JP2013044462A - Air conditioning system control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an air conditioning system control device in which, regarding a plurality of operation patterns in which operating abilities of an air conditioner are different from each other, information about comforts in a room and energy saving effects can be displayed, respectively.SOLUTION: For each of the plurality of operation patterns, on the basis of a current indoor temperature and operating ability which is set to an air conditioner 3, achievement time 21 required for the indoor temperature to achieve a target temperature and a power consumption amount 23 to be consumed by the air conditioner 3 until the indoor temperature achieves the target temperature are determined and for each of the plurality of operation patterns, information about at least the achievement time 21 and the power consumption amount 23 is displayed.

Description

  The present invention relates to an air conditioning system control device that performs air conditioner state monitoring and operation control.

  2. Description of the Related Art Conventionally, in BEMS (building energy management system) that manages an air conditioning system, energy saving has attracted attention, and the construction of a system that realizes energy saving is desired.

  As a technique for displaying an energy saving effect, for example, in a display device of an air conditioning system, a pie chart or a bar graph showing a relationship between a control state by an adjusting unit of the air conditioning system and an energy saving effect obtained by adjusting the adjusting unit For example, a graphic graph showing the relationship between the air supply amount and the inverter frequency, a graphic graph showing the relationship between the air supply amount and power consumption, and a graphic graph showing the energy saving amount Are displayed on the same screen. "(For example, see Patent Document 1).

  Further, for example, “to provide an energy saving control system that can maintain the contract type so that the demand does not exceed the contract power and can realize the energy saving operation according to the power consumption in an efficient and low cost”. The thing is proposed (for example, refer patent document 2).

  In addition, a display device for an air conditioner has been proposed that “displays the time until the set room temperature is reached or the operating state as an indicator” (see, for example, Patent Document 3).

JP 2006-292279 A (summary) JP 2009-115392 A (summary) JP-A-1-252850 (Claims)

  Generally, when energy saving is achieved by reducing the power consumption of an air conditioner, the operating capacity of the air conditioner is reduced, so the time until the target temperature is reached compared to when the operating capacity is large. become longer. For this reason, comfort is impaired in driving for energy saving. On the other hand, when the operating capability of the air conditioner is increased so as to reach the target temperature faster with an emphasis on comfort, the amount of power consumption becomes larger than that of the operation for energy saving.

Some conventional air-conditioning system control devices display energy saving effects and allow the user to save energy. For example, focusing on energy saving driving and comfort, the target temperature can be reached more quickly. There is a problem that the relationship between the driving situation and the energy saving effect and the comfort of the occupant cannot be compared for a plurality of driving conditions (driving patterns) such as comparing driving.
For this reason, there existed a problem that control of the air conditioner which considered indoor comfort and the energy-saving effect could not be performed.

  The present invention has been made in order to solve the above-described problems, and is an air conditioning system capable of displaying information on indoor comfort and energy saving effects for a plurality of operation patterns having different operation capacities of air conditioners. A control device is obtained.

  An air conditioning system control device according to the present invention is an air conditioning system control device that performs state monitoring and operation control of an air conditioner, and obtains operation data including at least information on a room temperature detected by the air conditioner; and A control unit that controls the air conditioner based on a pattern selected from the plurality of operation patterns, and information related to the plurality of operation patterns is displayed. And an input unit for inputting an operation for selecting an arbitrary pattern from the plurality of operation patterns, and the control unit, for each of the plurality of operation patterns, the current room temperature, Based on the operation capacity set for the air conditioner, the arrival time required for the room temperature to reach the target temperature, and the room temperature as the target The amount of power consumed by the air conditioner until the time is reached, and the display unit displays at least information on the arrival time and the power consumption for each of the plurality of operation patterns. It is.

  The present invention can display information related to indoor comfort and energy saving effect for a plurality of operation patterns having different operation capacities of air conditioners.

It is an organization chart which shows the building management structure by which the air-conditioning system control apparatus which concerns on Embodiment 1 is arrange | positioned. It is a block diagram which shows the structure of the air conditioning system control apparatus which concerns on Embodiment 1. FIG. It is a state transition diagram which shows the screen transition of the display and setting part of the air conditioning system control apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the present driving | running state display screen which concerns on Embodiment 1. FIG. It is a figure which shows the air conditioning machine setting screen at the time of the air_conditionaing | cooling operation which concerns on Embodiment 1. FIG. It is a figure which shows the air conditioning machine setting screen at the time of the air_conditionaing | cooling operation which concerns on Embodiment 1. FIG. It is a flowchart which shows the display operation of the air-conditioner setting screen which concerns on Embodiment 1, and the operation | movement pattern selection operation. It is a figure which shows an example of the driving capability ratio selection table | surface which concerns on Embodiment 1. FIG. 6 is a diagram illustrating a display example of a discomfort index display index according to Embodiment 1. FIG. It is a figure which shows the air-conditioner setting screen at the time of the air_conditionaing | cooling operation which concerns on Embodiment 2. FIG. It is a flowchart which shows the display operation of the air-conditioner setting screen which concerns on Embodiment 2, and the selection operation of an operation pattern. FIG. 10 is a diagram showing a power consumption display screen according to the third embodiment. It is a figure which shows the discomfort index display screen which concerns on Embodiment 4. FIG. It is an organization chart which shows the building management structure by which the air-conditioning system control apparatus which concerns on Embodiment 5 is arrange | positioned. It is a figure which shows the air conditioner setting screen at the time of the air_conditionaing | cooling operation which concerns on Embodiment 5. FIG. It is a flowchart which shows the display operation of the air-conditioner setting screen which concerns on Embodiment 5, and the selection operation of an operation pattern.

Embodiment 1 FIG.
The air conditioning system control apparatus according to the first embodiment enables a user to select an operation pattern for controlling an air conditioner from the viewpoints of both indoor comfort and energy saving effect.

(System configuration)
FIG. 1 is an organization chart showing a building management configuration in which an air conditioning system control apparatus according to Embodiment 1 is arranged.
In FIG. 1, an air conditioning system control device 2 according to the present embodiment is connected to a building management system 1 that integrally manages various facilities in a building such as a building. The air conditioning system control device 2 is connected to air conditioners 3 (1) to (5) installed on the floors (1) to (5).

