JP2708133B2 - Operation control device for air conditioner - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an operation control device for an air conditioner in which the operation of a plurality of air conditioning units is controlled by a single remote control device, and in particular, to a connection relationship. On measures to improve the accuracy of confirmation.

(Prior Art) Conventionally, as disclosed in, for example, Japanese Patent Application Laid-Open No. 60-10323, as an operation control device of an air conditioner, a single remote control device controls the operation of a plurality of indoor units. What is intended to simplify control of an air conditioner is a known technique.

(Problems to be Solved by the Invention) By the way, in such an air conditioner in which the operation of a plurality of air conditioning units is controlled by a single remote control device, a plurality of air conditioning units and a remote control device are used when different installations are performed. When checking the connection relationship with the air conditioning unit, the remote control device sends an address confirmation signal to each air conditioning unit in order, and when a response signal containing a preset redundant signal is received from each air conditioning unit, connection with the air conditioning unit is made. If it is determined that there is a plurality of air conditioning units having the same address, the return signal is an abnormal redundant signal different from the normal redundant signal. Therefore, by receiving such an abnormal redundant signal, it is determined that the address is an error such as a duplicate setting in which the address is duplicated. In this case, although there is no return signal from the air conditioning unit, noise is generated. As a result, an apparently abnormal redundant signal may be generated, and a connection state may be determined even when the signal is not connected.

In addition, even if only one air-conditioning unit is connected, there is a possibility that an erroneous detection that the setting is an overlapping setting may occur.

The present invention has been made in view of such a point, and an object of the present invention is to provide a means for distinguishing between an abnormal redundant signal and an apparent abnormal redundant signal due to noise, so that the remote control device and the air conditioning unit can be separated. An object of the present invention is to improve the accuracy of checking the connection relationship.

(Means for Solving the Problems) To achieve the above object, a first solution is to remotely control the operation of a plurality of air conditioning units (C ₁ ) to (C ₃ ) as shown in FIG. It is intended for an operation control device of an air conditioner equipped with a remote control device (R _C ) for controlling.

A call signal output means for designating addresses of the plurality of air conditioning units (C ₁ ) to (C ₃ ) to the remote control device ( _RC ) and outputting a call signal to the air conditioning unit corresponding to the addresses. (101), a reply for outputting a reply signal including a preset redundant signal to each of the air conditioning units (C ₁ ) to (C ₃ ) when receiving the call signal from the call signal output means (101). signal output means (60C ₁₎ provided - a (60C _3).

Furthermore, in the above remote control device (R _C), that is a normal value for redundant signal in reply signal is set in advance from the reply signal output means _{(60C 1) ~ (60C 3} ) are different abnormal redundant signal The redundant signal detecting means (102) to be detected and, when the detection of the abnormal redundant signal by the redundant signal detecting means (102) is performed a plurality of times in succession, the connection certifying means () for certifying that the air conditioning unit of the designated address is in the connected state. 103).

(Operation) With the above configuration, in the invention of claim (1), the address of each of the indoor units (C ₁ ) to (C ₃ ) is specified by the calling signal output means (101) of the remote control device (R _C ). When the call signal is output, if the indoor unit of the designated address is connected, the air conditioning unit (C ₁ )
(C ₃₎ return signal output means (60C ₁₎ of ~ reply signal including the predetermined redundancy signal from (60C ₃₎ is outputted.

In this case, even if none of the air conditioning units (C ₁ ) to (C ₃ ) is connected to the remote control device (R _C ), an abnormal redundant signal having a value different from the normal redundant signal set above due to noise is generated. It may be output, and by receiving this abnormal redundancy signal, there is a possibility that the air conditioning unit of the specified address is recognized as being connected to the remote control device (R _C ).
In the present invention, the indoor unit (C ₂ ) of the designated address is first specified by the connection qualifying means (103) when the redundant signal detection by the redundant signal detecting means (102) is repeated a plurality of times.
Is recognized as being connected, erroneous detection of a connection relationship that is recognized as being connected even though it is not connected is prevented, and the confirmation accuracy of the connection relationship is improved.

