JP4032903B2 - Target power control system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a target power control system, a control program, and a control method for preventing an aggregate power consumption of a plurality of groups from exceeding a target supply power of the aggregate in a group composed of a plurality of groups.
[0002]
[Prior art]
  A demand control device and a demand monitoring device are widely known as representative techniques for preventing the power used by the equipment from exceeding the target power supply in a factory or building having the equipment. FIG. 1 shows a case where the demand control device 140 is installed in a factory composed of a plurality of small factories 11a, 11b, and 11c as an example. As shown in FIG. 1, the demand control device 140 is used by being connected to a contract meter 150, equipment 1 a, 2 a, 3 a, 4 b, 5 b, 6 b, 7 c, 8 c, 9 c and an alarm device 161. Here, control priority is given to the equipment 1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, 9c.
[0003]
  The demand control device 140 connected in this way first changes the total power supplied to the equipment 1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, 9c based on the data obtained from the contract meter 150. To monitor. Next, the demand control device 140 continuously predicts the maximum supply power to the equipment 1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, and 9c for each demand period. Then, when there is a possibility that the predicted maximum supply power exceeds the target supply power, the demand control device 140 issues an alarm by the alarm device 161 and the equipment devices 1a, 2a, The operation is stopped in order from 3a, 4b, 5b, 6b, 7c, 8c, 9c. Thereafter, when there is a surplus in supply power, the demand control device 140 automatically returns power supply to the equipment 1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, 9c (for example, (See Patent Document 1).
[0004]
  On the other hand, the demand monitoring device is basically the same as the demand control device 140, but when there is a risk of exceeding the target supply power, the demand monitoring device is not automatically controlled but broadcasts this to factory personnel. Is transmitted in order to manually shut off the power sequentially from the equipment devices 1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, and 9c having a high control priority (for example, Patent Document 2). reference.).
[0005]
[Patent Document 1]
          Japanese Patent Laid-Open No. 09-261863 (Section 4-5, FIG. 1)
[0006]
[Patent Document 2]
          Japanese Patent Laid-Open No. 10-240360 (Section 2-5, FIG. 1)
[0007]
[Problems to be solved by the invention]
  In this way, the demand control device 140 can prevent the total power usage of the equipment 1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, 9c from exceeding the target supply power. However, if a specific person sets the target supply power of the factory in the demand control device 140 and adopts a form in which power management is automatically performed thereafter, the small factory members are assigned to the small factory 11a, 11b, It is impossible to know the degree of contribution to the energy saving and cost saving activities of 11c, and it is impossible to tackle specific energy saving and cost saving activities.
[0008]
  The problem of the present invention is to prevent the total power consumption of a plurality of groups from exceeding the target supply power of the aggregate in an aggregate consisting of a plurality of groups, such as a factory consisting of a plurality of small factories and a building consisting of a plurality of tenants. In addition, the target power control system, control program, and control method that each group member can know the degree of contribution to the group's energy-saving and cost-saving activities and can work on specific energy-saving and cost-saving activities Is to provide.
[0009]
[Means for Solving the Problems]
  A target power control system according to claim 1 includes a plurality of facility devices, a group target power setting device, andTarget powerA control device is provided. The plurality of facility devices are classified into a plurality of groups. Multiple group target power settingIn the equipmentIs the target power for each groupButSettingIsTheThe target power control device is communicatively connected to a plurality of facility devices and the plurality of group target power setting devices. The target power control apparatus includes supply power measurement means, expected supply power calculation means, difference power calculation means, difference power distribution means, and target power change means. The supply power measuring means measures the total supply power to the plurality of groups in synchronization with the demand time limit. The expected supply power calculation means calculates the expected supply power in the demand time period based on the data measured by the supply power measurement means. The difference power calculation means calculates the difference between the expected supply power and the target supply power of the aggregate at the time when the expected supply power is predicted to exceed the target supply power of the aggregate composed of all groups in the demand time period. The differential power distribution unit distributes the differential power calculated by the differential power calculation unit to each of the plurality of groups. Here, as a method for allocating the differential power, a distribution method based on the ratio of the target power of each of the plurality of groups, a distribution method based on a ratio of the difference between the target power of each of the plurality of groups and the used power, and an even distribution method may be considered. .