The air conditioner 3 is provided with a temperature sensor / humidity sensor 4, and information on the temperature of the indoor air (hereinafter referred to as indoor temperature) where the air conditioner 3 is installed and the humidity of the indoor air (hereinafter referred to as indoor humidity). Is transmitted to the air conditioning system control device 2. In addition, the air conditioner 3 transmits information such as an operation mode such as cooling, heating, and blowing operation and an operation capability to the air conditioning system control device 2.
In the following description, “operation data” includes the room temperature, room humidity, operation mode, and operation capability of the air conditioner 3.

  The air conditioning system control device 2 transmits command information related to operation control from the building management system 1 to the corresponding air conditioner 3, and transmits operation data received from the air conditioner 3 to the building management system 1. In addition, the air conditioning system control device 2 transmits command information related to operation control to the air conditioner 3 and displays information related to operation data received from the air conditioner 3 on the screen, so that the states of the plurality of air conditioners 3 are displayed. Perform monitoring and operation control. Details will be described later.

In the present embodiment, the configuration in which the air conditioning system control device 2 is connected to the building management system 1 will be described. However, the present invention is not limited to this, and the air conditioning system control device 2 and the air conditioner connected thereto. The configuration of 3 may be used.
Moreover, although the example of FIG. 1 shows the case where one air conditioner 3 is installed on each floor, the present invention is not limited to this, and a plurality of air conditioners 3 may be installed on one floor.
Moreover, although the case where there are a plurality of air conditioners 3 will be described, the air conditioner 3 for which the air conditioning system control device 2 performs state monitoring and operation control may be one.

(Configuration of air conditioning system control device 2)
FIG. 2 is a block diagram illustrating a configuration of the air conditioning system control apparatus according to the first embodiment.
In FIG. 2, the air conditioning system control device 2 includes a communication unit 5, a calculation unit 6, a display / setting unit 7, and an operation data storage unit 8.

The communication unit 5 is connected to the air conditioner 3 via a communication line, receives operation data from the air conditioner 3, and transmits information related to operation control for the air conditioner 3.
The communication unit 5 is connected to the building management system 1 via a communication line, receives command information from the building management system 1, and transmits operation data from the air conditioner 3 to the building management system 1.
The communication between the communication unit 5 and the building management system 1 and between the communication unit 5 and the air conditioner 3 may be wireless communication.

The calculation unit 6 has a plurality of operation patterns with different operation capacities set in the air conditioner 3, and controls the air conditioner 3 based on a pattern selected from the plurality of operation patterns.
In addition, the calculation unit 6 determines the time required for the room temperature to reach the target temperature, the amount of power consumed by the air conditioner 3 until the room temperature reaches the target temperature, and uncomfortable for the selected operation mode. Calculate the integrated value of the index. Details will be described later.
The calculation unit 6 corresponds to a “control unit” in the present invention.

The display / setting unit 7 includes information on the operation data collected by the communication unit 5, information on the arrival time for each operation pattern calculated by the calculation unit 6, power consumption, and the integrated value of the discomfort index, and the operation data storage unit 8. The past data stored in is displayed and the air conditioner operation information is presented to the user. Details of the display screen will be described later.
In addition, the display / setting unit 7 receives various screen switching operations, an operation for selecting an arbitrary pattern from a plurality of operation patterns, information on a target arrival time and a target power consumption (described later). Entered.
The display / setting unit 7 corresponds to a “display unit” and an “input unit” in the present invention.

  The operation data storage unit 8 stores past operation data acquired from the air conditioner 3. The operation data storage unit 8 stores in advance various table information used for calculation by the calculation unit 6 and various screen information displayed on the display / setting unit 7.

The communication unit 5 can be configured by a network interface such as a LAN interface.
The arithmetic unit 6 can be realized by hardware such as a circuit device that realizes this function, or can be realized as software executed on an arithmetic device such as a microcomputer or CPU.
The display / setting unit 7 can be configured by an arbitrary display device such as an LCD (Lipid Crystal Display) and an arbitrary input device such as a touch panel.
The operation data storage unit 8 can be configured by an arbitrary storage medium such as an HDD (Hard Disk Drive) or a flash memory.

(Screen transition of display / setting unit 7)
Next, the transition of the screen displayed on the display / setting unit 7 will be described.
FIG. 3 is a state transition diagram showing screen transition of the display / setting unit of the air conditioning system control apparatus according to the first embodiment.
The display / setting unit 7 displays the current operation state display screen 9 as an initial screen.
In FIG. 3, the screen displayed by the display / setting unit 7 changes from the current operation state display screen 9 to the air conditioner setting screen 10. In addition, the current operating state display screen 9 transits to the air conditioner setting screen 10 via the power consumption display screen 11 or the discomfort index display screen 12.
When the air conditioner 3 to be set is found on the current operation state display screen 9, the user selects the air conditioner 3 whose setting is to be changed and makes the transition to the air conditioner setting screen 10.
In addition, when the user wants to check the current energy saving degree collectively for each air conditioner, the user makes a transition to the power consumption display screen 11. Then, if necessary, the user selects the air conditioner 3 whose setting is to be changed on the power consumption display screen 11 and makes a transition to the air conditioner setting screen 10.
Further, when the user wants to check the discomfort index for each air conditioner collectively, the user transitions to the discomfort index display screen 12. Then, if necessary, the user selects the air conditioner 3 to be set on the discomfort index display screen 12 and makes a transition to the air conditioner setting screen 10.

(Current operation status display screen 9)
FIG. 4 is a diagram showing a current operation state display screen according to the first embodiment.
As shown in FIG. 4, the current operation state display screen 9 is set with items 13 for displaying the operation state (operation / stop) of each air conditioner 3 and the indoor temperature (room temperature) of the installation location.
The current operation state display screen 9 is provided with an operation button 41, a power consumption display screen button 42, and a discomfort index display screen button 43.
When an operation for selecting the power consumption display screen button 42 is input by the user, the screen transitions to the power consumption display screen 11. When an operation for selecting the discomfort index display screen button 43 is input, the screen transitions to the discomfort index display screen 12.
Details of the power consumption display screen 11 will be described in the third embodiment, and details of the discomfort index display screen 12 will be described in the fourth embodiment.