(Example) Hereinafter, an example of the present invention will be described with reference to FIG. 2 and subsequent drawings.

FIG. 2 shows an air conditioner (X) according to an embodiment of the present invention. This air conditioner (X) has a plurality of (three in the figure) indoor units for one outdoor unit (A). This is a multi-type air conditioner in which (B), (B), and (C ₁ ) to (C ₃ ) are connected in parallel.

The outdoor unit (A) includes a compressor (1) and two outdoor heat exchangers (2a) and (2b) that function as an evaporator or a condenser according to the flow direction of the refrigerant. The compressor (1) includes a first compressor (1a) whose capacity is adjusted by an inverter (not shown) capable of variably switching an output frequency, and an unloader (not shown) that performs differential operation depending on pilot pressure. The capacity is fully loaded (for example, 100
%) And a second compressor (1b) adjusted in two stages of an unloaded state (50%) and a second compressor (1b) connected in parallel via a check valve (1c). The discharge side of each of the first and second compressors (1a) and (1b) has a compressor (1
First and second oils in the gas discharged from a) and (1b) are separated and returned to the suction side of compressors (1a) and (1b).
Oil separators (1d) and (1e) are provided.

The high pressure gas line (31) of the refrigerant circuit (3) is connected to the discharge side of the compressor (1), and the low pressure gas line (32) is connected to the suction side. The outdoor heat exchangers (2a) and (2b) are provided in parallel with the compressor (1), and one end of each of the outdoor heat exchangers (2a) and (2b) is a four-way switching valve ( 21a) and gas pipes (21b)
a) and (22b) are switchably connected to the high-pressure gas line (31) and the low-pressure gas line (32),
The liquid tubes (33a) and (33b) of the liquid line (33) in the refrigerant circuit (3) are connected to the other ends of the outdoor heat exchangers (2a) and (2b).
Is connected. Each of the four-way switching valves (21
a) and (21b) are such that when the outdoor heat exchangers (2a) and (2b) function as condensers, the gas pipes (22a) and (22b) communicate with the high-pressure gas line (31). When the outdoor heat exchangers (2a) and (2b) function as evaporators, the gas pipes (22a) and (22b) connect to the low-pressure gas line (32). It is switched to a broken line in the figure so as to communicate. In addition, the four-way switching valve (21a), (2
One port of 1b) is the capillary (23a) and (2a)
Connected to the gas pipes (22a) and (22b) between the four-way switching valves (21a) and (21b) and the low-pressure gas line (32) via connection pipes (24a) and (24b) provided with 3b) Have been.

Further, a gas pipe (22) is connected to the high-pressure gas line (31).
The one-way valves (4) and (4) are provided downstream (inside the indoor unit (B)) from the connection portions of (a) and (22b), and the gas pipes (22a) and (4) are provided in the low-pressure gas line (32). The accumulators (41) are disposed downstream (compressor (1) side) of the connection section 22b). In addition, gas pipes (22a), (22
High pressure gas gas line upstream of the connection in b) (31)
And the low pressure gas line (32) downstream of the connection between the gas pipes (22a) and (22b) and upstream of the accumulator (41), in other words, the discharge side of the compressor (1). The suction side and the suction side are connected by a bypass path (42) for equalizing pressure. The on-off valve (42a) is connected to the equalizing bypass passage (42).
And a flow control capillary (42b).

In addition, each liquid pipe (33a) in the liquid line (33),
(33b) is connected to the receiver (43) so that the respective liquid refrigerants merge with each other, and the receiver (43) is connected to the main liquid pipe (33c) of the liquid line (33). Further, outdoor electric expansion valves (25a) and (25b) are provided in the liquid pipes (33a) and (33b), respectively. The outdoor electric expansion valves (25a) and (25b) Vessel (2a),
(2b) depressurizes the liquid refrigerant when functioning as an evaporator, and adjusts the flow rate of the liquid refrigerant when functioning as a condenser.

