JP2013029258A - Air conditioner system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner system that includes an indoor unit and a plurality of wired remote controllers, and controls power consumption of the remote controllers within the power supply capacity of a remote controller driving power supply, in consideration of operation states of the remote controllers, in managing power to be supplied to all the wired remote controllers from the indoor unit.SOLUTION: A remote controller control part transmits data on an operation instruction to notify a power supply management indoor unit of a key operation in receiving the key operation. In receiving the data on the operation instruction, an indoor unit control part of the power supply management indoor unit updates an item of back light luminance of a power supply management table so that a total current consumption value of group remote controllers corresponding to the back light luminance of the power supply management table is equal to or less than a maximum current value determined in advance by a power supply part, and transmits data on the updated luminance state to the group remote controllers. The remote controller control part controls the luminance of a back light according to the data on the luminance state, in receiving the data on the luminance state from the indoor unit control part of the power supply management indoor unit.

Description

  The present invention relates to an air conditioner system including an outdoor unit, an indoor unit, and a plurality of wired remote controllers, and more particularly to management of power supplied from an indoor unit to a wired remote controller.

  Using a common two-wire cord for the power line and signal line, feeding power to the remote control from one indoor unit will facilitate on-site wiring work and improve flexibility in wiring construction. An intended air conditioner system has been disclosed.

  In this air conditioner system, a plurality of indoor units and a remote controller are connected by a crossover communication line. The indoor unit is provided with address setting means for setting an address value for identifying the device, and the power supply for remote control operation of the indoor unit in which the address value set by the address setting means is a preset power supply permission address value. The power supply means is turned on, and there is only one indoor unit that supplies power to the remote controller (see, for example, Patent Document 1).

  On the other hand, on the premise of such a system, there is an air conditioner system including a plurality of remote controllers and several to tens of indoor units. In the case of such an air conditioner system, a group remote controller capable of managing indoor units in groups is used. However, when the number of indoor units is large, the group remote controller may be several to about 10 units.

  As described above, since power is supplied to all remote controllers from one indoor unit, the power source for driving the remote controller is designed on the assumption that the maximum number of remote controllers can be connected. In recent years, with a focus on operability, a backlight is provided on the display of the remote control, and the power supply that drives the remote control is designed in consideration of the increase in current caused by this backlight, so it is proportional to the increase in the number of remote controls. As a result, there is a problem that the power source becomes larger and the cost increases.

  However, remote controls used in air conditioner systems are generally operated only a few times a day, such as power on / off and set temperature changes, and all remote controls are used at the same time. It is rare. As described above, the remote controller driving power source provided in the indoor unit does not necessarily have a capacity for simultaneously driving all the remote controllers to which the maximum number is connected. For this reason, an air conditioner system that can reduce the cost by reducing the size of the power source for driving the remote controller has been desired.

JP-A-9-133395 (page 3-4, FIG. 1)

  The present invention solves the above-mentioned problems, includes an indoor unit and a plurality of wired remote controllers, and in the management of power supplied from the indoor unit to all wired remote controllers, considering the operation status of the plurality of remote controllers provided, It is an object of the present invention to provide an air conditioner system that controls a remote controller so that the power supply capacity of the remote controller drive power supply is less than or equal to.

In order to solve the above-described problems, the present invention includes a plurality of indoor units, and a plurality of wired remote controllers that are connected to the indoor units and include a backlight. ,
The indoor unit includes a power supply unit that supplies power to the wired remote controller, a power supply indoor unit that supplies power to at least one wired remote controller, an indoor unit controller that communicates with the wired remote controller, and the wired remote controller A power management indoor unit that includes a storage unit that stores a power management table that stores the luminance state of the backlight each time,
The wired remote control includes a key input unit for inputting key operations, a display unit, the backlight used in the display unit, and a remote control control unit that controls these and communicates with the indoor unit control unit. ,
The remote control unit, when receiving the key operation via the key input unit, transmits operation instruction data notifying the power management indoor unit of the key operation,
When the indoor unit control unit of the power management indoor unit receives the operation instruction data, a total current consumption value of the wired remote controller corresponding to the brightness state is equal to or less than a maximum current predetermined by the power source unit. Updating the brightness state of the power management table, and transmitting the updated brightness state data to the wired remote controller,
When receiving the brightness state data from the indoor unit control unit of the power management indoor unit, the remote control unit controls the backlight brightness according to the content of the brightness state.