  When an operation for selecting the operation button 41 is input after the operation for selecting the air conditioner 3 by the user, the screen transitions to the air conditioner setting screen 10 related to the air conditioner 3.

(Air conditioner setting screen 10)
5 and 6 are diagrams showing an air conditioner setting screen during the cooling operation according to the first embodiment.
FIG. 5 shows an example of an air conditioner setting screen during cooling operation when the current temperature is higher than the target temperature, and FIG. 6 shows an air conditioner setting screen during cooling operation when the current temperature is lower than the target temperature. An example is shown.

The air conditioner setting screen 10 displays the current room temperature of the air conditioner 3 and the target temperature set for the air conditioner 3. In addition, information on arrival time and power consumption is displayed for each of the plurality of operation patterns. Further, when the operation mode of the air conditioner 3 is the cooling operation, information on the discomfort level is displayed.
Here, a case will be described in which there are energy saving operation patterns (hereinafter referred to as energy saving operations) and comfortable operation patterns (hereinafter referred to as comfortable operations) as operation patterns.
The comfortable operation is an operation in which the operating capacity of the air conditioner 3 is set to the maximum value (100%) and the room temperature reaches the target temperature as quickly as possible.
The energy saving operation is an operation that emphasizes energy saving, and a preset operation capacity is set in the air conditioner 3, and the time to reach the target temperature is longer than the above comfortable operation, but the power consumption can be reduced. Driving.

5 and 6, the air conditioner setting screen 10 includes a current temperature 14, a target temperature 15, a detailed data item 19 for energy saving operation, a detailed data item 20 for comfortable driving, a graph 16, a discomfort index button 31, and a power consumption button. There are 32 display items.
The current temperature 14 is a measured value of the current indoor temperature of the air conditioner 3 based on the operation data acquired by the communication unit 5.
The target temperature 15 is a temperature set in the air conditioner 3 by a user input operation.
The target temperature 15 may be set, for example, by command information from the building management system 1 or input from a remote controller or the like provided in the air conditioner 3.

The detailed data item 19 for energy saving operation and the detailed data item 20 for comfortable driving have information on arrival time 21 and power consumption 23, respectively. Further, when the operation mode of the air conditioner 3 is the cooling operation, the detailed data item 19 of the energy saving operation and the detailed data item 20 of the comfortable operation each have information of the discomfort level 22.
The arrival time 21 is a predicted value of time [minutes] required for the room temperature to reach the target temperature.
The discomfort level 22 is a level value divided into, for example, five levels according to the predicted value of the integrated value of the discomfort index until the room temperature reaches the target temperature. Details will be described later.
The power consumption 23 is a predicted value of the power [kWh] consumed by the air conditioner 3 until the room temperature reaches the target temperature.
The calculation unit 6 obtains the arrival time 21, the discomfort level 22, and the power consumption 23 based on the operation data acquired by the communication unit 5 for each of the energy saving operation and the comfortable operation. The display / setting unit 7 displays these information in the detailed data item 19 for energy saving operation and the detailed data item 20 for comfortable driving. Details of the calculation operation of each predicted value will be described later.

  For example, in the example of FIG. 5, when the operation is performed in the energy saving operation, the arrival time required to decrease the current indoor temperature “28 ° C.” to the target temperature “24 ° C.” is “50 minutes”. The level is “level 3”, and the power consumption is “0.5 kWh”. Further, when driving with comfortable driving, the arrival time is “20 minutes”, the discomfort level in this driving is “level 1”, and the power consumption is “1.0 kWh”.

  The graph 16 graphs the predicted value of the indoor temperature for a predetermined time (for example, 60 minutes) for each operation pattern, where the vertical axis is the room temperature (° C.), the horizontal axis is the time (minutes), and the current time is 0 minutes. Is displayed.

For example, in the examples of FIGS. 5 and 6, the prediction of the indoor temperature when driving with energy-saving operation for 60 minutes from the current time (0 minutes) is shown by the prediction line 17 (dotted line), and when driving with comfortable driving. The predicted indoor temperature is indicated by a prediction line 18 (solid line).
Thus, by displaying the predicted value of the temperature change for each operation pattern as a graph, the user can visually recognize the temperature change status of each pattern.

The discomfort index button 31 is an operation item for changing the vertical axis of the graph 16 to the discomfort index. The power consumption button 32 is an operation item for changing the vertical axis of the graph 16 to power consumption.
By inputting an operation for selecting the discomfort index button 31 or the power consumption button 32 as required by the user, the vertical axis of the graph 16 is switched from the room temperature to the discomfort index or the power consumption, for a predetermined time (for example, 60 minutes). The predicted value of is visually displayed.
Note that the operation of the discomfort index button 31 may be disabled when the air conditioner 3 is in the heating operation.

(Operation)
FIG. 7 is a flowchart showing an air conditioner setting screen display operation and an operation pattern selection operation according to the first embodiment.
Hereinafter, description will be given based on each step of FIG.

(S101)
On the initial screen (current operation state display screen 9), the user inputs an operation for selecting the operation button 41 after the operation for selecting the air conditioner 3. The display / setting unit 7 starts displaying the air conditioner setting screen 10 related to the selected air conditioner 3.
(S102)
The user inputs information on the target temperature 15 for the air conditioner 3 from the display / setting unit 7.
(S103)
The calculating part 6 acquires the operation data of the air conditioner 3, and calculates | requires the arrival time 21, the predicted value of the power consumption 23, and the driving capability for each driving pattern. Further, when the air conditioner 3 is in the cooling operation, the predicted value of the integrated value of the discomfort index and the discomfort level 22 corresponding thereto are obtained.
Hereinafter, each predicted value and driving ability will be described in detail.

(Driving ability)
(A) Energy saving operation The operation data storage unit 8 stores in advance correspondence information between the temperature difference between the current temperature 14 and the target temperature 15, the driving ability in the energy saving operation, and the arrival time 21.