Between the downstream side of the one-way valve (4) in the high-pressure gas line (31) on the discharge side of the compressor (1) and the receiver (43), so-called hot gas, which is a high-pressure gas refrigerant, is supplied to the receiver (43). The hot gas bypass line (45) is connected to the hot gas bypass line (45), and the hot gas bypass line (45) is provided with a hot gas on-off valve (45a) and a capillary (45b) for adjusting the flow rate of the hot gas.

On the other hand, each of the high-pressure gas line (31), the low-pressure gas line (32), and the main liquid pipe (33) is extended to the indoor side, and the high-pressure gas line (31) is connected to the high-pressure branch pipe via the flow divider (31a). (31b), (31b),... And the low-pressure gas line (32) are connected to the low-pressure branch pipe (32b),
(32b), ... and the main liquid pipe (33)
are branched into liquid branch pipes (33e), (33e), ... through d), and these branch pipes (31b), (32b), (33e)
Are connected to the indoor units (B), (B) and (C ₁ ) to (C ₃ ).

Each indoor unit (B), (B) and (C ₁₎ ~
(C ₃ ) are identically configured, each having an indoor heat exchanger (5) functioning as an evaporator during the cooling operation, and functioning as a condenser during the heating operation, and an indoor fan disposed close to the indoor heat exchanger (5). (57) and an indoor electric expansion valve (51) for reducing the pressure of the refrigerant during the refrigerant operation and adjusting the flow rate of the refrigerant during the heating operation
And The indoor electric expansion valve (51) is disposed in the liquid branch pipe (33e), and the liquid branch pipe (33e) is connected to one end of the indoor heat exchanger (5).

In the two indoor units (B) and (B) among the indoor units (B), (B) and (C ₁ ) to (C ₃ ), the other end of the indoor heat exchanger (5) is connected to a gas pipe ( It is connected to the high-pressure branch pipe (31b) and the low-pressure branch pipe (32b) via 5a). Opening / closing valves (52) and (53) are provided at the gas pipe (5a) side ends of the high-pressure branch pipe (31b) and the low-pressure branch pipe (32b), respectively. , (53) are opened and closed to switch the indoor heat exchanger (5) between the high-pressure gas line (31) and the low-pressure gas line (32), thereby connecting the indoor heat exchanger (5).
Is configured to open the low-pressure side on-off valve (53) when functioning as an evaporator (during cooling), and open the high-pressure side on-off valve (52) when functioning as a condenser (during heating).

Further, a low-pressure bypass (54) is provided between the liquid branch pipe (33e) and the downstream side of the on-off valve (53) in the low-pressure branch pipe (32b).
The bypass valve (54a) and the capillary (54b) are disposed in the low-pressure bypass passage (54).
A pipe heat exchanger (54c) is formed between the low-pressure bypass passage (54) and the liquid branch pipe (33e), and a flush flow of the liquid refrigerant flowing out of the indoor heat exchanger (5) during heating. It is configured to prevent A high-pressure bypass (55) having a capillary (55a) for adjusting the flow rate is connected between the upstream side of the on-off valve (52) in the high-pressure branch pipe (31b) and the gas pipe (5a). Also, it is configured to bypass the condensed liquid accumulated in the high-pressure branch pipe (31b) or the like during cooling.

The on-off valves (52) and (53) and the bypass paths (54) and (55) are housed integrally in a branch unit (56B) as one kit. Compressor (1), outdoor heat exchanger (2
a), (2b) and the indoor heat exchangers (5), (5), ... are connected by three pipes consisting of a high pressure gas line (31), a low pressure gas line (32) and a liquid line (33). .

On the other hand, each indoor unit (B), (B) and (C ₁ )
(C ₃₎ of, the three indoor units _{(C 1) ~ (C 3} ), the liquid side is connected to join the aforementioned liquid branch pipe (33e) in both liquid collateral flow divider (58b) ing. Further, the gas pipe of the indoor units _{(C 1) ~ (C 3} ) (5a), ... are connected to join the gas collecting pipe (5b) in both the gas collateral flow divider (58a).

