KR20130142185A - Demand control device for facility equipment - Google Patents

Abstract

Provided is a demand control system for equipment that can control equipment in consideration of the comfort of residents. To this end, an operation history storage section for storing the operation history of each of the plurality of equipments, a priority calculation unit for calculating the priority for each of the plurality of equipments based on the operation history of the equipments, and the operation It was comprised so that the selection part which selects the high priority equipment as an equipment to operate so that the sum total of the power consumption of the equipment to be made may not exceed predetermined value.

Description

Demand control device of equipment {DEMAND CONTROL DEVICE FOR FACILITY EQUIPMENT}

The present invention relates to a demand control device for equipment.

It is proposed to group and manage equipment as a demand control apparatus of equipment. The demand control device selects a cyclic command method or a command method for each level, and executes demand control.

When the cyclic instruction method is selected, an instruction of demand control is given cyclically to each group. On the other hand, when the level-specific instruction method is selected, an instruction for demand control is given in accordance with the water solubility level with respect to the peak cut level (see Patent Document 1, for example).

[Patent Document 1] Japanese Unexamined Patent No. 4547776

However, in the demand control apparatus described in Patent Document 1, the equipment is controlled under a predetermined condition. For this reason, the equipment is controlled irrespective of the occupant's comfort.

This invention is made | formed in order to solve the subject as mentioned above, The objective is to provide the demand control apparatus of the equipment which can control a equipment in consideration of the comfort of a resident.

The apparatus for controlling demand of equipment according to the present invention includes an operation history storage unit for storing operation histories of a plurality of equipments, and a priority for each of the plurality of equipments based on the operation history. The priority calculation unit and a selection unit for selecting the high-priority equipment as the equipment to be operated so that the total value of power consumption of the equipment to be operated do not exceed a predetermined value.

According to the present invention, the equipment can be controlled in consideration of the comfort of the occupants.

Fig. 1 is a block diagram of the entire system controlled by the demand control device for equipment in the first embodiment of the present invention.
It is a figure for demonstrating the equipment information database of the demand control apparatus of the equipment in Embodiment 1 of this invention.
It is a figure for demonstrating the sensor group arrangement | sequence information database of the demand control apparatus of the equipment in Embodiment 1 of this invention.
It is a figure for demonstrating the sensor group arrangement | sequence information database of the demand control apparatus of the equipment in Embodiment 1 of this invention.
FIG. 5 is a diagram for explaining the operation history information storage unit of the demand control device for equipment in the first embodiment of the present invention.
FIG. 6 is a view for explaining a demand control history information storage unit of the demand control device of the equipment in the first embodiment of the present invention. FIG.
It is a block diagram for demonstrating the demand control object apparatus motion analysis part of the demand control apparatus of the equipment in Embodiment 1 of this invention.
It is a figure for demonstrating the demand control object apparatus operation | movement analysis part of the demand control apparatus of the equipment in Embodiment 1 of this invention.
Fig. 9 is a block diagram for explaining a device-specific priority calculation parameter database of the demand control device for equipment in Embodiment 1 of the present invention.
It is a block diagram for demonstrating the movable device selection part of the demand control apparatus of the equipment in Embodiment 1 of this invention.
It is a figure for demonstrating the priority correspondence table which the movable device selection part of the demand control apparatus of the equipment in Embodiment 1 of this invention produces | generates.
It is a figure for demonstrating the priority and power consumption correspondence table which the movable apparatus selection part of the demand control apparatus of the equipment in Embodiment 1 of this invention produces | generates.
It is a figure for demonstrating the control policy of the demand control apparatus of the equipment in Embodiment 1 of this invention.
It is a flowchart for demonstrating operation | movement of the demand control apparatus of the equipment in Embodiment 1 of this invention.

EMBODIMENT OF THE INVENTION The form for implementing this invention is demonstrated according to attached drawing. In addition, in each figure, the same code | symbol is attached | subjected to the same or corresponding part, The duplication description is abbreviate | omitted suitably or abbreviate | omitted.

Embodiment 1

Fig. 1 is a block diagram of the entire system controlled by the demand control device for equipment in the first embodiment of the present invention.

In FIG. 1, "1" is a group of equipment of demand control object. The equipment group 1 consists of an air conditioning equipment group, a lighting equipment group, an electric equipment group, a security equipment group, a disaster prevention equipment group, a satellite equipment group, a conveyance equipment group, etc. '2' is a group of electricity meters. The power meter group 2 is provided corresponding to the equipment group 1. The electric power meter group 2 has a function of detecting power consumption of each equipment of the equipment group 1. '3' is the sensor group. The sensor group 3 is provided corresponding to the equipment group 1. The sensor group 3 has a function of detecting an operating state of each equipment of the equipment group 1.