For example, when the current temperature 14 is higher than the target temperature 15, the operating capacity is set to 50% of the maximum value, and the temperature decrease tendency when the air conditioner 3 is operated with this operating capacity is acquired by experimental values or simulations. Thus, the arrival time 21 for each temperature difference is stored in advance.
Further, for example, when the current temperature 14 is lower than the target temperature 15, the operation is stopped (driving capacity 0%), and the temperature rising tendency at this time is acquired by an experimental value, simulation, etc. The arrival time 21 is stored in advance.
The correspondence information stored in the operation data storage unit 8 may be updated according to past operation data. For example, an actual measurement value of the arrival time 21 by the past energy saving operation may be acquired, and information corresponding to the temperature difference at this time may be updated to the actual measurement value.

The calculation unit 6 obtains a temperature difference based on the current temperature 14 acquired by the communication unit 5 and the target temperature 15 input from the display / setting unit 7, and refers to the operation data storage unit 8 to calculate the temperature difference. Get information on driving capability in energy-saving operation corresponding to.
(B) Comfortable driving The driving data storage unit 8 stores in advance a maximum value (100%) as information on driving ability in comfortable driving. In addition, the driving capability at the time of comfortable driving is not limited to this, and an arbitrary driving capability larger than the energy saving driving may be stored.
The calculation unit 6 refers to the driving data storage unit 8 and acquires information (maximum value) of driving ability in comfortable driving.

(Arrival time)
(A) Energy saving operation The calculation part 6 acquires the arrival time 21 corresponding to a temperature difference from the correspondence information in the energy saving operation mentioned above with reference to the operation data storage part 8, and makes this a predicted value.
(B) Comfortable operation The operation data storage unit 8 stores in advance information on the temperature decrease rate (temperature gradient) when the air conditioner 3 is operated with the driving ability (maximum value) in comfortable operation.
This temperature decrease rate is set by, for example, experimental values or simulations. In addition, the information may be updated based on actual measurement values from past operation data.
The calculation unit 6 refers to the operation data storage unit 8 and acquires the temperature decrease rate of the air conditioner 3. Then, a value obtained by dividing the temperature difference between the current temperature 14 and the target temperature 15 by the temperature decrease rate is set as the predicted value of the arrival time 21.

(Power consumption)
In the operation data storage unit 8, information on the relationship between the operation capability of the air conditioner 3 and the power consumption is stored in advance. For example, information on conversion coefficients for converting driving capability into power consumption is stored.
The calculation unit 6 predicts the power consumption amount by converting the driving ability acquired as described above into power consumption for each driving pattern and integrating the power consumption until reaching the target temperature.
In addition, after reaching the target temperature, the driving capability during steady operation for maintaining this temperature can be obtained based on the target temperature. For example, in the operation data storage unit 8, information on the driving capability at the time of driving maintaining the temperature is stored in advance for each temperature. Convert to electricity.
In this way, the amount of power consumed for a predetermined time (60 minutes) from the current time is predicted as the power consumption amount 23.

The driving ability may be derived from the predicted indoor temperature and indoor humidity.
For example, information of the driving capability ratio selection table 39 as shown in FIG. 8 is stored in the driving data storage unit 8 in advance.
And the calculating part 6 calculates | requires a temperature change rate (temperature inclination) based on the present temperature 14, the target temperature 15, and the estimated arrival time 21, and calculates | requires the indoor temperature for every unit time (minute unit).
In addition, information on the humidity change rate (humidity gradient) with respect to the temperature change rate (temperature gradient) is stored in advance in the operation data storage unit 8, and the humidity gradient in the operation pattern is obtained from the temperature gradient obtained as described above. . The calculation unit 6 obtains the room humidity for each unit time (minute unit) from this information and the information on the current room humidity acquired from the communication unit 5.
From the information on the room temperature and the room humidity for each unit time (minute unit) obtained in this way, the dry bulb temperature [° C. DB] and the wet bulb temperature [° C. WB] of the air conditioner 3 using the hx diagram. ] Is calculated. Then, the corresponding driving capacity ratio 40 is derived from the driving capacity ratio selection table 39 as shown in FIG. Multiplying the driving capacity ratio 40 for each unit time (minute unit) by the conversion coefficient for converting the driving capacity ratio 40 into power consumption, and integrating this, the power consumed for a predetermined time (60 minutes) The amount may be predicted as the power consumption amount 23.

  Note that although the amount of power consumed for a predetermined time is predicted here, the present invention is not limited to this, and the amount of power consumed until the room temperature reaches the target temperature is calculated as the amount of power consumed. It may be 23.

(Calculation of discomfort index)
The discomfort index is an index defined by the following equation from the temperature Td [° C.] and the humidity H [%]. In addition, the following formula is well-known and is generally used.
Discomfort index = 0.81Td + 0.01H (0.99Td-14.3) +46.3

Based on the current room temperature and room humidity acquired by the communication unit 5, the calculation unit 6 predicts the room temperature and room humidity for each unit time (in minutes) in each operation pattern.
The room temperature in each unit time can be calculated by obtaining the temperature change rate (temperature gradient) based on the current temperature 14, the target temperature 15, and the predicted arrival time 21.
The indoor humidity in each unit time is stored in advance in the operation data storage unit 8 by storing information on the humidity change rate (humidity gradient) with respect to the temperature change rate (temperature gradient). A humidity gradient in the operation pattern can be obtained and calculated from the humidity gradient and the current indoor humidity.
And the calculating part 6 calculates | requires the integrated value of the discomfort index | exponent for predetermined time (60 minutes) by calculating the discomfort index | exponent in each unit time from said formula about each driving | operation pattern, and integrating | accumulating this.

  Although the integrated value for a predetermined time is used here, the present invention is not limited to this, and the integrated value of the discomfort index until the room temperature reaches the target temperature may be obtained.