The invention according to claim 2 of the present invention stores the value of the operating timer indicating the lighting time of the backlight in association with the wired remote controller in the power management table,
When the indoor unit control unit of the power management indoor unit receives the operation instruction data from the wired remote controller, the in-operation timer in the power management table corresponding to the wired remote controller that has transmitted the operation instruction data Update the value to the initial count value of the maximum lighting time of the backlight,
The value of the operating timer is updated in accordance with the passage of time, and the brightness state of the wired remote controller in which the maximum lighting time has elapsed in the power management table is updated so as to reduce the brightness of the backlight. The updated brightness state data is transmitted to the wired remote controller.

By using the above means, according to the air conditioner system of the present invention,
The invention according to claim 1 is reviewed and updated so that the brightness state of each backlight in the power management table is limited to the maximum current value of the power supply of the entire wired remote controller when the key operation of the wired remote controller is performed. Since the backlight luminance control of the wired remote controller is performed according to the updated contents, the backlight luminance can be controlled to be always within the maximum current value of the power supply and as high as possible.

  In the invention according to claim 2, a wired remote controller in which key operation is completed is provided in the power management table by providing a timer during operation of each wired remote controller to reduce the brightness of the lit backlight when a predetermined time has elapsed. The current consumption of the backlight can be reduced, and a current capacity usable for the wired remote controller to be operated next can be secured.

It is a block diagram which shows the Example of the air conditioning system by this invention. It is a block diagram which shows the Example of the indoor unit of the air conditioner system by this invention. It is a block diagram which shows the Example of the remote control of the air conditioner system by this invention. It is explanatory drawing explaining the power supply management of the remote control by this invention. It is explanatory drawing explaining the power management table of the remote control by this invention. It is a flowchart explaining the process of the remote control part by this invention, and an indoor unit control part.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail as examples based on the attached drawings.
The feature of the present invention is that the indoor unit manages the operation status of each remote control, and indicates the brightness of the backlight of the remote control when the indoor unit is operating so that the current capacity for the remote control is not exceeded when the remote control operations overlap. It is to be.

  FIG. 1 is a block diagram showing an embodiment of an air conditioner system according to the present invention. This air conditioner system includes an outdoor unit 30, a plurality of indoor units 20a, 20b, 20e... 20x, and group remote controllers 10a, 10b, 10c, and 10d including wired remote controllers. The outdoor unit 30 and each indoor unit are connected by communication (main communication) via the communication line 1, and each indoor unit and each group remote controller are connected by communication (remote control communication) via the remote control connection line 2. In addition to the communication signal, the remote control connection line 2 is supplied with power for driving each group remote controller from a predetermined specific indoor unit (power supply indoor unit).

  FIG. 2 is a block diagram showing an embodiment of an indoor unit of an air conditioner system according to the present invention. Since this indoor unit 20a has the same configuration as other indoor units, the indoor unit 20a will be described as a representative.

The indoor unit 20a performs data communication with each group remote controller via the remote control connection line 2 and also superimposes a power source on the remote control connection line 2 and a room temperature detection unit 27 that detects the indoor temperature. A storage unit 25 that stores data, a communication unit 22 that communicates with the outdoor unit 30 and other indoor units, a blower fan motor 23, a stepping motor 24 for up and down wind direction plates, and an indoor unit control unit 26 that controls them A power supply unit 28 that inputs the AC power supply 4 and outputs a DC power supply Vcc, and a remote control power supply that switches whether the DC power supply Vcc is supplied to the communication / power supply superposition unit 21 as a power supply for driving each group remote controller And a switch 29.
The remote control connection line 2 is composed of a pair of electric wires. One electric wire is used as an earth wire (ground wire) for the device, and a communication signal and a DC power source Vcc are applied to the other electric wire.

  Further, by closing the remote control power supply switch 29, the driving power for each remote control can be supplied to the remote control connection line 2. As described above, the remote control power supply switch 29 of a specific indoor unit among the plurality of indoor units, in this embodiment, the indoor unit 20a is closed, and the remote control power supply switch 29 of the other indoor units is opened. Since the state of the remote controller power supply switch 29 can be read by the indoor unit control unit 26, the indoor unit whose switch is closed by the installation personnel manages the power of all group remote controllers. The indoor unit that manages the power supply is a power management indoor unit.

