JP2000146267A - Air conditioning control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To utilize an established air conditioning facility as it is, and easily perform the individual air conditioning control of each tenant. SOLUTION: A controller 2 for controlling them is connected to a heat source machine 11, an outside conditioning machine 12, and a distribution panel 14. A main input device 3 for inputting a standard schedule S1 and a sub-input device 4 for inputting a change schedule S2 are connected to the controller 2. The sub-input devices 4 are provided, corresponding to the groups where indoor machines 13 are classified, and also they are provided so that the user can input the change schedule S2 on one or plural indoor machine 13 belonging to that group in one sub-input device 4. The controller 2 decides a regular schedule S0, and controls the operation and stoppage of the indoor machine 13, etc., through the distribution panel 14, according to the decision.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technology for improving a central air conditioning control system employed in tenant buildings and the like.

[0002]

2. Description of the Related Art For example, in an existing building constructed about 10 to 20 years ago, a central air conditioning control system using a gas absorption chiller / heater or the like as a heat source unit is used. This air-conditioning control system intensively controls the operation / stop of one or a plurality of indoor units (fan coils) arranged in each tenant of a building, and the above-mentioned heat source units and external conditioners. These operating times are typically 8 am
In principle, it is fixed within a fixed time such as hour to 6 pm. Tenant users who wish to operate at other times are operated in such a manner as to apply in advance to an air conditioning manager to operate the target heat source device or the like.

[0003]

However, the conventional air conditioning control system has the following problems. In other words, as described above, if the air conditioning manager needs to go out early or work overtime in order to operate outside regular hours, the labor cost is large. In addition, if the tenant user cannot make an application for overtime operation in advance, there is a problem that the overtime operation is not permitted depending on the convenience of the air conditioning manager.

In such a situation, a reliable method for individually air-conditioning the indoor units of each tenant is to renew the heat source units and the indoor units to a type that can be individually managed in recent years. However, this renewal requires enormous costs. On the other hand, various methods have been proposed for enabling individual air conditioning of each indoor unit while maintaining the conventional central air conditioning equipment, but all of these methods require significant remodeling on the indoor unit side. In particular,
Wiring and the like are required for the number of indoor units, and a great deal of cost is required.

[0005] The present invention has been made in view of the above-mentioned conventional problems, and it is possible to use existing air conditioning equipment as it is and to easily perform individual air conditioning control of each indoor unit. It is intended to provide a system.

[0006]

According to a first aspect of the present invention, there is provided a heat source device for cooling or heating a heat medium, an external air conditioner for ventilation, and a plurality of air conditioners for receiving air from the heat medium and performing indoor air conditioning. In the air-conditioning control system having the indoor unit and the switchboard for controlling the operation / stop of the indoor unit, a controller for controlling these units is connected to the heat source unit, the external controller, and the switchboard. The controller has:
A main input device for inputting a standard schedule which is a standard operation / stop time of the indoor unit is connected, and a change schedule which is a start / stop time for each indoor unit different from the standard schedule is input. Sub-input devices are connected to the groups into which the indoor units are classified, and one or more indoor units belonging to the group in one sub-input device. The controller is provided so that the change schedule for the unit can be input, and the controller determines a regular schedule which is a time for actually operating and stopping each indoor unit based on the input standard schedule and the change schedule. , Operation of each of the indoor units via the switchboard according to the regular schedule.
An air-conditioning control system is characterized in that it is configured to control stop and to control operation / stop of the heat source unit and the external control unit.

It should be noted in the present invention that a controller to which the main input device and the sub input device are connected is provided, and that the heat source unit and each of the indoor units are controlled based on the input standard schedule and change schedule. That is, it is configured to control the operation / stop. And the important point here is that the sub input device is
In addition to being provided corresponding to the group into which the indoor units are classified, one sub-input device is provided so that the change schedule for one or a plurality of indoor units belonging to the group can be input.

There are various methods of grouping the indoor units, for example, for each floor, or for each tenant when the tenant has a plurality of indoor units. Further, all the indoor units can belong to one group with one group. Then, one sub input device is provided for each group. That is, the number of the sub-input devices is equal to the number of groups, not the number of indoor units. Specifically, for example, even when there are ten indoor units, three sub-input devices are installed when the indoor units are divided into three groups, and only one sub-input device is used when the indoor units are grouped into one group. Provide.