(Association of discomfort levels)
The operation data storage unit 8 stores in advance correspondence information between the range of integrated values of discomfort index and discomfort level.
For example, the following table information is stored. The value is an example.
Discomfort index integrated value 0 to 1000: Level 0
1001-2000: Level 1
2001-3000: Level 2
3001-4000: Level 3
4001-5000: Level 4
5001-6000: Level 5

  The calculation unit 6 refers to the operation data storage unit 8 to obtain a level value corresponding to the calculated integrated value of the discomfort index, and sets it as the discomfort level 22.

(S104)
Next, based on the operation data and the calculated value, the display / setting unit 7 presents the current temperature 14, the target temperature 15, the detailed data item 19 for energy saving operation, the detailed data item 20 for comfortable operation, The arrival time 21, the power consumption 23, and the graph 16 are displayed. When the air conditioner 3 is in the cooling operation, the discomfort level 22 is displayed.
Thereby, the user can easily grasp the relationship between the operation state of the air conditioner 3 and the energy saving effect and the comfort of the occupant for each operation pattern.

The prediction line 18 for comfortable driving in the graph 16 is drawn as a line segment connecting the intersection of the target temperature 15 and the arrival time 21 from the current temperature 14.
When the current temperature 14 is higher than the target temperature 15 (FIG. 5), the prediction line 17 in the energy saving operation in the graph 16 is a line segment connecting the intersection of the target temperature 15 and the arrival time 21 from the current temperature 14. Draw with. On the other hand, when the current temperature 14 is lower than the target temperature 15 (FIG. 6), the temperature rise up to the target temperature 15 is a natural rise that does not depend on the operation of the air conditioner 3. Therefore, based on a preset temperature rise function. A prediction line 17 is drawn.

The integrated value of the discomfort index may be displayed instead of or in addition to the discomfort level 22 displayed in the detailed data item 19 for energy saving operation and the detailed data item 20 for comfortable operation.
The display method of the discomfort level 22 may be character information such as “level 2” as shown in FIG. 5 and FIG. 6, or the discomfort index display index (graphic display) as shown in FIG. May be. For example, in the example of FIG. 9, the display index (201 to 205) corresponding to the level value (1 to 5) is displayed. Thus, by using the level of the discomfort index as a display index, the user can visually recognize the discomfort index.

(S105)
Next, the user operates the display / setting unit 7 to select an arbitrary pattern from a plurality of operation patterns. This selection operation may be, for example, an operation for selecting either the detailed data item 19 of the energy saving operation or the detailed data item 20 of the comfortable operation on the air conditioner setting screen 10 or the prediction line 17 of the energy saving operation in the graph 16. Alternatively, an operation for selecting one of the prediction lines 18 for comfortable driving may be used.

(S106)
The calculation unit 6 controls the air conditioner 3 based on the operation pattern selected in step S105. That is, when comfortable driving is selected, the driving capacity of the air conditioner 3 is set to the maximum value. Further, when the energy saving operation is selected, the operation capacity obtained in step S103 is set in the air conditioner 3.

  5 and 6 show the case of the cooling operation, the present invention is not limited to this, and the same display can be performed by the same operation even in the case of the heating operation. However, since the discomfort index is an index during cooling operation, it is not used during heating operation. During the heating operation, a comfort index may be calculated and displayed.

As described above, in the present embodiment, the operation time set for the air conditioner 3 has a plurality of operation patterns different from each other, and the arrival time required for the room temperature to reach the target temperature for each of the plurality of operation patterns. 21 and the amount of power consumption 23 consumed by the air conditioner 3 are obtained. Then, the display / setting unit 7 displays information on the arrival time 21 and the power consumption 23 for each of the plurality of operation patterns.
For this reason, the arrival time 21 can be displayed as information related to indoor comfort and the power consumption 23 can be displayed as information related to the energy saving effect for a plurality of operation patterns with different operating capabilities of the air conditioner 3. Therefore, it is possible to control the air conditioner 3 in consideration of indoor comfort and energy saving effect.

Moreover, in this Embodiment, when the operation mode of the air conditioner 3 is a cooling operation, the integrated value of a discomfort index is calculated | required about each of several operation patterns. The display / setting unit 7 displays information related to the integrated value of the discomfort index (discomfort level 22) as information related to indoor comfort for each of the plurality of driving patterns.
For this reason, control of the air conditioner 3 which considered indoor comfort and the energy-saving effect can be performed.

In the present embodiment, the plurality of operation patterns include an energy saving operation pattern for setting a predetermined operation capacity in the air conditioner 3 and a comfortable operation pattern for setting the operation capacity of the air conditioner 3 to a maximum value.
Therefore, by comparing the case of driving with an emphasis on energy savings and the case of driving taking into account comfort, the energy saving effect and comfort level of the two patterns are displayed to the user, so that the user can save only the energy saving effect. In addition, it is possible to set the air conditioner considering the aspect of comfort.

  In the present embodiment, the case where the operation data includes the room temperature, the room humidity, the operation mode, and the operation capability of the air conditioner 3 has been described. However, the present invention is not limited to this and is described above. If the calculated discomfort index is not calculated, at least information on the room temperature may be acquired.

Embodiment 2. FIG.
In the second embodiment, a mode is described in which the value of the arrival time 21 or the power consumption 23 can be changed by an operation by the user.

FIG. 10 is a diagram showing an air conditioner setting screen during cooling operation according to the second embodiment.
In the present embodiment, a user setting operation pattern (hereinafter referred to as user setting operation) is provided as an operation pattern.
As shown in FIG. 10, the air conditioner setting screen 10 in the present embodiment displays a detailed data item 24 of the user setting operation instead of the comfortable operation.
Other displays are the same as those in the first embodiment, and the same parts are denoted by the same reference numerals.

  Here, the case where the user setting operation is displayed instead of the comfortable driving will be described. However, the present invention is not limited to this, and the user setting operation may be displayed instead of the energy saving driving, or in addition to the energy saving driving and the comfortable driving. Further, the user setting operation may be displayed.

FIG. 11 is a flowchart showing the display operation of the air conditioner setting screen and the operation pattern selection operation according to the second embodiment.
Hereinafter, based on each step of FIG. 11, it demonstrates centering on difference with the said Embodiment 1. FIG. In addition, the same step number is attached | subjected to the operation | movement same as the said Embodiment 1 (FIG. 7).