The gas merging pipe (5b) branches into a high-pressure gas branch pipe (31b) and a low-pressure gas branch pipe (32b) in the same manner as described above, and each of the gas branch pipes (31b) and (32b) is proud. On-off valves (52), (53) and both bypass paths (5
4) A branch unit (56C) consisting of (55) is provided.

Therefore, unlike the other indoor units (B) and (B), each of the indoor units (C ₁ ) to (C ₃ ) cannot switch the cooling / heating operation individually, and the three units simultaneously perform the cooling or heating operation. It is configured to be able to.

Thus, the refrigerant circuit (3) is configured. That is, a plurality of branch units (56B), (56B) and (56C) are connected in parallel to one outdoor unit (A), and further, each branch unit (56B) and (56B) Each of the single indoor units (B) and (B) is connected, and three indoor units (C ₁ ) to (C ₃ ) are connected in parallel to the branch unit (56C).

In addition, (26) is an outdoor fan arranged close to the outdoor heat exchangers (2a) and (2b), and (44) is a low-pressure gas line (3
This is a suction heat exchanger that exchanges heat between 2) and the main liquid pipe (33c).

Further, various sensors are arranged in the refrigerant circuit (3). That is, (Th1) is the indoor unit (B)
(Th2) is a gas temperature sensor that detects the gas refrigerant temperature of the indoor unit (B),
(Th3) is a room temperature sensor that detects the temperature of the intake air of the indoor fan (57). (Th4) is the outdoor heat exchanger (2a), (2
The liquid temperature sensor that detects the temperature of the liquid refrigerant on the b) side, (Th5) is the gas temperature sensor that detects the temperature of the discharged gas refrigerant on the outdoor heat exchangers (2a) and (2b), and (Th6) detects the outside air temperature (Th7) is a discharge gas temperature sensor that detects the discharge gas refrigerant temperature of the compressor (1), and (HPS) is the compressor (1)
High-pressure pressure sensor that detects the discharge gas refrigerant pressure of the
S) is a low-pressure pressure sensor for detecting the pressure of the suction gas refrigerant of the compressor (1).

Next, FIG. 3 shows a control system of the air conditioner,
(60A) is an outdoor control unit for controlling the operation of the outdoor unit (A), (60B) and (60B) are indoor control units for controlling the operation of each of the indoor units (B) and (B), 60C ₁₎ ~ (60C ₃₎ each indoor unit (C ₁₎ ~
Indoor control unit for controlling the operation of (C _3), (61
B), (61B), and (61C) are branch control units for controlling the operation of each device of the branch units (56B), (56B), and (56C), respectively. the 61C), being adapted to centrally control the operation of the indoor units _{(C 1) ~ (C 3} ).

Also, (R _B ) and (R _B ) correspond to each indoor control unit (60
B), (60B), an indoor remote controller that can remotely send and receive signals, and (R _C ) are the indoor control units (60C ₁ ) to
An indoor remote controller capable of remotely transmitting and receiving signals to (60C ₃ ), wherein the indoor remote controller (R _C ) outputs a control command signal to the branch control unit (61C), and The operation status of the units (C ₁ ) to (C ₃ ) can be grasped while controlling the operations of the units (C ₁ ) to (C ₃ ) in groups or individually.

Next, regarding the configuration of the indoor remote controller (R _C ),
This will be described with reference to FIG. In FIG. 4, (65) is a run / stop button for commanding the operation and stop of each indoor unit (C ₁ ) to (C ₃ ), and (66) is each indoor unit (C ₁ ) to
(C ₃ ) lights up while driving, goes off when stopped,
Operation light that flashes when stopping, (70) an input unit for inputting the operation command for each indoor unit _{(C 1) ~ (C 3} ), (80) the operating state and setting of the indoor units (C ₁₎ This is a display unit for checking conditions and the like.