The main input device includes, for example, identification information storage means (I
A recognition means for recognizing a D card, a password, and other identification means can be provided. The main input device is configured to be able to input the standard schedule. The standard schedule includes, for example, an operation suspension day and an operation day, a standard operation start time and a stop time on the operation day. And the main input device is
One common schedule may be set for all indoor units, or a plurality of different standard schedules may be set for each indoor unit.

[0010] The sub input device is configured to be able to input the change schedule different from the standard schedule. Further, as described above, one sub-input device is provided for each group, and a configuration is employed in which a change schedule of a plurality of indoor units can be input using one sub-input device.

The sub-input device is provided with a function of specifying an indoor unit whose schedule is to be changed using, for example, identification information storage means (an ID card or the like), a password, and other identification means, which will be described later. Then, the change schedule for the specified indoor unit is configured to be input from the sub input device.

Further, the controller determines the regular schedule, which is the time for actually operating and stopping each indoor unit, based on the standard schedule and the change schedule. This normal schedule is determined by, for example, setting the standard schedule as the normal schedule when the standard schedule is input, and then directly changing the normal schedule when the change schedule is input. be able to.

The controller controls the operation / stop of each indoor unit via the switchboard based on the regular schedule, and also controls the start / stop of the heat source unit and the external conditioner. In this case, for example, when there are a plurality of heat source units and external control units, it is preferable that the controller performs control such as changing the number of operating heat source units or the like to an optimum number according to the number of operating indoor units. . Thereby, energy saving can be achieved.

It is preferable that the controller is provided with a settlement function for storing and totalizing the operation time of each indoor unit and calculating a fuel cost or the like from the total value. This makes it possible to easily calculate the air conditioning cost for each indoor unit. In this case, when a plurality of indoor units are used by one tenant user, an integrated value may be calculated for each tenant.

Next, the operation of the present invention will be described. The air-conditioning control system of the present invention includes the controller, and the controller controls the operation and operation of the heat source unit and the indoor unit.
It is configured to control the stop. The operation and stop timings of the heat source unit and the indoor unit are determined based on the standard schedule and the change schedule as described above.

Therefore, not only the operation control within a so-called fixed time based on the standard schedule but also the operation control of each indoor unit during a time outside the fixed time can be automatically performed by the controller. Therefore, there is no need for the air conditioning manager to constantly monitor the operation of the air conditioning control system, and labor costs can be reduced.

Further, on each indoor unit side, the operation instruction of the indoor unit outside the fixed time can be directly given by the input from the sub input device. This eliminates the conventional influence of the air conditioning manager, and realizes a very smooth operation of the air conditioning control system.

Further, as described above, the sub-input devices are provided for each of the groups, and a single device can input a change schedule for a plurality of indoor units. Therefore, the required number of sub-input devices is significantly reduced as compared with the number of indoor units, thereby reducing capital investment.

Further, in the air conditioning control system, the controller is connected to the switchboard and the heat source unit, and the main input device and the sub input device are provided from the controller. As a result, there is almost no need to modify the existing indoor units, which can also reduce capital investment.

As described above, according to the present invention, it is possible to provide an air conditioning control system that can use existing air conditioning equipment as it is and can easily perform individual air conditioning control of each indoor unit. .

Next, as in the second aspect of the present invention, the controller comprises a main control device and a sub control device which are two control devices connected to each other, and the main control device includes the main control device and the sub control device. The input device is connected to the sub-control device, the sub-input device is connected to the sub-control device, the main control device controls the operation and stop of the heat source device and the external control device, and the sub-control device is controlled via the switchboard. The sub-controller is configured to control the operation / stop of the indoor unit, and the sub-controller receives the standard schedule received from the main input device via the main controller and the change received from the sub-input device. A regular schedule for actually operating / stopping each indoor unit via the switchboard is determined based on the schedule and the indoor unit is controlled according to the regular schedule. In addition to performing the rotation control, the operation status is transmitted to the main control device, and the main control device controls the operation / stop of the heat source unit and the external control unit according to the operation status of the indoor unit. It is preferable that it is comprised as follows.