'4' is a device information database. The equipment information database 4 has a function of storing attribute information of each equipment of the equipment group 1. '5' is a sensor group batch information database. The sensor group arrangement information database 5 is provided with the function of storing the information regarding the equipment with which the electric power meter group 2 was connected, and the information regarding the arrangement | positioning of the sensor group 3.

'6' is an operation history information storage unit. The operation history information storage section 6 has a function of storing information on the operation history of each equipment of the equipment group 1. '7' is a demand control history information storage unit. The demand control history information storage unit 7 has a function of storing information on the history of each of the equipments of the equipment control group 1 on demand controlled.

'8' is a demand control target device motion analysis unit. The demand control target device motion analysis unit 8 has a function of analyzing the operation status of each device in the device group 1. The demand control target device motion analysis unit 8 performs a function of normalizing and calculating the priority parameters of the respective equipments of the equipment group 1 at predetermined time intervals based on the analysis result or the like. Equipped.

'9' is a database of parameter estimation parameters for each device. The device-specific priority calculation parameter database 9 has a function of storing the calculation result of the demand control target device motion analysis unit 8. '10' is the moving device selection unit. The movable device selection unit 10 has a function of selecting equipment to be operated at predetermined time intervals based on the contents stored in the priority calculation parameter database 9 for each device. The movable device selection unit 10 has a function of outputting an operation command to the equipment based on the selection result. That is, the movable device selection unit 10 has a function of switching the equipment to be dynamically operated at predetermined time intervals based on the selection result.

Next, the device information database 4 is demonstrated using FIG.

It is a figure for demonstrating the equipment information database of the demand control apparatus of the equipment in Embodiment 1 of this invention.

As shown in FIG. 2, the information on the equipment is stored in the device information database 4. Specifically, the ID, type, model name, operating characteristics of the startup time, and operating characteristics of power consumption of the equipment are associated and stored. For example, the ID of equipment is "1" and the "air-conditioning" equipment whose model name is "AC-1". The starting time of this equipment is "10" minutes. The power consumption of this equipment group 1 is "10" kW.

Next, the sensor group placement information database 5 is demonstrated using FIG. 3 and FIG.

FIG.3 and FIG.4 is a figure for demonstrating the sensor group arrangement | sequence information database of the demand control apparatus of the equipment in Embodiment 1 of this invention.

As shown in FIG. 3, the sensor group arrangement | positioning information database 5 memorize | stores the information about the equipment group 1 to which the electricity quantity meter group 2 was connected as electricity quantity meter information. Specifically, the electric power meter ID and the ID of the equipment connected are stored in association with each other. For example, FIG. 3 shows that electric power meter ID "1" is connected to ID "1" of equipment.

As shown in FIG. 4, the information regarding the arrangement of the sensor group 3 is stored in the sensor group arrangement information database 5 as the sensor group arrangement information. Specifically, the sensor ID, the room, the area, and the copper are associated and stored. For example, FIG. 4 shows that the sensor ID "1" is arranged in the "1" room of the "N" area of "B".

Next, the operation history information storage unit 6 will be described with reference to FIG.

FIG. 5 is a diagram for explaining the operation history information storage unit of the demand control device for equipment in the first embodiment of the present invention.

As shown in Fig. 5, the operation history information storage section 6 stores the operation history of each equipment of the equipment group 1 as the operation history database. Specifically, the ID, the operation rate, the cumulative service time, the last start time, the last stop time, the initial priority, the previous priority, the operation command, the operation state, and the power consumption of the equipment are associated and stored. For example, in what is ID "1" of equipment, initial priority is also "1". The final starting time of the said equipment is "10:00". The final stop time of the said equipment is "09:10" of the next day. The operation command at this time is "cooling: 20 degreeC". In contrast, the operating state at this time is 'cooling: 23 degrees'. Power consumption at this time is "3" kW. The cumulative service time of the equipment is 120 hours. The operation rate of the said equipment is 40%.

Next, the demand control history information storage unit 7 will be described with reference to FIG.

FIG. 6 is a view for explaining a demand control history information storage unit of the demand control device of the equipment in the first embodiment of the present invention. FIG.

As shown in Fig. 6, the demand control history information storage unit 7 stores time, state determination, and IDs of equipments that have been operated. State determination A-C shows the favorable degree of a state. Specifically, it is determined that the smaller the power consumption, the better. State determination A represents the best case. State judgment B represents the worst case. If the condition is good, the equipment to be operated increases. On the other hand, if the condition is bad, the equipment to be operated is reduced. For example, the state determination at time "10:00" is "A". At this time, the ID of the equipment which operated was "1", "12", "33", "14", and "25".