(S201)
After the above-described steps S101 to S104, the user operates the display / setting unit 7 to select an arbitrary pattern from a plurality of operation patterns, and at least the arrival time 21, the power consumption 23, and the target temperature 15 are selected. Enter the presence or absence of setting change for one. For example, after selecting an operation pattern, a pop-up message such as “Do you want to change the setting value?” Is displayed, and either “Yes” or “No” is selected.
That is, even when the energy saving operation or the comfortable operation is selected, when an operation for changing the set value is performed, the operation shifts to the user setting operation pattern.

(S202)
The calculation unit 6 determines whether or not a setting change is input. If there is no setting change, the operation unit 6 proceeds to step S106 and performs operation control of the air conditioner 3 by the above-described operation. On the other hand, if there is a setting change, the process proceeds to step S203.
If an operation for selecting a user-set operation pattern is performed during pattern selection, this step may be omitted and the process may proceed to step S203.

(S203)
The user operates the display / setting unit 7 to input a desired value for at least one of the arrival time 21, the power consumption 23, and the target temperature 15.
The arrival time 21 input here corresponds to the “target arrival time” in the present invention.
The power consumption 23 input here corresponds to the “target power consumption” in the present invention.

(S204)
When the value of the target temperature 15 is changed, the prediction calculation is performed again using the updated target temperature 15 by the same operation as in step S104.

When the value of the arrival time 21 is changed, the calculation unit 6 calculates the time required for the room temperature to reach the target temperature based on the updated arrival time 21 and the current temperature 14 as the updated arrival time 21. The operation capability of the air conditioner 3 is obtained.
For example, the temperature change rate (temperature gradient) for each driving ability is acquired by an experimental value, simulation, or the like, or acquired from past driving data, and stored in the driving data storage unit 8. The calculation unit 6 obtains a temperature gradient from the current temperature 14 and the updated arrival time 21, and refers to the operation data storage unit 8 to obtain the driving ability corresponding to the temperature gradient.
When the driving ability is updated, the predicted value of the power consumption 23 is obtained again by the same operation as in step S104. Further, when the air conditioner 3 is in the cooling operation, the predicted value of the integrated value of the discomfort index and the discomfort level 22 corresponding thereto are obtained.

When the value of the power consumption 23 is changed, the calculation unit 6 is consumed by the air conditioner 3 until the room temperature reaches the target temperature based on the updated power consumption 23 and the current temperature 14. The operating capacity of the air conditioner 3 in which the electric energy is the updated electric power consumption 23 is obtained.
For example, the driving ability can be obtained by back-calculating the above-described driving ability from a function that converts power consumption.
When the driving ability is updated, the predicted value of the arrival time 21 is obtained again by the same operation as in step S104. Further, when the air conditioner 3 is in the cooling operation, the predicted value of the integrated value of the discomfort index and the discomfort level 22 corresponding thereto are obtained.

(S104)
The air conditioner setting screen 10 is displayed as in the first embodiment. At this time, the display is updated to the predicted value in step S204.
For example, as shown in FIG. 10, the display of the detailed data item 24 of the user setting operation is updated. In addition, based on the predicted value obtained in step S204, a predicted line 25 in the user setting operation is drawn on the graph 16.

  Thereafter, Steps S201 and S202 are performed in the same manner as described above, and if there is no setting change in Step S202, the process proceeds to Step S106, and the driving capacity obtained in Step S204 is set in the air conditioner 3.

As described above, in the present embodiment, the arrival time 21 and the power consumption 23 are updated based on the information (target arrival time and target power consumption) input from the display / setting unit 7. The driving capacity is obtained and the driving capacity is set in the air conditioner 3.
For this reason, the information regarding indoor comfort and the information regarding an energy saving effect can be displayed according to the driving conditions desired by the user. Therefore, fine control according to the user's wish is possible.

Embodiment 3 FIG.
FIG. 12 is a diagram showing a power consumption display screen according to the third embodiment.
As described in the first embodiment, when the user inputs an operation for selecting the power consumption display screen button 42 on the current operation state display screen 9, the screen transitions to the power consumption display screen 11.
As shown in FIG. 12, the power consumption display screen 11 includes a graph 35 displaying the power consumption 34 (instantaneous value) for each of the plurality of air conditioners 3 as a bar graph, and the current temperature 46 of each air conditioner 3. The target temperature 47 is displayed.
The value of the power consumption 34 of each air conditioner 3 can be obtained by converting the set operating capacity into power consumption based on the operation pattern set in the air conditioner 3 by the operation of the first or second embodiment. .
The power consumption may be obtained based on the operation data acquired from the communication unit 5. For example, you may obtain | require from indoor temperature and indoor humidity using the driving capability ratio selection table | surface 39 mentioned above. Further, for example, each air conditioner 3 may be provided with a power consumption measuring instrument to acquire this information.

The current temperature 46 is information acquired by the communication unit 5.
The target temperature 47 is a temperature set in each air conditioner 3 by a user input operation. The target temperature 47 may be set, for example, by command information from the building management system 1 or input from a remote controller provided in the air conditioner 3 or the like.

The power consumption display screen 11 is provided with a week display button 44, a month display button 45, and an operation button 41.
The operation data storage unit 8 sequentially stores the power consumption calculated as described above.
When the week display button 44 is selected, the calculation unit 6 refers to the operation data storage unit 8, acquires information on power consumption in the past one week in each air conditioner 3, and calculates an average value thereof. The display / setting unit 7 displays the average value of power consumption for the past week on the graph 35 of the power consumption display screen 11.
When the month display button 45 is selected, the calculation unit 6 refers to the operation data storage unit 8, acquires information on the power consumption for the past month in each air conditioner 3, and calculates an average value thereof. The display / setting unit 7 displays an average value of power consumption for the past month on the graph 35 of the power consumption display screen 11.
In this embodiment, the case of displaying the average value of power consumption for the past week or the past month is described, but the present invention is not limited to this. For example, not only the average value but also the power consumption of each air conditioner for each day of the week and the power consumption (integrated value) for each month of each air conditioner may be displayed. The power consumption display screen 11 may be provided with a selection button or the like corresponding to information to be displayed.