The plurality of indoor units and the plurality of group remote controllers each include the destination and the source address in the data to be transmitted, and the device that has received this data uses the predetermined address to determine the destination. It is possible to select data to be received by confirming whether or not is addressed to the user. The power management indoor unit that manages the power supply of the group remote controller ignores the destination included in the received data and monitors the data transmitted by all the group remote controllers.
For example, data transmitted from the group remote controller includes a destination address, a transmission source address, a transmission item (for example, an instruction to the indoor unit), contents of the transmission item (for example, operation start of the destination address # 10), and the like. On the other hand, from the power management indoor unit, the destination address, the source address, the transmission item (for example, an instruction to the group remote controller), the content of the transmission item (for example, the backlight luminance state of the destination address # 20 to high luminance, medium luminance, off) ) Etc. Therefore, the device that receives these data can receive the data addressed to itself, determine the item to be processed according to the transmission item, and execute the process according to the content of the transmission item.

  When the indoor unit control unit 26 of the power management indoor unit receives the “operation instruction” data transmitted from each group remote controller in which the key operation is performed, the current consumption in each group remote controller is the maximum value on the design value, for example, Maximum value: The power management table described later is updated so as not to exceed 1.2 amperes, and the group remote controller that needs to be restricted in accordance with the contents of the updated table is turned on with high-brightness / middle-brightness / off. Transmits instruction data of “luminance state”. It also manages the time interval of key operations that are operated continuously at the same time, and for 15 seconds after the key operation is performed, the “brightness state” instruction data with the backlight turned off for the group remote controller without the next key operation Send. If there is a next key operation within 15 seconds, the corresponding group remote controller can turn on the backlight for another 15 seconds.

FIG. 3 is a block diagram showing an embodiment of a remote controller of an air conditioner system according to the present invention. Since the group remote controller 10a has the same configuration as other group remote controllers, the group remote controller 10a will be described as a representative.
The group remote controller 10a transmits the instruction data to each indoor unit and receives the communication data from each indoor unit and the remote controller connection line 2 from the key input unit 12 for inputting the state of the key operated by the user. A communication / power source separation unit 16 that separates and extracts a DC power source Vcc that drives the group remote controller 10a, a display unit 11, a backlight 17 that illuminates a reflective liquid crystal panel (not shown) of the display unit 11, and a storage unit that stores data 13 and a remote control unit 15 including a microcomputer with a program for controlling them.

  When receiving a key operation via the key input unit 12, the remote control unit 15 converts the key code corresponding to the key into the key code, receives the key operation content, displays it on the display unit 11, and displays “operation instruction” data. It is transmitted to the indoor unit that is the target of the operation instruction. Since the transmitted data is also received by the power management indoor unit, the backlight is illuminated with high brightness / medium brightness from the indoor unit control unit 26 of the power management indoor unit that was monitoring the data of this “operation instruction”. When the data indicating the “luminance state” to be turned off / in is returned, the remote controller 15 controls the backlight 17 according to this instruction.

  FIG. 4 is an explanatory diagram for explaining power management of the remote controller according to the present invention. FIG. 4A shows an example of equal control for equally managing group remote controllers operated simultaneously, and FIG. 4B gives priority to the group remote controller that started operation later among the group remote controllers operated simultaneously. In this case, the push remote control priority to be managed is shown. Further, in FIG. 4, the passage of time is divided into t0 to t10.

  The vertical direction of FIG. 4 is (1) the group remote controller 10a to (4) the backlight on / off of the group remote controller 10d, and (5) the total current consumption is the total current consumption in each of these four group remote controllers. Show. Moreover, the horizontal direction has shown time. T1 indicates a certain period of time, and T2 indicates a state immediately after a key operation of any group remote controller is performed immediately after T1, and the luminance state of the backlight 17 is updated by this key operation. T3 and T4 have a similar relationship.

  In FIG. 4, “high” indicates that the backlight 17 is lit with high brightness, “medium” indicates that the backlight 17 is in medium brightness, and “off” indicates that the backlight 17 is turned off. Show. Each group remote controller consumes 0.5 amperes when “high”, 0.3 amperes when “medium”, and 0.05 amperes when “off”.