In the input unit (70), (71) is an operation switching button for setting the operation mode to each of the cooling, heating, cooling / heating automatic, and blow operation modes, and (72) is each indoor unit (C ₁ ).
When group control of ~ (C _3), the air volume, wind direction, individual setting button ON / indoor units and switching the like (C ₁₎ ~ (C ₃₎ for individually setting the flap swing (73) of the device An inspection / test operation button for instructing the distinction between the inspection operation and the test operation at the time of installation. (74) is a command for swinging a flap (not shown) serving as a wind direction changing device or stopping at a desired position. With swing flap /
Off button, (75) is an air volume adjustment button for changing the air volume of each indoor fan (57), ..., and (76) is a display unit (8
Set temperature / timer time display section (84) described later in (0)
(77) is a wind direction adjustment button for adjusting the wind direction in the vertical direction of the flap, and (78) is a switch of the display change button (76) when the set temperature is displayed. When the temperature is adjusted and the timer time is displayed, the timer setting time is adjusted. On the other hand, when the individual setting is performed using the individual setting button (72), the address number of the indoor unit (C ₁ ) to (C ₃ ) to be set is selected. Button for adjusting the set temperature / timer time.

Further, in the display section (80), (81) is an operation mode display section for displaying operation modes such as cooling, heating, cooling / heating automatic operation, air blowing, etc., and (82) is for displaying abnormality contents when the apparatus is abnormally stopped. Abnormal content display section of (83)
Inspection / test run display section that displays which operation mode is selected when the test run button (73) is pressed. (84) displays the set temperature or the number of timer hours according to the switch command of the display switch button (76). Set temperature / timer time display
(85) is centralized in the display unit for displaying to that effect at the time of concentration control to control by concentrating the indoor units _{(C 1) ~ (C 3} ), (86) the set air volume of the indoor fan (57) (87) is a wind direction / swing flap display for displaying the wind direction when the wind direction is set and when the swing flap is set, and (88) is the individual setting button This is an address display section for displaying the address numbers of the indoor units (C ₁ ) to (C ₃ ) currently being set when the indoor units (C ₁ ) to (C ₃ ) are individually set by (72).

Although the description is omitted, the remote control device is standardized, and the configurations of the indoor remote control devices (R _B ) and (R _B ) for controlling the operation of the other indoor units (B) and (B) are also the same as those of the above-mentioned indoor units. It is the same as the remote control device (R _C ).

Next, the air conditioning operation of the air conditioner (X) will be described.

First, when the indoor units (B), (B),... Perform the cooling operation, the two-way switching valve (21) of the outdoor unit (A) is operated.
a) and (21b) are switched to the solid lines in FIG.
a) and (22b) communicate with the high pressure gas line (31). In each of the indoor units (B), (B),..., The high-pressure side on-off valve (52) is closed, and the low-pressure side on-off valve (53) is opened, and the gas pipe (5a) is connected to the low-pressure branch pipe (32b). Communicated. In this state, the high-pressure gas refrigerant discharged from the compressor (1) flows into each of the outdoor heat exchangers (2a) and (2b) and condenses, and the condensed liquid refrigerant passes through the liquid line (33). Flows into the indoor units (B), (B), ..., and the indoor electric expansion valve (51),
(51), after expansion in each indoor heat exchanger (5),
(5), ..., evaporates, flows through the low pressure gas line (32), and returns to the compressor (1).

On the other hand, when the indoor units (B), (B),... Perform the heating operation, the refrigerant flows in the opposite direction to the cooling operation. That is, the four-way switching valves (21a) and (21b) of the outdoor unit (A)
It is switched to the broken line in the figure, and each indoor unit (B),
In (B), ..., the high-pressure side on-off valve (52) is opened and the low-pressure side on-off valve (53) is closed, and the refrigerant from the high-pressure gas line (31) is condensed in the indoor heat exchanger (5). Then, it flows through the liquid line (33), expands in the outdoor electric expansion valves (25a) and (25b), evaporates in the outdoor heat exchangers (2a) and (2b), and returns to the compressor (1).