Next, the demand control target device motion analysis unit 8 will be described with reference to FIGS. 7 and 8.

It is a block diagram for demonstrating the demand control object apparatus motion analysis part of the demand control apparatus of the equipment in Embodiment 1 of this invention. It is a figure for demonstrating the demand control object apparatus operation | movement analysis part of the demand control apparatus of the equipment in Embodiment 1 of this invention.

As illustrated in FIG. 7, the demand control target device operation analysis unit 8 includes a power consumption measurement unit 8a, a control target state measurement unit 8b, and a priority parameter calculation unit 8c.

The power consumption measurement unit 8a has a function of detecting the power consumption of each equipment of the equipment group 1 based on the detection result of the power meter group 2 and the information of the sensor group arrangement information database 5. do. The control object state measuring part 8b is equipped with the function which detects the operation state of each equipment of the equipment group 1 based on the detection result of the sensor group 3 and the information of the sensor group arrangement information database 5. do. The priority parameter calculation unit 8c is obtained from the device information database 4, the operation history information storage unit 6, the demand control history information storage unit 7, the power consumption amount measurement unit 8a, and the control target state measurement unit 8b. On the basis of the information of the above, it is provided with a function of calculating the priority parameter for determining the operation priority of all the equipments of the equipment group 1.

As shown in Fig. 8, the parameter group for calculating the priority includes the operation rate, the cumulative service time, the influence on the amount of power, the response time, the priority (initial setting value), the priority (the previous calculation value), and the use of the control target space. It consists of situation, operation efficiency, error from command value, and external environment.

The operation rate is the rate at which equipment provided services. The priority of equipment with high utilization rate is lowered. On the other hand, the priority of the equipment with low operation rate becomes high.

The cumulative service time refers to the cumulative time that the cutting device provided the service. The priority of equipment with a long cumulative service time is lowered.

The influence on the amount of power represents the relationship between the amount of power available at some point and the amount of power consumed with the equipment. When equipment equipment is used, the priority of the equipment is lowered when the amount of remaining power is greatly reduced.

Response time shows the response time of the equipment with respect to the control command of starting or stopping. If the instruction is invalid in relation to the demand control period, for example, the equipment cannot be started within the demand period even if the start command is transmitted, the priority of the equipment is lowered.

Priority (initial setting value) represents the static priority of equipment. This priority is a fixed value. Priority (last calculated value) represents the dynamic priority of equipment. This priority is the latest priority.

The use situation of the space to be controlled refers to the use situation of the space near the equipment. When the space near the equipment is in use, the priority of the equipment is increased. In contrast, if the space near the equipment is not in use, the priority of the equipment is lowered.

Operation efficiency shows the power consumption which put it in operation from the viewpoint of an effect. For example, the relationship between the temperature on the air conditioning surface and the power consumption is summarized in view of the effect. In the case of lighting, the relation of illuminance to power consumption is summarized in view of the effect. The priority of the high-efficiency equipment is high. On the other hand, the priority of the said equipment with low effect becomes low.

The error from the command value is a deviation from the control target. For example, the air-conditioning surface, the difference between the measurement temperature and the set temperature, and the difference between the measurement humidity and the set humidity become a deviating situation. If it is illumination, the difference will be a measurement illuminance and setting illuminance. The priority of equipment with high effectiveness in reducing errors is increased. On the other hand, the priority of the equipment which is low in error reduction is low.

The external environment refers to the latest situation of the external environment in the vicinity of equipment, such as outside temperature, outside humidity, outside light, and wind. The priority of the equipment in the vicinity of which the equipment becomes an operationless or inoperable external environment is lowered.

Next, the priority calculation parameter database 9 for each device is demonstrated using FIG.

Fig. 9 is a block diagram for explaining a device-specific priority calculation parameter database of the demand control device for equipment in Embodiment 1 of the present invention.

As shown in Fig. 9, the priority calculation parameter database 9 for each device stores the priority parameters of each parameter group for each equipment. For example, when the ID of the equipment is "1", the priority regarding the operation rate is "1". The priority regarding the cumulative service time is "1". The priority regarding the influence on the power amount is "2". The priority regarding the influence on the power amount is "2". The priority regarding the response time is "5". The priority regarding the initial priority is "1". Priority regarding last priority is "4". The priority regarding the use of the object space is "5". The priority regarding operation efficiency is "5". The priority regarding the error with the command value is "3". The priority regarding the external environment is "5".