  The indoor unit control unit 26 of the power management indoor unit includes the power management table described above in the storage unit 25, and each group remote controller in the power management table at the timing of receiving the “operation instruction” data transmitted from each group remote controller. By updating the item of the brightness status of the group and comprehensively managing the “brightness status” of all group remote controllers in the power management table, the total current consumption of all group remote controllers will not exceed the design maximum current value Yes. The updated “brightness state” data is transmitted to each group remote controller, and each group remote controller changes the luminance of the backlight 17 according to this luminance state. FIG. 4 illustrates the principle of adjusting the luminance of the backlight 17 so that the total current consumption of all group remote controllers is within the maximum current value. For this reason, the brightness state of each group remote controller is managed by the power management table. The contents of the power management table will be described later in detail.

The case of the equal control in FIG.
At t0 in FIG. 4, no key operation is performed on all group remote controllers, and all the backlights 17 are turned off. Therefore, 0.05 ampere × 4 units and the total current consumption is 0.2 ampere. Here, when an operation is performed with the group remote controller 10a and the group remote controller 10b, the two group remote controllers are not limited, that is, the total current consumption is 1 even if the backlights 17 to the two group remote controllers are operated with high brightness. .1 ampere, which does not exceed 1.2 amperes of current capacity, so that both remote controllers operate the backlight 17 with high brightness during the period t1.

  On the other hand, at t4, the group remote controllers 10a and 10c are already driven with high luminance. If the group remote controller 10b is operated at this time, if the three group remote controllers are set to high luminance, the total current consumption is 1.55. Amps are needed. This cannot be realized because the current capacity exceeds 1.2 amperes. Next, when all the three group remote controllers are set to medium luminance, the total current consumption is 0.95 ampere, which is within the current capacity, and thus the data on the luminance state is transmitted to the three group remote controllers. This state is t5.

  Here, when the operation of the group remote controller 10d is further performed, the total current consumption is 1.2 amperes even if all the group remote controllers are set to the medium luminance, so that the data on the luminance state of the medium luminance is transmitted to all the group remote controllers. . This state is t6.

  On the other hand, when the state of t7, that is, when the group remote controllers 10b, 10c, and 10d are in the middle luminance state, when the key operation of the group remote controller 10c is finished next, only two group remote controllers are in the key operation. Therefore, as with t0, these two group remote controllers can have high brightness. This state is t8. The case where the key operation is completed indicates a case where the next key is not pressed for a predetermined time, for example, 15 seconds after a key is pressed, and the key is continuously pressed within this time. If not, the power management indoor unit determines that the operator does not intend to continue the operation. Therefore, the backlight 17 is turned on for a predetermined time. This time management will be described in detail later.

Next, the case of the rear push remote control priority control in FIG. 4B will be described.
In the case of the push remote control priority, the key that is pressed after the other group remote control that has already been pressed, that is, the key that was pressed first on the corresponding group remote control when instructing something, is the key. Since the probability of being pressed is high, the backlight is turned on with priority given to the operability of the group remote controller for the key that was pressed after that. Whether to adopt the boost remote control priority control or the equal control is determined by the specifications of the air conditioner system.

  Since the equalization control and the push-back remote control priority control are different in part, the different parts will be described. t5 and t7 are the different parts. In the case of the push-push remote control priority control in FIG. 4B, if this group remote control is a key operation pushed later than another group remote control when the group remote control 10b is operated, The luminance of the backlight 17 is set higher than that of other group remote controllers.

  At t5, the group remote controllers 10a, 10b, and 10c cannot all be set to high brightness, but the last-operated group remote controller 10b is set to at least high brightness. In the case of t5, if the group remote controller 10b is set to high luminance and the other two group remote controllers are set to medium luminance, the total current consumption is 1.15 amperes, which is less than the maximum current capacity. Therefore, the brightness state instruction data is transmitted to each group remote controller.

  Similarly, in the case of the push-back remote control priority control in FIG. 4B, the instruction data of the brightness state in which only the group remote controller 10d operated last at t7 has high brightness and the group remote controls 10b and 10c have medium brightness is displayed for each group. Send to remote control.