  When an operation for selecting the operation button 41 is input after the operation for selecting the air conditioner 3 by the user, the screen transitions to the air conditioner setting screen 10 related to the air conditioner 3.

As described above, since the power consumption 34 that is instantaneous power is displayed for each of the plurality of air conditioners 3, the user can recognize at a glance an air conditioner with high power consumption.
Further, since the current temperature 46 and the target temperature 47 are also displayed, the relationship between the power consumption and the target temperature can be recognized.
Thereby, the user can judge the location which can be inefficient driving | operation and can achieve energy saving.

Embodiment 4 FIG.
FIG. 13 is a diagram showing a discomfort index display screen according to the fourth embodiment.
As described in the first embodiment, when the user inputs an operation for selecting the discomfort index display screen button 43 on the current operation state display screen 9, the screen transitions to the discomfort index display screen 12.
As shown in FIG. 13, the discomfort index display screen 12 displays a graph 37 in which the current discomfort index 36 is displayed as a bar graph for the air conditioner 3 whose operation mode is the cooling operation among the plurality of air conditioners 3.
The discomfort index 36 of each air conditioner 3 can be obtained by the calculation formula described in the first embodiment based on the current indoor temperature and indoor humidity information acquired by the communication unit 5.
In the example of FIG. 13, the case where the discomfort index 36 is represented by a bar graph corresponding to a numerical value is described. However, the present invention is not limited to this, and the numerical value of the discomfort index 36 is converted into an unpleasant level as in the first embodiment. Correspondence information may be stored in the operation data storage unit 8 in advance, and the discomfort level may be displayed by referring to this.

  The discomfort index display screen 12 is provided with an operation button 41. When an operation for selecting the operation button 41 is input after the user selects the air conditioner 3, the air conditioner 3 is selected. The screen transitions to the air conditioner setting screen 10 according to.

As described above, since the current discomfort index 36 is displayed for the air conditioner 3 in which the operation mode is the cooling operation among the plurality of air conditioners 3, the user can quickly view the air conditioner 3 having a high discomfort index. Can be recognized.
Thereby, a user can judge the location where indoor comfort is low about each floor where the air conditioner 3 is arrange | positioned.

Embodiment 5 FIG.
In the present embodiment, the air conditioner setting screen 10 is displayed in consideration of demand control.
In addition, demand control refers to the control which suppresses the capability of the air conditioner 3 so that the total value of the power consumption of the some air conditioner 3 may fall below a predetermined value (for example, contract electric power).

FIG. 14 is an organization chart showing a building management configuration in which the air conditioning system control apparatus according to the fifth embodiment is arranged.
In FIG. 14, the air conditioning system control device 2 according to the present embodiment is connected to a demand determination unit 50. Other configurations are the same as those in the first embodiment, and the same reference numerals are given to the same portions.

The demand determination unit 50 obtains operation data from each air conditioner 3 to obtain power consumption (instantaneous power), and one or a plurality of the power consumption values of each air conditioner 3 are less than a predetermined value. A demand signal for instructing a decrease in the operating capacity of the air conditioner 3 is transmitted.
For example, priorities are set for a plurality of air conditioners 3, and the operation capacity is suppressed in order from the air conditioners 3 with the lowest priority, or the operation is stopped, and the overall power consumption is controlled to be lower than a predetermined value. Send demand signal. Further, for example, a demand signal for controlling the plurality of air conditioners 3 to uniformly reduce the operating capacity and control the overall power consumption to be lower than a predetermined value is transmitted.
The communication unit 5 of the air conditioning system control device 2 acquires a demand signal from the demand determination unit 50, and performs display in consideration of demand control.

FIG. 15 is a diagram showing an air conditioner setting screen at the time of cooling operation according to the fifth embodiment. FIG. 16 is a flowchart showing an air conditioner setting screen display operation and an operation pattern selection operation according to the fifth embodiment.
Hereinafter, based on the steps in FIG. 16, the difference from the first and second embodiments will be mainly described with reference to FIG.

(S301)
After setting the operating capacity of the air conditioner 3 by the same operation as in the first or second embodiment (S104), the calculation unit 6 determines whether the room temperature has reached the target temperature 15.
If the target temperature 15 is reached, the process is terminated.

(S302)
When the room temperature has not reached the target temperature 15, the calculation unit 6 determines whether there is a demand signal from the demand determination unit 50.
If the demand signal has not been received, the process returns to step S301.

(S303)
When the demand signal is received by the communication unit 5, the calculation unit 6 sets the operation capability of the air conditioner 3 instructed by the demand signal to a predetermined value corresponding to the demand control regardless of the operation pattern selected in step S201. Set to driving capacity.
For example, the operation pattern at the time of demand control is stored in advance in the operation data storage unit 8, and the calculation unit 6 refers to this to acquire the driving ability corresponding to the demand control.
Note that the setting of the driving capability in demand control is not limited to this, and information on the driving capability for the air conditioner 3 is included in the demand signal, and the calculation unit 6 may install the driving capability instructed by the demand signal. good.

  Moreover, the calculating part 6 performs the prediction calculation of the arrival time 21 and the power consumption 23 again by the operation | movement similar to said step S104 based on the acquired driving capability and the present indoor temperature. Further, when the air conditioner 3 is in the cooling operation, the predicted value of the integrated value of the discomfort index and the discomfort level 22 corresponding thereto are obtained.

(S304)
Next, the display / setting unit 7 displays the arrival time 21 and the power consumption 23 during the demand control calculated in step S303. When the air conditioner 3 is in the cooling operation, the predicted value of the integrated value of the discomfort index and the corresponding discomfort level 22 are displayed.
For example, as shown in FIG. 12, when demand control is activated during, for example, comfortable driving, a detailed data item 49 for demand control is displayed.
Further, based on the updated predicted value, the predicted line 18 for comfortable driving drawn on the graph 16 is updated to the predicted line 48 for demand control corresponding to the updated predicted value. In FIG. 12, the reference time (0 minutes) of the graph 16 is based on the time when the prediction calculation of each operation pattern is performed in step S103 or S204. As a result, it can be visually recognized that the demand control has been performed in the middle of the control by the operation pattern.