Next, the movable device selection part 10 is demonstrated using FIGS. 10-12.

It is a block diagram for demonstrating the movable device selection part of the demand control apparatus of the equipment in Embodiment 1 of this invention. It is a figure for demonstrating the priority correspondence table which the movable device selection part of the demand control apparatus of the equipment in Embodiment 1 of this invention produces | generates. It is a figure for demonstrating the priority and power consumption correspondence table which the movable apparatus selection part of the demand control apparatus of the equipment in Embodiment 1 of this invention produces | generates.

As shown in FIG. 10, the movable device selecting unit 10 includes an operation step determination unit 10a, a priority weighting unit 10b, a priority unit 10c for each device, and a priority distribution unit 10d. And an expected power consumption calculation unit 10e and a movable device operation command generation unit 10f.

The operation step determination unit 10a has a function of determining an operation step of demand control. The priority weighting unit 10b has a function of calculating priority weights for calculating the overall priority. The priority calculation unit 10c for each device is based on the information of the priority calculation parameter database 9 for each device and the priority calculation weights calculated by the priority weighting calculation unit 10b. It has a function of calculating the overall priority of the equipment.

The priority distribution calculation unit 10d has a function of calculating the priority distribution based on the calculation result of the priority calculation unit 10c for each device, and generating a priority correspondence table. The estimated power consumption calculation unit 10e calculates power consumption in order of priority based on the calculation result of the priority distribution calculation unit 10d and the attribute information of the equipment group 1 stored in the device information database 4. And a function of generating a priority and power consumption correspondence table. The movable device operation command generation unit 10f has a function of selecting each of the equipments of the equipment group 1 to be operated and generating an operation command based on the calculation result of the expected power consumption calculation unit 10e.

As shown in Fig. 11, the priority correspondence table corresponds to the overall priority and the ID of the corresponding equipment. For example, when the overall priority is "1", ID of equipment is "1" and "12".

As shown in Fig. 12, in the priority / power consumption correspondence table, the estimated power consumption when the equipment is operated in the order of high overall priority is calculated. For example, when only the equipment with a comprehensive priority of "1" is operated, the sum of the estimated power consumption amounts is calculated to be 70% of the preset allowable power. Moreover, when operating to the equipment of comprehensive priority "2", the sum total of the estimated power consumption is calculated as 75% of allowable power. In FIG. 12, when operating to the equipment of comprehensive priority "5", the sum total of the estimated power consumption will reach 100% of allowable power.

Next, the control policy in each operation step of demand control is demonstrated using FIG.

It is a figure for demonstrating the control policy of the demand control apparatus of the equipment in Embodiment 1 of this invention.

The control policy of this embodiment is divided into a plurality of steps according to the elapsed time. For example, in FIG. 13, the control policy is divided into first to third steps. In the first step, operation of the equipment is given priority over power consumption. In the second stage, the power consumption and the operation of the equipment are treated equally. In the third stage, power consumption is given priority over operation of equipment.

Next, the operation of the demand control device will be described with reference to FIG. 14.

It is a flowchart for demonstrating operation | movement of the demand control apparatus of the equipment in Embodiment 1 of this invention.

First, in step S1, the operation history information storage part 6, the demand control history information storage part 7, etc. are initialized. Thereafter, the flow advances to step S2 to determine in which stage of the demand control operation the operation step determination unit 10a is located. Thereafter, the priority weighting unit 10b calculates the priority weight based on the determination result of the operation step determination unit 10a.

Specifically, when the demand control operation is the first step, the priority weighting calculation unit 10b gives a high weight to the error, the operation rate, and the cumulative service time of the priority parameter. When the demand control operation is the second stage, the priority weighting calculation unit 10b treats all parameters as equal weights. When the demand control operation is in the third stage, the priority weighting calculation unit 10b gives high weight to the influence on the amount of power and the operation efficiency.

Subsequently, proceeding to step S3, the device-specific priority calculation unit 10c performs a weighted addition process on the initial value of the device-specific priority calculation parameter database 9 to calculate the overall priority of each equipment. Calculate.

Specifically, when the demand control operation is the first step, the priority calculation unit 10c for each device calculates the overall priority of each equipment by giving priority to comfort. When the demand control operation is the second stage, the priority calculation unit 10c for each device calculates the overall priority of each equipment in consideration of the comfort and the total power consumption. When the demand control operation is the third step, the priority calculation unit 10c for each device calculates the overall priority of each equipment by giving priority to the total power consumption.