Next, a more detailed operation will be described using the power management table of FIG.
FIG. 5 is an explanatory diagram for explaining the power management table of the remote controller according to the present invention. This table is stored in the storage unit 25 of the power management indoor unit (indoor unit 20a), and is updated each time a key operation of each group remote controller is performed. The items in the horizontal direction of the power management table correspond to the group remote controller 10a to the group remote controller 10d and the total current consumption thereof, and the items in the vertical direction correspond to the current “in-operation timer”, the current “luminance state”, and the luminance state. The “current consumption” is defined in advance. Therefore, this current consumption value may be used instead of the “brightness state”, but is added for the purpose of explanation in this embodiment.

  As described above, the “brightness state” defines the combination of the luminances of the backlights 17 of the respective group remote controllers and limits the current consumption. The luminances of the backlights 17 are defined as high luminance, medium luminance, and extinguishing. Yes. The “in-operation timer” is a time estimated that the user will continue to operate, and during this time, the backlight 17 is lit at a high or medium luminance. When the indoor unit control unit 26 receives the operation instruction data by the first key operation, the indoor unit control unit 26 sets the operation timer to 15 seconds (the initial count value of the maximum lighting time of the backlight 17). This count value is decreased, and when it becomes 0, data on the luminance state indicating the extinction is transmitted to the corresponding group remote controller.

  If this operation timer is in operation (when it is a value other than zero), 15 seconds is set again. As described above, every time a key operation is performed on each group remote controller, the “operation instruction” data is transmitted from the group remote controller. Therefore, the indoor unit control unit 26 of the power management indoor unit that has received this data performs power management. In the table, set the item contents of the timer during operation of the corresponding group remote controller to 15 seconds.

  5 (1) shows the state of T1 when the equalization control and the push-back remote control have priority, FIG. 5 (2) shows T2 at the time of the equalization control, and FIG. 5 (3) shows T2 when the boosting remote control has priority. (4) shows T3 during equal control, and FIG. 5 (5) shows T4 during equal control. Note that T1 to T4 are timings at certain moments defined in FIG. 4 in order to explain the state of each group remote controller in this embodiment.

  At the time T1 when priority control and boosting remote control are prioritized in FIG. 5 (1), the group remote controller 10a to group remote controller 10d in the power management table have operating timers of 9 seconds, 0 seconds, 5 seconds, 0 seconds, and brightness. The state is high brightness, off, high brightness, off, and the current consumption (ampere) is 0.50, 0.05, 0.50, 0.05, and the total current consumption is 1.10 amps. Yes.

  When the “operation instruction” data is transmitted from the group remote controller 10b in the above state, the indoor unit control unit 26 of the power management indoor unit that has received the data writes 15 seconds in the item of the operating timer of the group remote controller 10b. As described above, the total current consumption of the group remote controller is calculated so that it does not exceed 1.2 amperes, and the “medium luminance” derived from this calculation result is written in the item of the luminance state. As shown in T2, the power management table is updated, and data indicating the content of the updated luminance state is transmitted to each group remote controller. In FIG. 5 (2), the equalization control T2 shows an example in which the in-operation timer is decreased by 1 second as time elapses.

  Next, T2 when the push-push remote control is prioritized will be described. When the “operation instruction” data is transmitted from the group remote controller 10b in the state of T1 when priority control and boosting remote control are prioritized in FIG. 5 (1), the indoor unit control unit 26 of the power management indoor unit that has received the data Then, 15 seconds is written in the timer item during operation of the group remote controller 10b. Then, high brightness is written in the brightness state item of the group remote controller 10b having the largest timer value during operation, and the total current consumption of the group remote controller is calculated so as not to exceed 1.2 amperes as described above. "Medium brightness" is written in the group remote controller 10a, 10c derived from the calculation result in the item of, and the power management table is updated as shown at T2 in FIG. The data transmission for instructing the content of the brightness state is performed. FIG. 5 (3) shows an example in which the operating timer has decreased by 1 second as time elapses at T2 when the push remote control has priority.

  On the other hand, at T3 at the time of the equal control in FIG. 5 (4), the group remote controller 10a to the group remote controller 10d have the in-operation timer set to 0 seconds, 4 seconds, 1 second, and 8 seconds, and the brightness state is turned off. In addition, the current consumption is 0.05, 0.30, 0.30, 0.30, and the total current consumption is 0.95 amperes.

  When the operating timer of the group remote controller 10c reaches 0 seconds in the above state, the indoor unit control unit 26 calculates the total current consumption of the group remote controller so that it does not exceed 1.2 amps as described above, and is operating. "High luminance" derived from this calculation result is written in the item of the luminance state of the group remote controller 10d having the largest timer value, and the power management table is updated as shown in FIG. Data indicating the content of the updated luminance state is transmitted to the group remote controller. FIG. 5 (5) shows an example in which the in-operation timer is decreased by 1 second as time elapses at T4 of the equal control.

  As described above, when a key operation is performed on each group remote controller, the brightness state in the power management table is reviewed and updated so as to limit it within the maximum current value of the power supply of the entire group remote controller, and according to this updated content Since the backlight luminance control of the group remote controller is performed, the backlight luminance can be controlled to be always within the maximum current value of the power supply and as high as possible.

  In addition, a timer for operating each group remote controller is provided in the power management table for management, and the backlight that is lit is turned off when a predetermined time has elapsed. It is possible to secure a usable current capacity for the group remote controller operated by the user.

  Next, processing operations of the indoor unit and the group remote controller will be described using the flowchart shown in FIG. FIG. 6 (1) shows the process of the group remote controller, and FIG. 6 (2) shows the process of the indoor unit. Note that ST shown in FIG. 6 represents a step, numbers following the ST represent a step number, Y represents Yes, and N represents No.

  In FIG. 6 (1), the remote control control unit 15 confirms whether or not a key operation has been performed via the key input unit 12 (ST1). When there is a key operation (ST1-Y), the operated key is received and processed, that is, converted into a key code, or contents corresponding to the key code are displayed on the display unit 11. Further, the processed content is transmitted as operation instruction data to the corresponding indoor unit (ST5). Then jump to ST1.

  On the other hand, when there is no key operation (ST1-N), it is confirmed whether there is reception data transmitted from the indoor unit and received via the communication / power source separation unit 16 (ST2). If there is no received data (ST2-N), the process jumps to ST1. When this received data is present (ST2-Y), it is confirmed whether the received data is in a luminance state (ST3). As described above, this indicates a case where the destination address included in the received data is addressed to itself, the transmission item is an instruction to the group remote controller, and the content of the transmission item is in the backlight luminance state. If the received data is not in the luminance state (ST3-N), the process jumps to ST1. When the received data is in the luminance state (ST3-Y), the backlight 17 is controlled corresponding to the luminance state. Then, jump to ST1.

  6 (2), the indoor unit control unit 26 confirms whether there is main communication data via the communication unit 22 (ST21). If there is main communication data (ST21-Y), processing according to the received data, for example, if the error data is from the outdoor unit 30, the operation of the indoor unit is stopped (ST25).

  Next, it is confirmed whether the remote control power supply switch is closed (ST28). If the remote control power supply switch is not closed (ST28-N), the process jumps to ST21. When the remote control power supply switch is in the closed state (ST28-Y), the value in the power management table is other than zero every 1 second counted by a timer counter (not shown) provided in the indoor unit control unit 26. The value of the item “in-operation timer” is subtracted (−1) (ST29). Then, the process jumps to ST21.

  On the other hand, when there is no main communication data (ST21-N), it is confirmed whether there is remote control communication data received via the communication / power superimposing unit 21 (ST22). When there is no remote control communication data (ST22-N), the current state is maintained, that is, the standby state or the operation state is maintained (ST26). Then, the process jumps to ST28.

  If this remote control communication data is present (ST22-Y), it is next checked whether the remote control power supply switch is closed (ST23). When the remote control power supply switch is not in the closed state (ST23-N), the destination of the received remote control communication data is checked. Take control. If it is not addressed to the own device, it is ignored and this step is exited (ST27). Then, the process jumps to ST21.

  On the other hand, when the remote control power supply switch is in the closed state (ST23-Y), the “operation instruction” data of the remote control communication data is processed as if the key was pressed, so that the remote control power supply switch corresponds to the remote controller communication data source group remote controller. Write 15 seconds to the item “Timer in operation” in the power management table. Then, the brightness state of the group remote controller in the power management table is considered, that is, the brightness state is determined by distributing the total current consumption so as not to exceed 1.2 amperes, and the power management table is updated. Then, the updated luminance state is transmitted to each group remote controller (ST24). Then, the process jumps to ST27.