During the cooling operation, for example, when the open / close state of both on-off valves (52) and (53) in one indoor unit (B) is switched, the heating operation is performed. When the two on-off valves (52) and (53) in the two indoor units (B) are switched, a cooling operation is performed, and a so-called simultaneous cooling and heating operation is performed. At this time, for example, if two of all the indoor units (B), (B),... Are operated in the heating operation and the other one is operated in the cooling operation, the indoor units (B) and (B) in the heating operation The escaping liquid refrigerant is merged by the flow divider (33d) of the liquid line (33), then flows to the indoor unit (B) for cooling operation, evaporates, and returns to the compressor (1) from the low-pressure gas line (32). become.

During this simultaneous cooling operation, the two outdoor heat exchangers (2a) and (2b) operate as an evaporator or a condenser according to the indoor load, and one is operated, and the other is operated. Operation will be stopped.

Here, the indoor unit (C ₁ ) as each air conditioning unit by the remote control device (R _C ) which is a characteristic part of the present invention is described.
(C ₃₎ and the connection, that is, each indoor control unit (60C ₁₎ ~
The control for checking the presence or absence of connection with the (60C _3),
This will be described with reference to the flowchart of FIG.

First, when the power source is turned on, after actuation of the remote control device (R _C), in step S1, and sends a call signal including a pulse signal of predetermined width in the address n, a timer having a predetermined set time T ₁ in step S2 (Not shown) is set, and in step S3, it is determined whether or not a reply signal to the call signal is output from the indoor control unit (for example, 60C ₂ ) at the address n and received by the remote control device (R _C ). . This reply signal includes a normal signal and a redundant signal added to confirm whether the signal is a normal signal,
This redundant signal is set to a predetermined value in advance.

Then, the control, repeated in step S4 until the set time T ₁ of the above-mentioned timer times, when even the time is up does not receive a reply signal, counts the number of times CT (n counter (not shown) in step S5 ) Is set to “1” to perform initial setting.

On the other hand, when the return signal is received in the determination in step S3, the process proceeds to step S6, and it is determined whether or not the return signal includes an abnormal redundant signal that is not a normal redundant signal set in advance. If the signal is not a normal redundant signal, the process directly proceeds to step S9. If the signal is an abnormal redundant signal, the abnormal redundant signal is received a predetermined number of times m in steps S7 and S8.
When the number of consecutive units is equal to or more than (for example, about four times), the process proceeds to step S9, and it is determined that the indoor unit (C ₁ ,...) At the address n is connected.

In the above flow, in step S1, the addresses of the plurality of air conditioning units (C ₁ ) to (C ₃ ) are designated,
A call signal output means (101) for outputting a call signal to the air conditioning unit corresponding to the address is configured. The indoor control units (60C ₁ ) to (60C ₃ ) are configured to output a return signal including a preset redundant signal when receiving the call signal from the call signal output unit (101). It functions as.

Further, in step S6, detects that a different abnormality redundant signal from a redundant signal redundancy signal is preset in the return signal from the indoor control units (reply signal output _{means) (60C 1) ~ (60C} 3) The redundant signal detecting means (102) is configured, and the redundant signal detecting means (10
When the detection of the abnormal redundant signal in 2) is repeated a plurality of times, a connection certifying means (103) for certifying that the indoor unit (C ₁ ,...) Of the designated address is in a connected state is configured.

Therefore, according to the invention of claim (1), when the remote controller (R _C ) specifies the address of each of the indoor units (C ₁ ) to (C ₃ ) and outputs the calling signal, the designated indoor unit (R _C ) is output. for example, when C ₂₎ is connected, the return signal including a normal redundancy signal set in advance from the indoor control unit (reply signal output means) (60C ₂₎ is output.

In this case, when there are a plurality of indoor units (C ₁ ) to (C ₃ ) corresponding to the designated address, for example, both the indoor units (C ₁ ) and (C ₂ ) are set as address n = 2. When the overlap is set, the redundant signal in the return signal becomes an abnormal redundant signal different from the normal redundant signal. However, in the above case, even when no indoor unit is connected, an abnormal redundant signal may be received due to noise. In such a case, the designated indoor unit (C ₂ ) Is not connected to the remote control device (R _C ), but is determined to be connected.