In this case, the above control contents can be easily realized by the two control devices, the main control device and the sub control device. Further, the control of the indoor unit and the control of the heat source unit and the external control unit are shared by the two control devices. Therefore, each part can be finely controlled.

Further, the main control device controls the heat source unit and the external conditioner according to the operating condition (feedback value or the like) of the indoor unit received from the sub control device. for that reason,
Rational control without excessive operation of the heat source unit can be easily performed. Note that, for example, a sequencer can be used as each of the control devices. The sequencer is a control device capable of performing sequence control, and, as is well known, can sequentially advance each stage of control in a predetermined order.

Further, as in the third aspect of the present invention, it is preferable that the main input device and the sub input device are touch panels having a touch screen built in a display screen. In this case, it is possible to perform a simple operation of pressing the display screen while visually confirming the setting state and the like using the touch panel, and it is possible to perform the input operation reliably and easily in a space-saving manner. Further, a personal computer can be used as the main input device. Also in this case, excellent operability can be realized by using a keyboard, a display, and the like of a personal computer.

According to the present invention, the main input device and the sub input device recognize the identification information from identification information storage means storing identification information set for each indoor unit. It is preferable that a recognition device for identifying the indoor unit is provided based on the recognized identification information. Here, the identification information includes, for example, an ID (identification number), and the identification information storage means includes an ID card that magnetically stores the ID. Further, the above-mentioned identification can be performed only by inputting the password. In addition, it can be performed by using a password and the above ID in combination.

[0026]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First Embodiment An air conditioning control system 1 according to a first embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the air-conditioning control system 1 of the present embodiment receives three heat source units 11 for cooling or heating a heat medium, an external air conditioner 12 for ventilation, and the supply of the heat medium to air-condition an indoor room. This is a central air-conditioning control system having eight indoor units 13 for performing the above-mentioned operations and a switchboard 14 for controlling the operation / stop of the indoor units 13. The heat source unit 11 and the indoor unit 13 are connected by a medium passage 10 for circulating the heat medium.

A controller 2 for controlling these units is connected to the heat source unit 11, the external controller 12, and the switchboard 14. The controller 2 includes the indoor unit 13
A main input device 3 for inputting a standard schedule, which is a standard operation / stop time, is connected, and a change schedule, which is an operation / stop time for each indoor unit different from the standard schedule, is input. The sub input device 4 is connected.

The sub-input devices 4 are provided corresponding to the four groups A to D that classify the indoor units 13, and one sub-input device 4 includes one or more indoor units 13 belonging to the group. Is provided so that the above change schedule can be input. There are a total of eight indoor units, and the grouping is divided into A group, A1, A2, A
3 units belong to B group, B1 and B2
And two indoor units, C1 and C2
, And one indoor unit D1 belongs to the D group.

[0029] The controller 2, based on the standard schedule S ₁ and the rescheduled S ₂ input, determines a regular schedule S ₀ is actually time to operate and stop each indoor unit, the normal schedule According to S ₀ , the operation / stop of each indoor unit 13 is controlled via the switchboard 14, and the start / stop of the heat source unit 11 and the external control unit 12 is controlled.

More specifically, as shown in FIG. 1, the controller 2 is a main sequencer (MP) which is two control devices (sequencers) connected to each other.
LC) 21 and a sub-sequencer (SPLC) 22. The main input device 3 is connected to the main sequencer 21, and the sub input device 4 is connected to the sub sequencer 22.
The main sequencer 21 is configured to control the operation / stop of the heat source unit 11 and the external controller 12, and the sub-sequencer 22 is configured to control the operation / stop of the indoor unit 13 via the switchboard 14.