In this embodiment, the power supply indoor unit that supplies power to each group remote controller and the power management indoor unit that manages each group remote controller are performed by the same indoor unit. However, the present invention is not limited to this. You may supply and manage with an indoor unit.
In this embodiment, each group remote controller is managed by the power management indoor unit. However, the present invention is not limited to this. A power management table is provided for each group remote controller. It is also possible to monitor the key operation (communication data) of the group remote controller, update the power management table included in the group remote controller, and control its own backlight according to the updated contents.
In the present embodiment, each group remote controller is managed by the power management indoor unit. However, the present invention is not limited to this, and a function in which a specific group remote controller manages all group remote controllers, that is, the power management in the first embodiment. The same functions as the indoor unit may be provided, and each group remote controller may follow the instructions of this specific group remote controller.

In this embodiment, the backlight is controlled to be lit as high as possible within the current capacity. However, for example, if the brightness is fixed by setting or the like, the backlight may be controlled only below the set brightness. Good.
In this embodiment, the backlight lighting time is managed by the power management table in the power management indoor unit. However, the lighting time is not limited to this, and the lighting time is managed by each group remote controller. When the time expires and the light is turned off, the group remote controller may send a backlight turn-off notification to the power management indoor unit, and the power management indoor unit that has received the notification may update the luminance state data in the power management table to be turned off. .
Also, in this embodiment, when the luminance status data in the power management table is transmitted from the power management indoor unit to the group remote controller, the luminance status data is transmitted only to the group remote controller updated in the power management table. The present invention is not limited to this, and all brightness state data in the power management table may be transmitted to all group remote controllers by simultaneous broadcast communication. Each group remote controller that has received this extracts only the brightness state data corresponding to itself and controls the backlight according to this data. As a result, communication traffic can be reduced when the number of group remote controllers to be managed is large.

DESCRIPTION OF SYMBOLS 1 Communication line 2 Remote control connection line 4 AC power supply 10a Group remote control 10b Group remote control 10c Group remote control 10d Group remote control 11 Display part 12 Key input part 13 Storage part 15 Remote control part 16 Communication / power supply separation part 17 Backlight 20a Indoor unit 21 Communication Power supply superposition unit 22 Communication unit 23 Blower fan motor 24 Stepping motor for up / down wind direction plate 25 Storage unit 26 Indoor unit control unit 27 Room temperature detection unit 28 Power supply unit 29 Remote control power supply switch 30 Outdoor unit

Claims (2)

A plurality of indoor units, and a plurality of wired remote controllers that are connected to the indoor units and equipped with a backlight,
The indoor unit includes a power supply unit that supplies power to the wired remote controller, a power supply indoor unit that supplies power to at least one wired remote controller, an indoor unit controller that communicates with the wired remote controller, and the wired remote controller A power management indoor unit that includes a storage unit that stores a power management table that stores the luminance state of the backlight each time,
The wired remote control includes a key input unit for inputting key operations, a display unit, the backlight used in the display unit, and a remote control control unit that controls these and communicates with the indoor unit control unit. ,
The remote control unit, when receiving the key operation via the key input unit, transmits operation instruction data notifying the power management indoor unit of the key operation,
When the indoor unit control unit of the power management indoor unit receives the operation instruction data, a total current consumption value of the wired remote controller corresponding to the brightness state is equal to or less than a maximum current predetermined by the power source unit. Updating the brightness state of the power management table, and transmitting the updated brightness state data to the wired remote controller,
The air conditioner system, wherein the remote control unit controls the luminance of the backlight according to the content of the luminance state when the luminance state data is received from the indoor unit control unit of the power management indoor unit. In the power management table, the value of the operating timer indicating the lighting time of the backlight is stored in association with the wired remote controller,
When the indoor unit control unit of the power management indoor unit receives the operation instruction data from the wired remote controller, the in-operation timer in the power management table corresponding to the wired remote controller that has transmitted the operation instruction data Update the value to the initial count value of the maximum lighting time of the backlight,
The value of the operating timer is updated in accordance with the passage of time, and the brightness state of the wired remote controller in which the maximum lighting time has elapsed in the power management table is updated so as to reduce the brightness of the backlight. The air conditioner system according to claim 1, wherein the updated brightness state data is transmitted to the wired remote controller.

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