Thereafter, the flow advances to step S4, and the priority distribution calculating unit 10d creates a priority distribution based on the output of the priority calculating unit 10c for each device. The estimated power consumption calculation unit 10e calculates the estimated power consumption for each priority based on the priority distribution and attribute information of the equipment in the device information database 4. Specifically, the sum of power consumption from the highest level (level 1) to the level is calculated as the ratio of the allowable power in demand control.

Subsequently, the flow proceeds to step S5, and the movable device operation command generation unit 10f determines based on the estimated power consumption for each priority, up to which priority the equipment is to be operated. Thereafter, the movable device operation command generation unit 10f generates an operation command for the device to be operated. For example, the operation command for air conditioning includes an operation mode and a set temperature. As the operation mode, cooling and the like are set. 20 degreeC etc. are set as preset temperature. Thereafter, the movable device operation command generation unit 10f outputs an operation command to the device to be operated. At this time, the information concerning the operation command is stored in the operation history information storage unit 6.

Subsequently, the process proceeds to step S6, where the demand control target device motion analysis unit 8 analyzes the operation status of the equipment that has received the operation command. The demand control target device motion analysis unit 8 collects information from the power meter group 2 and the sensor group 3.

Subsequently, the flow proceeds to step S7, and the power consumption amount measurement unit 8a calculates the power consumption of each equipment from the information of the power meter group 2 and the power meter information in the sensor group arrangement information database 5. The control target state measuring unit 8b obtains the control target state (temperature, illuminance, etc.) from the information of the sensor group 3 and the sensor group arrangement information in the sensor group arrangement information database 5.

Subsequently, the process proceeds to step S8, where the priority parameter calculation unit 8c outputs the control target state measurement unit 8b, the power consumption amount measurement unit 8a, the operation history information storage unit 6, and the demand control history information storage unit. Based on the information stored in (7), the parameter group for priority calculation is calculated | required according to the predetermined priority update policy. These parameters are normalized in five steps as shown in FIG. After that, the process returns to Step S2 and the above operation is repeated.

According to Embodiment 1 described above, the priority of the equipment to operate is calculated based on the operation | movement history of equipment. For this reason, the equipment can be dynamically controlled in consideration of both the allowable electric power and the comfort of the occupant.

Moreover, the priority of the equipment with low operation rate or the equipment with short cumulative service time becomes high. For this reason, all the equipments can be operated without bias.

In addition, the weight of the operation history and power consumption of the equipment changes with time. Specifically, as the cumulative value of power consumption of the equipment increases, the weight of the power consumption at the time of calculating the priority increases so that the priority of the device with less power consumption increases. For this reason, the equipment can be controlled according to the actual state.

In addition, the priority of the equipment may be calculated at a time interval longer than the response time of the equipment having the shortest response time among the plurality of equipment. In this case, the load at the time of calculating a priority can be reduced, considering the comfort of a resident.

As mentioned above, the demand control apparatus of the equipment which concerns on this invention can be used for the system which controls equipment in consideration of the comfort of a resident.

1 equipment
2 amount of electricity meter group
3 sensor group
4 Device Information Database
5 Sensor Group Batch Information Database
6 operation history information preservation part
7 Demand control history information storage
8 Demand control target device motion analysis unit
8a Power Consumption Measurement Unit
8b Control target state measuring unit
8c priority parameter calculation
9 Device Priority Estimation Parameter Database
10 Moving device selection
10a operation step determination unit
10b priority weighted mountain government
10c device priority
10d priority distribution calculation
10e Estimated Power Consumption
10f movable device operation command generation unit

Claims (5)

An operation history preserving unit for storing operation histories of the plurality of equipments;
A priority calculation unit for calculating a priority for each of the plurality of equipments based on the operation history;
Selection unit for selecting a high-priority equipment as the equipment to operate so that the total power consumption of the equipment to be operated does not exceed a predetermined value
Demand control device for equipment, characterized in that provided with. The method according to claim 1,
The said priority calculation part raises the priority of the equipment of low operation rate, or the equipment of short cumulative operation time, The demand control apparatus of the equipment. The method according to claim 1 or 2,
The priority calculation unit uses the response time of the equipment as a variable when calculating the priority, and at a time interval longer than the response time of the equipment having the shortest response time among the plurality of equipment, A demand control device for equipment, characterized in that the priority of equipment is calculated. The method according to any one of claims 1 to 3,
The priority calculation unit uses the power consumption of the equipment as a parameter when calculating the priority to change the weight of the operation history and the power consumption of the equipment at the time of calculating the priority over time. A demand control device for equipment. The method of claim 4,
The priority calculation unit increases the weight of the power consumption when calculating the priority so that the priority of the equipment with less power consumption increases as the cumulative value of power consumption of the equipment increases. Demand control device of equipment.

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