Here, in the present invention, the connection authorization means (103)
When the detection of the abnormal redundant signal by the redundant signal detecting means (102) is repeated a plurality of times (four times in the above embodiment), the indoor unit (C ₂ ) of the designated address is recognized as being in the connected state for the first time. In addition, erroneous detection of the connection relationship as described above does not occur, so that the accuracy of confirming the connection relationship can be improved.

In the above embodiment, the case where the indoor units (C ₁ ) to (C ₃ ) as the air conditioning units are controlled by one remote control device (R _C ) has been described, but the present invention is not limited to such an embodiment. For example, the present invention can be applied to a multi-system in which there are a plurality of air conditioners (X) themselves and these are controlled by one remote control device.

Further, in the above embodiment, as a configuration of the air conditioner,
The outdoor unit (A) and the branch units (56B) are connected by three pipes of a high-pressure gas line (31), a low-pressure gas line (32), and a liquid line (33). ), The cooling / heating switching operation is performed for each
The present invention is not limited to such an embodiment, and can be applied to an air conditioner having a normal gas line and a liquid line. Further, the type of a switching command signal to be switched by a switching button switch (71W) is described. However, the present invention is not limited to the operation mode switching as in the above embodiment.

(Effect of the Invention) As described above, according to the invention of claim (1),
As an operation control device of an air conditioner provided with a remote control device for controlling the operation of a plurality of air conditioning units, the remote control device outputs a call signal by designating an address to each air conditioning unit and outputs a call signal to the call signal. Is detected as an abnormal redundant signal different from the preset normal redundant signal, and if the detection of the abnormal redundant signal is repeated a plurality of times, the air conditioning unit corresponding to the specified address is recognized as being connected. As a result, it is possible to effectively prevent erroneous detection that an air conditioner unit that is not connected is recognized as being connected by an abnormal redundant signal caused by noise, thereby improving the accuracy of connection check. be able to.

[Brief description of the drawings]

FIG. 1 is a diagram showing the configuration of the present invention. 2 and the following drawings show an embodiment of the present invention, FIG. 2 is a refrigerant piping system diagram showing a configuration of an air conditioner, FIG. 3 is a block diagram showing a configuration of a control system of the entire air conditioner, FIG. 4 is a front view showing the appearance of the control panel of the remote control device, and FIG. 5 is a flowchart showing the control contents for checking the connection relationship between the remote control device and the indoor control unit. X ...... air conditioner C ₁ -C ₃ ...... indoor unit (air-conditioning unit) 60C ...... indoor control unit (reply signal output means) R _C ...... remote control device 101 ...... ringing signal output means 102 ...... redundant signal detection Means 103 ... Connection recognition means

Claims (1)

(57) [Claims] 1. An operation control device for an air conditioner, comprising a remote control device (R _C ) for remotely controlling the operation of a plurality of air conditioning units (C ₁ ) to (C ₃ ). the (R _C), by specifying the address of the plurality of air conditioning units _{(C 1) ~ (C 3} ), a call signal output means for outputting a ringing signal to the air conditioning unit corresponding to the address (101) Each of the air conditioning units (C ₁ ) to (C ₃ ) is provided with a return signal output for outputting a return signal including a preset redundant signal when receiving the call signal from the call signal output means (101). Means (60C ₁ ) to (60C ₃ ) are provided, while the remote controller (R _C ) has a redundant signal in the reply signal from the reply signal output means (60C ₁ ) to (60C ₃ ). A redundant signal that detects that the signal is an abnormal redundant signal different from the preset normal value Signal detection means (10
2) When the detection of the abnormal redundant signal by the redundant signal detecting means (102) is repeated a plurality of times, the connection certifying means (10) certifying that the air conditioning unit of the designated address is in the connected state.
3) An operation control device for an air conditioner, comprising: