3b), (3c) are connected to each other.
constitutes the air conditioning unit. Although not shown, the outdoor unit (2) is internally equipped with a compressor, a four-way switching valve for cold/warm switching, and an outdoor heat exchanger, while the main unit (3a) and slave unit (3b) Although not shown, (3c) is equipped with an expansion mechanism and an indoor heat exchanger inside, and the parent unit (3a) and slave units (3b) and (3c) are connected in parallel to the outdoor unit (2). In addition, they are connected so that refrigerant can circulate, forming a single refrigerant circulation system.

Furthermore, the main unit (3a) is a new type unit which is the first air conditioning unit, and the slave units (3b) and (3c) are the first air conditioning unit.
It is composed of either a new type air conditioning unit or an old type unit that is a second air conditioning unit. The new unit and the old unit have different functions (not shown); the old unit has only certain main functions, such as an indoor fan control function and anti-freezing function, while the new unit has the above main functions. In addition, it has additional functions, such as a louver control function. Furthermore, compared to the old model, the new unit has different functions even though they have the same purpose.For example, in the indoor fan control function, the old model has two-speed control of H-L. , the new unit is configured with H-M-L three-speed control. For example, the first slave device (3b) is a new model unit, and the second slave device (3c) is an old model unit.

On the other hand, a remote controller (4) is connected to the base unit (3a), and the remote controller (4) displays the slave units (3b) and (3c) in the same operating state via the base unit (3a). We are trying to centralize control. The remote control (4) has a key power section (41) for an operator such as a resident to appropriately select a driving mode, etc., and also displays driving information such as the selected driving mode and the current driving state. It has a display section (42) for displaying. Furthermore, the above remote control (4)
includes a control unit (43) that processes operation signals for air conditioning operation, wind speed, etc. input from the key human power units (4 units) and outputs control signals, and a control signal for the control unit (43). a transmitting unit (44) that outputs the information to the base unit (3a), and a receiving unit (45) that receives driving information signals from the base unit (3a) and slave units (3b) and (3c) from the base unit (3a). ) is provided.

On the other hand, the base unit (3a) and slave units (3b) and (3c) each have an address setting section (31) consisting of a deep switch, etc., in which their own address is set, and the operating state to be controlled of the internal devices. an indoor control unit (32) that determines the
3), and a pair of indoor transmitter (34) and indoor receiver (35) for transmitting address signals and control signals to the remote controller (4) and receiving control signals from the remote controller (4), etc. A remote control (4) is connected to the base unit (3a). Furthermore, the base unit (3a) and slave units (3b), (3c) transmit and receive various control signals such as operation signals to and from the outdoor unit (2),
A pair of indoor transmitting section (36) and indoor receiving section (37) are provided for transmitting and receiving various control signals between the base unit (3a) and the slave units (3b), Dc). The outdoor unit (2) has a pair of outdoor transmitter (21) and outdoor receiver (2) that transmit and receive control signals to and from the base unit (3a).
2) is provided.

Furthermore, the parent device (3a) and the child device (3b).

The main body control section (33) of (3c) includes an air conditioning control means (3
3a) and model classification means (33b),
The air conditioning control means (33a) of the main unit (3a) is connected to the remote control (4
) controls the air conditioning operation of the main unit (3a) and sends the @ control signal of the remote controller (4) to each slave unit (3b).

(3b) and the outdoor unit (2), and receives control signals such as request signals for anti-freezing operation from each slave unit (3b), (3c) and the outdoor unit (2), and transmits the control signal to the remote control (4). is configured to send to. In addition, the air conditioning control means (33) of each of the slave units (3b) and (3c)
a) receives the control signal from the base unit (3a) and controls each slave unit (3a).
It is configured to uniformly control the air conditioning operations of 3b) and (3c) and to transmit various status signals to the main unit (3a). Furthermore, the model classification means (33b) sends a model signal indicating whether the unit is a new type unit or an old type unit to each air conditioning control means (33a) when the power is turned on.
), and the model signal is set to, for example, 01H for a new model unit and 02H for an old model unit.

Moreover, the master device (3a) of the new model unit has a model discrimination means (33c) and an output change means (33d), and the slave device (3b) of the new model unit has a model discrimination means (33c) and an input change means (33e). ) are configured. The model discrimination means (
33c) is the base unit (3a), slave unit (3b), (3c
) of the old model unit based on the model signal output by the slave unit (
It is configured to determine whether or not 3c) exists and output a determination signal. In addition, the output changing means (33d
), the model discrimination means (33c) is the slave unit (3) of the old model unit.
If c) is determined, the air conditioning control means (33a) is configured to change the content of the control signal outputted to the control content of the old model unit. That is, the output changing means (33d
), the control signals for functions with the same purpose but different operations are changed to the old unit's control signals between the old unit and the new unit. For example, for fan control, even if the new unit is 3 speed, the old unit is 2 speed. In the case of the second speed, only the second speed control signal is output, and the control signals for different objective functions are not changed.

The input changing means (33e) also includes a model determining means (
When 33c) identifies the slave unit (3c) of the old model unit,
The air conditioning control means (33a) is configured to change the content of the control signal received from the base unit (3a) to the control content of the old unit and take it in. In other words, the base unit (3a) receives the control signal from the old unit. Since the control signal is output, the control signal is read in response to the control signal.

The outdoor unit (2) is also configured to output a model signal to the base unit (3a) when the power is turned on.

Next, control operations in this air conditioner (1) will be explained based on the control flows shown in FIGS. 4 to 6.

First, as shown in FIG. 4, when the power is turned on, the outdoor unit (2) transmits a model code signal to the base unit (3a) in step STI. The base unit (3a) receives this model code signal, and each slave unit (3b), (3c)
sent to. After that, the process moves to step ST2, and the main device (
3a) and handsets (3b) and (3c) determine whether the sending address is 1 or not. If the sending address is 0, the process goes to step ST3; if the sending address is 1, the process goes to step S.
I will move on to T4. Then, in step ST3, the model classification means (33b) of the main unit (3a) outputs a classification signal indicating the new model unit, and the air conditioning control means (33
a) sends the model signal to each handset (3b).

(3c) etc., while in step ST4, the model classification means (33b) outputs a classification signal indicating whether each child unit (3b) or (3c) is a new model unit or an old model unit, and the model classification means (33b) transmits the model signal to the base unit (3a) and other slave units (3b).

Output to (3c).

Thereafter, the process moves from steps ST3 and ST4 to step T5, where it is determined whether or not standby has been completed.
Check the model signals of c) and return to step STI until the model signals of all slave units (3c) are received. On the other hand, when all model signals are received, the process moves from step ST5 to step ST6, and the master unit (3a) and slave units (3b), (3c
) are all new units using model discrimination means (3).
3c) is determined. If all of the units are new models, the process moves to step ST7, where the control routine for the new model unit is performed.If even one slave unit (3c) is identified as an old model unit, the process moves from step ST6 to step ST8, where the control routine for the new model unit is performed. Now we move on to the control routine.

In the control routine of this new unit, the main unit (3
The output changing means (33d) of a) does not change the control signal,
Further, the input changing means (33e) of the slave device (3b) does not change the control signal either.

Therefore, based on the control signal from the remote controller (4), the base unit (
3a) directly sends the control signal to the slave unit (3b).

(3c), and the air conditioning operation is controlled.

In addition, in the control routine for the old unit, the output changing means (33d) changes the control signal to the control signal for the old unit. For example, when controlling an indoor fan, even if the new unit is at 3 speed, the old unit is at 2 If it is fast,
The air conditioning control means (33a) changes to a control signal for only 2nd speed.
outputs. In the handset (3c) of the old model unit, the air conditioning control means (33a) directly receives the control signal and controls the air conditioning operation. In addition, in the slave device (3b) of the new model unit, the input changing means (33e) changes the control signal to the control content of the old model unit and reads it.
The new unit is operated and controlled in the same way as the old unit.

At that time, the main unit (3a) is controlled as a new type unit,
For example, the indoor fan is controlled to three speeds.

Furthermore, for functions that are not present in the old model unit, such as louver control, the output changing means (33d) does not change the control signal, and the slave unit (3b) of the new model unit performs louver control.

Next, a specific control operation for model discrimination will be explained based on FIG. 5.

First, when the power is turned on, it is determined in step STI 1 whether or not the base unit (3a) is the base unit (3a) in each indoor unit, and if it is the base unit (3a), the process moves to step STI 2.
It is determined whether or not the outdoor unit (2) is a pair type with only the base unit (3a), and if it is a pair type, the base unit (3a) is a new type unit, so the process moves to step STI 3 and the above-mentioned steps are performed. Now we will move on to the control routine for the new unit.

In step 5TI2, if it is not a pair type, the determination is No, and the process moves to step 5T14, where the main device (3
It is determined whether or not it is a twin type equipped with a) and one slave unit (3b), and if it is a twin type, in step 5T15, 2
Base unit (3b).

In case of triple type with (3c), Ste.tube 5T
Moving on to 16, the slave unit (3b) of the old model unit,
It is determined whether (3c) exists.

If the slave units (3b) and (3c) are all new units, if there is even one slave unit (3b) or (3c) of the old model in the new unit control routine of step 5T13, step STI 7 is executed. This will move on to the control routine of the old model unit.

On the other hand, if it is determined in step STI 1 that the slave unit (3b) or (3c) is a new model unit, the process moves to step 5T18, where it is determined whether it is a twin type or a triple type in the same manner as in step 5714. Then, in the case of the twin type, the process moves to step 5T19, and in the case of the triple type, the process moves to step 5T20.
0, the base unit (3a) and other slave units (3b),
(3c) It is determined whether or not the unit is an old model unit. If it is a new model unit, the process moves to step 5T13; if an old model unit exists, the process moves to step 5T17, and the process moves to each control routine as described above.

Also, in FIG. 6, it is determined whether the outdoor unit (2) is a new model unit or an old model unit. When the power is turned on, it is determined in step 5T31 whether the outdoor unit (2) is an old model unit or not. ) is determined, and if it is a new unit, the $1 jra of the new unit in step 5T32 is determined.
In the routine, step 5T33 in case of old model unit.
This will move on to the control routine for the old model unit.

Therefore, the parent device (3a) and each child device (3b).

(3c) outputs a model signal, and if there is a slave unit (3c) of an old model unit, the control signal is changed to one corresponding to the function of the old model unit and the control signal is output or taken in. Even when indoor units with different functions coexist, each slave unit (3b) and (3c) can be accurately and centrally controlled, and in particular, the slave unit (3c) of the old model unit will not malfunction, making it comfortable. air conditioning. Furthermore, there is a handset (3b) with different functions.

Since (3c) can coexist, slave devices can be added or changed, and the degree of freedom in installation can be improved.

In addition, since the content of the control signal is changed for the same purpose function that operates differently between the new unit and the old unit, the functions added to the old unit will operate in the slave unit (3b) of the new unit, and the function will be changed. Accurate centralized control can be performed without any degradation.

In this embodiment, one or two slave units (3b) are used.

(3c) has been described, but it may also include three or more slave units.

Further, the first air conditioning unit and the second air conditioning unit are not limited to new and old units, but may be units having different functions.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of the present invention. 2 to 6 show one embodiment of the present invention, FIG. 2 is a general system diagram of the air conditioner, and FIG. 3 is a circuit block diagram thereof. FIG. 4, FIG. 5, and FIG. 6 are control flow diagrams showing control operations for model discrimination, respectively. (1)...Air conditioner (2)...Outdoor unit (3a)...Main unit (3b), (3c)...Slave unit (4)...Remote control (33a)... Air conditioning control means (33b)...Model classification means (33c)...Model discrimination means (33d)...Output change means (33e)...Input change means and 2 others

Claims (2)

[Claims] (1) A main unit (3a) consisting of a first air conditioning unit equipped with a main function for performing a predetermined air conditioning operation and an additional function different from the main function, and a second air conditioning unit equipped with only the first air conditioning unit or the main function.
A plurality of child units (3b) each consisting of one of the air conditioning units, (
3c),... In the air conditioner equipped with the above-mentioned parent unit (3a) and each slave unit (3b), (3c),...
・In addition to transmitting and receiving control signals to each other,
Each slave unit (3b)
), (3c), . . . are centrally controlled to control air conditioning operation (33a), (33a), . 3c),...
・When outputting a preset control signal, a model signal corresponding to each air conditioning unit is sent to each air conditioning control means (
Model classification means (33b), (33
b), . . . and a base unit (
3a) and the slave units (3b), (3b), . . . and whether the other slave units (3c), (3c), . . . output the model signal of the second air conditioning unit. Model discrimination means (33c), (33c), etc., which are provided in the base unit (3a), and model discrimination means (33c) for discriminating the
When c) determines the slave unit (3c) of the second air conditioning unit,
output changing means (3) for changing the content of the control signal output by the air conditioning control means (33a) to the control content of the second air conditioning unit;
3d) and the slave units (3b), (3b), etc. consisting of the first air conditioning unit.
c), (33c), ... are slave units of the second air conditioning unit (
3c), the air conditioning control means (33a), (33
a) Input changing means (33e), (33e), etc., which take in the content of the control signal of the base unit (3a) received by the main unit (3a) as the control content of the second air conditioning unit. An operation control device for an air conditioner characterized by: (2) In the operation control device for an air conditioner according to claim (1), the output changing means (33d) of the main unit (3a) comprises:
An operation control device for an air conditioner, characterized in that it is configured to change the content of a control signal for a same purpose function that operates differently in a first air conditioning unit and a second air conditioning unit.