As described above, in the present embodiment, regardless of the selected operation pattern, the operation capability of the air conditioner 3 instructed by the demand signal is set to a predetermined operation capability corresponding to demand control, and the operation capability The arrival time 21 and the power consumption 23 are obtained based on the current room temperature. The display / setting unit 7 displays information on the arrival time 21 and the power consumption 23 during demand control.
For this reason, even when the demand control is executed during the execution of the control based on the driving pattern, the arrival time 21 and the power consumption 23 in the control can be displayed.
Further, each air conditioner 3 can be demand-controlled based on the demand signal without switching the operation pattern by the user's operation.

  1 building management system, 2 air conditioning system control device, 3 air conditioner, 4 temperature sensor / humidity sensor, 5 communication unit, 6 calculation unit, 7 display / setting unit, 8 operation data storage unit, 9 operation status display screen, 10 air conditioning Machine setting screen, 11 Power consumption display screen, 12 Discomfort index display screen, 13 items, 14 Current temperature, 15 Target temperature, 16 Graph, 17 Predicted line, 18 Predicted line, 19 Detailed data item of energy saving operation, 20 Comfortable driving Detailed data item, 21 arrival time, 22 discomfort level, 23 power consumption, 24 detailed data item of user-set operation, 25 prediction line, 31 discomfort index button, 32 power consumption button, 34 power consumption, 35 graph, 36 discomfort index , 37 graph, 39 driving capacity ratio selection table, 40 driving capacity ratio, 41 operation buttons, 42 power consumption display screen Button, 43 Discomfort index display screen button, 44 Week display button, 45 Month display button, 46 Current temperature, 47 Target temperature, 48 Predicted line, 49 Detailed data item of demand control, 50 Demand judgment part, 201-205 Display index.

Claims (9)

An air-conditioning system control device that performs air conditioner status monitoring and operation control,
A communication unit for acquiring operation data including at least information on the indoor temperature detected by the air conditioner;
A control unit for controlling the air conditioner based on a pattern selected from the plurality of operation patterns, each having a plurality of operation patterns with different operation capacities set for the air conditioner;
A display unit for displaying information on the plurality of driving patterns;
An input unit for inputting an operation of selecting an arbitrary pattern from the plurality of driving patterns;
With
The controller is
For each of the plurality of driving patterns,
Based on the current room temperature and the operating capacity set for the air conditioner, the time required for the room temperature to reach the target temperature, and the air conditioner until the room temperature reaches the target temperature. Find the amount of power consumed in
The display unit
For each of the plurality of driving patterns,
At least information on the arrival time and the power consumption is displayed. The plurality of driving patterns include an energy saving driving pattern and a comfortable driving pattern,
The controller is
When the comfortable driving pattern is selected, the driving capacity of the air conditioner is set to the maximum value,
2. The air conditioning system control according to claim 1, wherein when the energy saving operation pattern is selected, a predetermined operation capacity corresponding to a temperature difference between the current room temperature and the target temperature is set in the air conditioner. apparatus. The plurality of driving patterns include a user setting driving pattern,
In the input unit, information on the target arrival time is input,
The controller is
When the user setting operation pattern is selected,
Based on the target arrival time and the current room temperature, the time required for the room temperature to reach the target temperature is determined as the operating capacity of the air conditioner at which the target reaching time is reached. The air conditioning system control device according to claim 1 or 2, wherein The plurality of driving patterns include a user setting driving pattern,
The input unit receives information on target power consumption,
The controller is
When the user setting operation pattern is selected,
Based on the target power consumption and the current indoor temperature, the power consumption consumed by the air conditioner until the room temperature reaches the target temperature is the target power consumption of the air conditioner. The air conditioning system control device according to claim 1 or 2, wherein an operating capacity is obtained and the operating capacity is set in the air conditioner. The operation data includes information on an operation mode and indoor humidity,
The controller is
When the operation mode of the air conditioner is cooling operation,
For each of the plurality of driving patterns,
Based on the current room temperature and the current room humidity, obtain an integrated value of the discomfort index until the room temperature reaches the target temperature,
The display unit
For each of the plurality of driving patterns,
Information about the integrated value of the discomfort index is displayed. The air conditioning system control device according to any one of claims 1 to 4 characterized by things. The controller is
Based on the preset correspondence information between the range of integrated values of discomfort index and discomfort level, obtain the discomfort level corresponding to the integrated value of discomfort index,
The display unit
6. The air conditioning system control device according to claim 5, wherein the discomfort level information is displayed. The communication unit acquires the operation data from a plurality of the air conditioners,
The controller is
For each of the plurality of air conditioners, based on the operation data, obtain the current instantaneous power,
The display unit
For each of the plurality of air conditioners,
The air conditioning system control device according to any one of claims 1 to 6, wherein information on the instantaneous power, the room temperature, and the set temperature is displayed. The communication unit acquires the operation data including information on an operation mode and indoor humidity from the plurality of air conditioners,
The controller is
About the air conditioner whose operation mode is cooling operation among the plurality of air conditioners, based on the operation data, obtain a current discomfort index,
The display unit
The air conditioning system control device according to any one of claims 1 to 7, wherein information on the discomfort index is displayed for the air conditioner whose operation mode is cooling operation. The communication unit is
From the demand determination device that demand-controls each air conditioner so that the total value of the instantaneous power of the plurality of air conditioners to be controlled by the air conditioning system control apparatus falls below a predetermined value, one or more air conditioners Obtain a demand signal that indicates a decrease in driving ability,
The controller is
Regardless of the selected operation pattern, the operation capacity of the air conditioner indicated by the demand signal is set to a predetermined operation capacity corresponding to demand control,
Based on the operating capacity and the current room temperature, the time required for the room temperature to reach the target temperature, and the power consumption consumed by the air conditioner until the room temperature reaches the target temperature. Find the quantity
The display unit
The air conditioning system control device according to any one of claims 1 to 8, wherein information on the arrival time and the power consumption during the demand control is displayed.

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