[0031] The sub sequencer 22 actually driving and stopping each indoor unit on the basis of the change schedule S ₂ received from the standard schedule S ₁ and the sub-input device 4 for receiving the main input device 3 via the main sequencer 21 to determine a regular schedule _{S 0.} The sub sequencer 22 via the switchboard 14 according to the normal schedule S ₀ performs operation control of the indoor unit 13, and transmits the driving condition data F (the feedback value) to the main sequencer 21. On the other hand, the main sequencer 21
Controls the operation / stop of the heat source unit 11 and the external control unit 12 according to the operation state of the indoor unit 13.

In this embodiment, a touch panel having a built-in touch sensor on a display screen is employed as the main input device 3 and the sub input device 4. In particular,
As the main input device 3, one main touch panel is provided, and as the sub input device 4, a total of four touch panels are provided, one for each of the groups A to D.

The touch panel of the sub input device 4 is provided with an ID sensor 45 as a recognition device for recognizing an ID set for each sub (indoor unit) from an ID card that magnetically stores the ID. The indoor unit 13 is specified based on the recognition data of the ID sensor 45. The main touch panel of the main input device 3 is also provided with an ID from the ID card storing the ID of the air conditioning manager.
An ID sensor 35 for recognizing is provided.

Each of the ID cards in this embodiment is a magnetic card, and is of a type in which an ID is stored using magnetism. Each of the ID sensors 35 and 45 is a magnetic reading type sensor. Further, the controller 2 of the present embodiment may be provided with a settlement device 5 for calculating a fuel cost and the like for each sub.

[0035] Detailed description will next be made with reference to the flowchart in block diagram and Figure 2 of Figure 1 the flow of control of the heat source unit 11 and the indoor unit 13 by the input of the standard schedule S ₁ and reschedule S _2. As shown in FIG. 2, the air-conditioning control system 1 according to the present embodiment performs step S <b> 102 (hereinafter, referred to as step S <b> 102).
Simply in) of S102, sends a standard schedule _{S 1} inputted from the main panel 3 from the main sequencer 21 to the sub sequencer 22, S101
To determine a regular schedule _{S 0} in.

[0036] Then, when a change schedule _{S 2} from the sub sequencer 4 is inputted, S103, S1
01, according to the contents, the regular schedule S
Change the contents of ₀ . Thereafter, when there is no input of the rescheduled S _2, at S104, in accordance with the normal schedule S _0, starts the operation of the indoor unit has come operation start time.

The indoor unit operation status data F (feedback value) is, as shown in FIG.
From the main sequencer 21. The data F can be read from the main sequencer 21 to the sub sequencer 22. Then, in S105,
It is determined whether the number of operating heat source units 11 is appropriate. If it is not appropriate, the number of the heat source units 11 that are insufficient in S106 is operated. Specifically, if the number of operating indoor units 13 is three or less, one heat source unit 11 is used. If the number of operating indoor units is four or five, two heat source units 11 are used.
When the number of operating indoor units is six or more, three heat source units 11 are operated.

[0038] Then, in S107, in accordance with the normal schedule _{S 0,} to stop the operation of the indoor unit 13 come down time. Accordingly, in S108 and S109, it is determined whether or not the number of operating heat source units 11 is appropriate.
If not, the excess number of heat source units 11 is operated. The appropriate operating number is as described above.

Next, the input procedure from the main input device (main touch panel) 3 will be described with reference to the flowchart of FIG. 3 and the screen images of FIGS. As shown in FIGS. 3 and 5, in the main touch panel 3, first, in S201, an initial screen G1 (FIG. 5) is displayed and an ID can be accepted. On the other hand, the air-conditioning manager can read the ID of his or her own ID card by approaching the ID sensor 35 of the main touch panel 3.

Next, the main touch panel 3 is switched to S20
In step 2, it is determined whether the read ID is correct, that is, whether the ID belongs to a registered air conditioning manager. If the ID is incorrect, the screen returns to the initial screen G1 (S201) again.
If the ID is correct, a password input screen G2 (FIG. 6) is displayed in S203, and input of the password is enabled. On the other hand, the air-conditioning administrator enters his password on the numeric keypad G2 displayed on the touch panel.
0 can be input by directly touching it with a finger.

Next, the main touch panel 3 is switched to S20
In step 4, it is determined whether the input password is correct, that is, whether the password belongs to a registered air conditioning manager. If the password is incorrect, enter the password input screen G again.
2 (S203). If the password is correct,
In S205, a selection menu screen G3 (FIG. 7) from which a plurality of processing modes can be selected is displayed.

In the selection menu screen G3, the system setting mode (S210), the standard schedule setting mode (S220), and the operation status confirmation mode (S23)
0), external controller / heat source device setting monitor mode (S240),
Six modes, a password confirmation mode (S250) and a charge settlement confirmation mode (S260), can be selected. The system setting mode (S210) is for setting calendars required when setting standard schedules, etc.
This mode is for registering indoor unit users (tenants), assigning indoor units to groups, setting IDs, and the like.

The standard schedule setting mode (S22)
0) is a mode for registering a common schedule for all indoor units. Specifically, various settings can be made by operating the standard schedule screen G4 shown in FIG. First, by inputting the operation start time and the operation stop time of the indoor unit for each day of the week using the numeric keypad G40, the standard air conditioning time for each day of the week can be set.

By pressing the holiday setting 45, a screen for inputting a standard holiday or the like for suspending the air conditioning control system 1 all day is displayed, and the setting can be made. The data input in this mode is the standard schedule S ₁
Is transmitted as described above, and serves as a reference for the operation / stop control of the indoor unit and the like.

The operation status check mode (S230) is as follows.
This is a mode for obtaining information about the operating state of each indoor unit 13, that is, whether each indoor unit 13 is operating or stopped. Further, in this operation check mode, it is possible to output an integrated value of the operation time of each indoor unit, fuel cost, and the like.

The external control device / heat source device setting monitor mode (S
240) is a mode for setting whether the operation of the heat source unit 11 and the external conditioner 12 is to be performed automatically or manually, and for monitoring the operation status of these units. The password confirmation mode (S250) is a mode for confirming a password for each indoor unit of the air conditioning manager. The charge check mode (S260) is a mode for checking the air-conditioning charge used for each air-conditioning user.

Next, the input procedure from the sub input device (A to D group touch panel) 4 will be described with reference to the flowchart of FIG. 4 and the screen images of FIGS. 5, 6, 9 to 11. As shown in FIGS. 4 and 5, on the touch panel 4 of each group, first in S301, the same initial screen G1 as that of the main input device is displayed.
(FIG. 5) is displayed and an ID can be accepted.
On the other hand, the user of each indoor unit 13 transmits the ID card of the indoor unit 13 to the touch panel 4 to which the indoor unit belongs.
The ID can be read by approaching the ID sensor 45.

Next, in step S302, the touch panel 4 determines whether the read ID is correct, that is, whether the ID is a registered sub-type. If the ID is not correct, the screen returns to the initial screen G1 (S301) again. ID
If the password is correct, a password input screen G2 (FIG. 6) is displayed in S303, and the password can be input. On the other hand, the sub user enters his / her password on the numeric keypad G20 displayed on the touch panel.
Can be input by directly touching with a finger.

Next, in step S304, the touch panel 4 determines whether the input password is correct, that is, whether the input password is a registered one. If the password is incorrect, the password input screen G2 (S30
Return to 3). If the password is correct, a selection menu screen G5 (FIG. 9) for selecting a plurality of processing modes is displayed in S305.

In the selection menu screen G5 (FIG. 9), three modes of a change schedule setting mode (S310), an operation status confirmation mode (S320), and a password change mode (S330) can be selected.

The change schedule setting mode (S32)
0) is a mode for registering an operation schedule different from the standard schedule for the indoor unit of the user. Specifically, the change schedule menu screen G6
In FIG. 10, three types of settings can be selected: temporary operation setting, change schedule setting, and holiday setting.

The temporary operation setting is a function for forcibly turning on and off the operation irrespective of the schedule, and a setting for stopping the current operation or immediately starting the operation can be input. The change schedule can be set on the change schedule setting screen G7 shown in FIG. On this screen, first, the currently set contents are displayed for each day of the week, and a portion to be changed can be input from the numeric keypad G60. In this change schedule setting, the operation start time and the stop time on the day can also be set. In the holiday setting, a unique holiday (all day operation stop date) can be set. These settings are configured so that the last input is applied preferentially.

[0053] Then, the change scheduling mode (S320) is entered by the data is changed schedule S _2, and the is transmitted as described above, a reference operation-stop control of the indoor unit or the like.

In the operation status confirmation mode (S320), the operation status of the indoor unit 13 can be monitored. Further, in this mode, the contents of the standard schedule set in advance can be confirmed. The password change mode (S330) is a mode for changing the password of the indoor unit.

Next, the operation of this embodiment will be described. The air-conditioning control system 1 of the present embodiment is provided with the above-described controller. The controller 2 controls the operation and stop of the switchboard 14 and the indoor unit 13 as well as the heat source unit 11 and the external controller 1.
2 is configured to control the operation / stop. Further, operation and stop timing of the heat source apparatus 11, the outer conditioner 12 and the indoor unit 13, as described above, is determined based on the standard schedule S ₁ and reschedule S _2.

[0056] Therefore, not only the operation control in between so-called scheduled based on the standard schedule S _1, also the operation control in the time outside between scheduled for each indoor unit can be automatically performed by the controller. Therefore, it is not necessary for the air conditioning manager to constantly monitor the operation of the air conditioning control system 1, and labor costs can be reduced.

Further, on the side of each indoor unit, the operation instruction of the indoor unit outside the fixed time can be directly given by the input from the sub input device 4. This eliminates the conventional influence of the air conditioning manager, and realizes a very smooth operation of the air conditioning control system.

The sub input device 4 is provided with
For each of the four groups A to D, one by one
There are four in total. And one sub-entry for each group
From the power unit 4 to a plurality of indoor units 13 belonging to the group.
Change schedule S ₂Can do the input
You. Therefore, the required number of sub input devices 4 is the number of indoor units.
Significantly lower than 8 which reduces capital investment.
Reduction can be achieved.

Further, in the air conditioning control system 1, the controller 2 is connected to the switchboard 14, the heat source unit 11, and the external controller 12, and the controller 2 is provided with the main input device 3 and the sub input device 4. . For this reason, the existing heat source unit 11, the external conditioning unit 12, and the indoor unit 13
Almost no modification is required, which can also reduce capital investment.

In this embodiment, the controller 2 is composed of two sequencers, a main sequencer 21 and a sub sequencer 22. The control of the switchboard 14 for controlling the indoor unit 13 and the control of the heat source unit 11 and the external control unit 12 are shared by the two sequencers. Therefore, each part can be finely controlled.

The main sequencer 21 controls the heat source unit 11 and the external conditioner 12 in accordance with the operation status (feedback value or the like) of the indoor unit received from the sub sequencer 22. Therefore, rational control without excessive operation can be easily performed.

Embodiment 2 As shown in FIG. 12, this embodiment is an example in which five indoor units are further added to the air conditioning control system 1 of Embodiment 1. That is, as shown in the figure, the sub-sequencer 22 in the first embodiment is replaced with a first sub-sequencer (first SPL).
C) 22 and a second sub-sequencer (second SPL)
C) 23 was provided. Then, the E group touch panel 4 as a sub input device for the second sub sequencer 23
And the switchboard 14 were connected. The switchboard 14 has E
Five indoor units (FC) 13 belonging to the group were connected. The exchange of data between the second sub sequencer 23 and the main sequencer 21 is performed by the first sub sequencer 22.
It was configured to be performed via Others are the first embodiment.
Is the same as

In this case, a total of 13 indoor units belonging to the groups A to E can be individually air-conditioned easily. Otherwise, the same operation and effect as those of the first embodiment can be obtained. In each of the first and second embodiments, the case where the number of indoor units is 8 or 13 and the number of groups is 4 or 5 has been described. However, the number of indoor units and the number of groups can be further increased or decreased. A similar effect can be obtained.

[0064]

As described above, according to the present invention, it is possible to provide an air conditioning control system which can use existing air conditioning equipment as it is and can easily perform individual air conditioning control of each indoor unit. Can be.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an air conditioning control system according to a first embodiment.

FIG. 2 is a flowchart showing a control flow in the first embodiment.

FIG. 3 is a flowchart illustrating an input procedure in a main input device according to the first embodiment.

FIG. 4 is a flowchart illustrating an input procedure in a sub input device according to the first embodiment.

FIG. 5 is an explanatory diagram of an initial screen of a main and sub input device according to the first embodiment.

FIG. 6 is an explanatory diagram of a password input screen of the main and sub input devices according to the first embodiment.

FIG. 7 is an explanatory diagram of a selection menu screen of a main input device according to the first embodiment.

FIG. 8 is an explanatory diagram of a standard schedule screen of the main input device according to the first embodiment.

FIG. 9 is an explanatory diagram of a selection menu screen of a sub input device according to the first embodiment.

FIG. 10 is an explanatory diagram of a sub-input device change schedule menu screen according to the first embodiment.

FIG. 11 is an explanatory diagram of a sub-input device change schedule setting screen according to the first embodiment.

FIG. 12 is a block diagram illustrating a configuration of an air conditioning control system according to a second embodiment.

[Explanation of Codes] . . Air conditioning control system, 11. . . 11. heat source machine, . . External conditioning machine, 13. . . Indoor unit, 14. . . Switchboard, 2. . . Controller, 21. . . Main sequencer, 22. . . 2. Sub-sequencer, . . 35. main input device (main touch panel); . . 3. ID sensor, . . 45. sub input device (touch panel of groups A to D); . . ID sensor, 5. . . Payment device,

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Kouji Matsubara 19-18 Sakuradacho, Atsuta-ku, Nagoya-shi, Aichi Prefecture Inside Higashi Kokugas Corporation (72) Inventor Eiichi Fukuda 19-18, Sakuradacho, Atsuta-ku, Nagoya-shi, Aichi No. F-term in Toho Gas Co., Ltd. (reference) 3L060 AA03 AA08 EE27 EE32 EE35 3L061 BA05 BA07 BB04

Claims (4)

[Claims] 1. A heat source unit for cooling or heating a heat medium, a ventilator for ventilation, a plurality of indoor units for supplying air from the heat medium to air-condition a room, and operating the indoor units. -In an air conditioning control system having a switchboard for controlling stoppage, a controller for controlling these units is connected to the heat source unit, the external control unit, and the switchboard. A main input device for inputting a standard schedule, which is the standard operation / stop time of the indoor unit, is connected, and a change schedule, which is a start / stop time for each indoor unit, which is different from the standard schedule, is input. Sub-input devices are connected, and the sub-input devices are provided corresponding to the groups into which the indoor units are classified. Is provided so that the change schedule for one or more indoor units belonging to the group can be input, and the controller sets a time for actually operating / stopping each indoor unit based on the input standard schedule and the change schedule. And controlling the operation / stop of each indoor unit via the switchboard and controlling the operation / stop of the heat source unit and the external control unit in accordance with the regular schedule. An air conditioning control system characterized by the above-mentioned. 2. The control device according to claim 1, wherein the controller comprises a main control device and a sub control device, which are two control devices connected to each other, wherein the main control device includes the main input device and the sub control device. The sub-input device is connected to the device, the main control device controls the operation / stop of the heat source device and the external control device, and the sub-control device controls the operation / operation of the indoor unit via the switchboard. The sub-controller is configured to perform stop control, and the sub-controller is configured to control the switchboard based on the standard schedule received from the main input device via the main control device and the change schedule received from the sub-input device. A regular schedule for actually operating and stopping each indoor unit is determined via the control unit, and the operation control of the indoor unit is performed according to the regular schedule. The operating condition is transmitted to the main control device, and the main control device is configured to control the operation / stop of the heat source unit and the external control unit according to the operating condition of the indoor unit. An air-conditioning control system characterized by the following. 3. The air conditioning control system according to claim 1, wherein the main input device and the sub input device are a touch panel having a touch screen on a display screen. 4. The method according to claim 1, wherein:
The main input device and the sub input device are provided with a recognition device for recognizing the identification information from the identification information storage means storing the identification information set for each indoor unit. An air-conditioning control system, wherein the air-conditioning control system is configured to specify a corresponding indoor unit.