[0010]
  This target powerControl systemsoCan set target power for each of multiple groups. For this reason,Each group member can know the degree of contribution of the group to energy saving and cost saving activities, and can work on specific energy saving and cost saving activities.In this target power control system, the supply power measurement means measures the total supply power to the plurality of groups in synchronization with the demand time limit. Then, the expected supply power calculation means calculates the expected supply power in the demand time period based on the data measured by the supply power measurement means. For this reason, it is possible to quickly predict and cope with the total supply power to the plurality of groups exceeding the target supply power of the aggregate. Further, in this target power control system, when the difference power calculation means predicts that the expected supply power exceeds the target supply power of the aggregate in the demand time period, the difference between the predicted supply power and the target supply power of the aggregate Is calculated. The differential power distribution unit distributes the differential power to each of the plurality of groups. Then, the target power changing means reduces the target power of each of the plurality of groups by the power distributed by the differential power distribution means in synchronization with the demand time period.Because of thisTarget powerControl systemsoEven in situations where the peak power usage time zones of several groups overlap and the total power usage of multiple groups exceeds the target supply power of the aggregate, aggregation is achieved by reducing the target power of each of the multiple groups. The target power supply of the body can be observed.Further, in this target power control system, only the minimum necessary power is distributed to each of the plurality of groups so that the power supplied to the plurality of groups does not exceed the target supply power of the aggregate. For this reason, in this target power control system, the burden on each of the plurality of groups can be reduced.Further, if demand monitoring means and demand control means are introduced into each of the plurality of groups and the target power of each of the plurality of groups can be observed, more comfortable power management can be performed.
[0011]
  A target power control system according to claim 2 is the target power control system according to claim 1,The group target power setting apparatus has demand control means. The demand control means performs demand control for a plurality of facility devices belonging to the group.
[0012]
  A target power control system according to claim 3 is the target power control system according to claim 1 or 2,The differential power distribution unit distributes the differential power to each of the plurality of groups based on the target power ratio of each of the plurality of groups.
[0013]
  Target power control according to claim 4The system is a target power control system according to claim 1 or 2, wherein the differential power distribution means calculates the differential power based on a ratio of a value obtained by subtracting the used power of each of the plurality of groups from the target power of each of the plurality of groups. Allocate to multiple groups.
[0014]
  Target power control according to claim 5A target power control system according to claim 1 or 2. The differential power distribution unit distributes the differential power equally to each of the plurality of groups.
[0015]
  Claim6The target power control system according to claim 1Any of 5A control system according to claim 1,The target power controller isA power data storage means, a power data processing means and a power data output means;Have. The power data storage means stores the power data in time series. The power data processing means processes the power data stored in the power data storage means. The power data output means outputs the processed data obtained by the power data processing means.
[0016]
  here,Target powerControl systemsoCan store, process, and output power usage data for multiple groups and total power consumption data for multiple groups. For this reason,It is possible to consider the power usage peak time zone of each of the plurality of groups, the total power usage peak time zone of the plurality of groups, and the like.ThereforeIn addition, it is possible to perform activities such as flattening the total power used by a plurality of groups by shifting the power use peak time period of each of the plurality of groups through discussions between the plurality of groups.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
<First Embodiment>
  FIG. 2 shows the configuration and control form of the target power control system 30 according to the first embodiment of the present invention. The target power control system 30 illustrated here prevents the total power used by the small factories 11a and 11b from exceeding the target supply power of the entire factory 21 in the factory 21 including the small factory A11a and the small factory B11b. In addition, the target power control system 30 can be used by personnel belonging to small factories to know the degree of contribution of the small factories 11a and 11b to energy saving and cost saving activities, and to make specific energy saving and cost saving activities possible. .
[0018]
  [Components of target power control system 30 and description thereof]
  A target power control system 30 shown in FIG.,The contract meter 150 includes power data management computers 101, 111, 121, a power meter 190, equipment 1 a, 2 a, 3 a, 4 b, 5 b, 6 b, an alarm device 161, a small factory computer 41, and a printer 123. Here, the priority order to receive control is set to the equipment 1a, 2a, 3a, 4b, 5b, 6b.
[0019]
  A control program 130 is installed in the target power control device 170. The target power control apparatus 170 executes the control program 130 by the program execution unit 172.
[0020]
  The control program 130 includes a small factory target power input routine 42, a contract meter reading routine 220, a small factory power meter reading routine 230, a small factory demand monitoring routine 240, a target power recalculation routine 52, and a recalculation target power transmission routine 53. ing. The small factory target power input routine 42 requests that the small factory computer 41 installed in the small factory 11a, 11b respectively input the target power. The contract meter reading routine 220 receives and stores the power supply data from the contract meter 150 in time series. The small factory power meter reading routine 230 receives and stores the power usage data of the small factories 11a and 11b in time series from the power meters 190 installed in the small factories 11a and 11b, respectively. The small factory demand monitoring routine 240 includes an expected power consumption calculation routine 241. The predicted usage power calculation routine 241 calculates the expected usage power of each of the small factories 11 a and 11 b based on the usage power data received by the small factory power meter reading routine 230.
[0021]
  Then, when the total power consumption of the small factories 11a and 11b exceeds the expected power consumption of the small factories 11a and 11b, a control command broadcast is performed. Then, a small factory staff member cuts the power supply of the equipment devices 1a, 2a, 3a, 4b, 5b, and 6b having high priority while looking at the power meter 190 to reduce the used power to a predetermined level. Thereafter, when there is a margin in the total power consumption of the small factories 11a and 11b, a control release broadcast is performed. Then, the small factory member turns on the power to the equipment 1a, 2a, 3a, 4b, 5b, 6b and resumes operation. (Hereinafter referred to as demand monitoring in this embodiment.)
  When the supply power to the factory 21 measured by the contract meter 150 reaches the target supply power excess prevention level set in the target power control device 170, the target power recalculation routine 52 is a small factory target power input routine. The calculation which cuts the target electric power of each small factory 11a and 11b input into 42 by a predetermined ratio is performed. The recalculated target power transmission routine 53 transmits the recalculated target power to the small factory computers 41 of the small factories 11a and 11b, and further performs target power change notification broadcasting.
[0022]
  The power data management computers 101, 111, 121 store power data. In addition, software for processing stored data is installed in the power data management computers 101, 111, and 121. Furthermore, a printer 123 that prints stored data and processed data on a sheet is connected to the power data management computers 101, 111, and 121.
[0023]
  [Target power control system connection form]
The target power control device 170 is connected to the contract meter 150, the power data management computers 101, 111, 121, the power meter 190, the broadcaster 161, and the small factory computer 41. The equipment 1a, 2a, 3a, 4b, 5b, 6b is connected to a contract meter 150 and a power meter 190. The printer 123 is connected to the power data management computers 101, 111, and 121.
[0024]
  [Control form of target power control system]
A control mode of the target power control system 30 shown in FIG. 2 will be described using the flowcharts shown in FIGS. 3 and 4. Here, FIG. 3 shows a flow of processing in which the target power control device 170 observes the target powers of the small factories 11a and 11b set by the small factories 11a and 11b, respectively. FIG. 4 shows a process flow in which the target power control device 170 complies with the target power of the entire factory 21.
[0025]
  (1) Control of target power in small factories 11a and 11b (Process P)
  In the flowchart shown in FIG. 3, in step S1, the small factory target power input routine 42 requests that the small factory computer 41 installed in each small factory 11a, 11b input target power. Then, the small factory affiliation staff inputs the target power examined in the small factory 11a and 11b from each small factory computer 41. In step S2, the small factory power meter reading routine 230 receives and stores the power usage data of each of the small factories 11a and 11b in time series from the power meter 190 installed in each of the small factories 11a and 11b. In step S3, the predicted use power calculation routine 241 provided in the small factory demand monitoring routine 240 calculates the predicted use power of each of the small shops 11a and 11b based on the previous use power data. Then, in step S4, it is confirmed whether or not the predicted power consumption of each of the small factories 11a and 11b exceeds the target power of each of the small factories 11a and 11b. As a result of the confirmation in step S4, if the predicted power usage of each of the small factories 11a and 11b does not exceed the target power of each of the small factories 11a and 11b, the process returns to step S2. As a result of the confirmation in step S4, if the predicted power usage of each of the small factories 11a and 11b exceeds the target power of each of the small factories 11a and 11b, a control command broadcast is performed in step S5. Then, in step S6, a small factory staff member cuts the power of the equipment devices 1a, 2a, 3a, 4b, 5b, and 6b having a high priority while looking at the power meter 190 to reduce the used power to a predetermined level. . In step S7, it is confirmed whether or not the expected power consumption of each of the small factories 11a and 11b is less than the target power of each of the small factories 11a and 11b. As a result of the confirmation in step S7, if the predicted power consumption of each of the small factories 11a and 11b is not yet lower than the target power of each of the small factories 11a and 11b, the process returns to step S5. As a result of the confirmation in step S7, if the predicted power usage of each of the small factories 11a and 11b is less than the target power of each of the small factories 11a and 11b, a control release broadcast is performed in step S8. And in step S9, the small factory affiliation personnel turn on the equipment 1a, 2a, 3a, 4b, 5b, 6b and restart the operation.
[0026]
  (2) Control of target power supply in the entire factory 21
  In the flowchart shown in FIG. 4, in step S10, the contract meter reading routine 220 receives and stores the total power supply data from the contract meter 150 to the small factories 11a and 11b in time series. In step S11, it is confirmed whether the total power consumption of the small factories 11a and 11b has reached the target supply power excess prevention level of the entire factory 21. As a result of the confirmation in step S11, if the total power consumption of the small factories 11a and 11b has not reached the target supply power excess prevention level, the process returns to step S10. As a result of the confirmation in step S11, if the total power consumption of the small factories 11a and 11b has reached the target supply power excess prevention level, the target power of each of the small factories 11a and 11b is recalculated in step S12. In the recalculation, the ratio of the power used by the small factory A11a and the small factory B11b at that time is taken and the target supply power of the entire factory 21 is divided by the ratio. In step S13, the recalculated target powers of the small factories 11a and 11b are transmitted to the small factory computer 41, respectively. In step S14, the target power change notification broadcast is performed with the transmission in step S12 as a trigger. In S15, the small factory computer 41 of each small factory 11a, 11b displays the target power of each small factory 11a, 11b recalculated. In step S1 of process P, the recalculated target power is input again. The subsequent processing is performed as described in the processing P.
[0027]
  [Power data management]
  Here, the power data management computers 101, 111 and 121 receive and store the power values read by the contract meter reading routine 220 and the small factory power meter reading routine 230.
[0028]
  [Features of target power control system 30]
  (1)
  Here, the small factory target power input routine 42 in the control program 130 executed by the target power control device 170 is transferred to the small factory computer 41 installed in each small factory 11a, 11b. Require input of target power. Therefore, the staff belonging to the small factory can set the target power in each of the small factory 11a and 11b. For this reason, the staff belonging to the small factory can know the degree of contribution to the energy saving and cost saving activities of the small factory 11a and 11b, and can work on specific energy saving and cost saving activities.
[0029]
  (2)
  Here, the small factory demand monitoring routine 240 in the control program 130 executed by the target power control apparatus 170 uses the equipment 1a, 2a, 3a, 4b, 5b, 6b installed in the small factory 11a, 11b. When the electric power is expected to exceed the target electric power of each of the small factories 11a and 11b, this is transmitted to the personnel belonging to the small factory by a control command broadcast to supply power to the equipment 1a, 2a, 3a, 4b, 5b and 6b. Is cut off manually to reduce the power consumption to a predetermined level. Therefore, the target power control system 30 can observe the target power of each of the small factories 11a and 11b.
[0030]
  (3)
  Here, when the total power consumption of the small factories 11a and 11b measured by the contract meter 150 reaches the target supply power excess prevention level of the whole plant 21, the target power recalculation routine 52 performs the small factories 11a and 11b, respectively. The calculation is performed to cut the target power of a predetermined percentage. Then, the recalculated target power transmission routine 53 transmits the recalculated target powers of the small factories 11a and 11b to the small factory computers 41 respectively installed in the small factories 11a and 11b. Then, the transmission is triggered and a target power change notification broadcast is performed to notify personnel belonging to the small factories 11a and 11b that the target power has been changed. Then, the transmitted target power is displayed on the small factory computer 41. Further, in order to comply with the newly set target power, the small factory demand monitoring routine 240 transmits this fact to the small factory staff by a control command broadcast, and the equipment 1a, 2a, 3a, 4b, 5b, 6b. It is urged to shut down the power supply to reduce the power consumption to a predetermined level. Therefore, the target power control system 30 can comply with the target power of the entire factory 21.
[0031]
  (4)
  Here, the power data management computers 101, 111 and 121 receive and store the power values read by the contract meter reading routine 220 and the small factory power meter reading routine 230. In addition, software for data processing is installed in the power data management computers 101, 111, and 121. Therefore, it is possible to process the stored data. Here, for example, if the previous data is processed to create a diagram showing the power data of the small factory A11a, small factory B11b, and the entire factory 21 in time series, the power consumption peaks of the small factories 11a and 11b respectively. The time zone and the total power usage peak time zone of the small factories 11a and 11b can be examined. For this reason, activities such as flattening the total power consumption of the small factories 11a and 11b by shifting the peak power hours of the small factories 11a and 11b by negotiating between the small factories 11a and 11b. It can be performed.
[0032]
  <Modification of First Embodiment>
  (1) Modification of target power supply control in the entire factory 21
  In the first embodiment, the target supply power excess prevention level is set with respect to the total supply power to the small factories 11a and 11b and the target supply power is observed in a threshold manner. A form like the demand control device 140 described may be used. That is, when the expected total supply power is calculated based on the total supply power to the small factories 11a and 11b received and stored by the contract meter reading routine 220, and the expected total supply power exceeds the target supply power, That is, the target power of each of the small factories 11a and 11b is changed.
[0033]
  (2) Modification of computer system
  In the first embodiment, the power data management computers 101, 111, and 121 are connected to the target power control apparatus 170, but the following may be considered as an alternative to this. The data server is connected to the target power control device 170, and the power data is stored in this data server. Then, the small factory computers 41 respectively installed in the small factories 11a and 11b are connected to the data server via the network. Further, software for data processing is installed in each of these small factory computers 41 and a printer 123 is connected. In this way, when processing and outputting data, it is convenient because data processing work and data output work can be performed in the small factories 11a and 11b.
[0034]
  Second Embodiment
FIG. 5 shows the configuration and control form of the target power control system 31 according to the second embodiment of the present invention. The target power control system 31 exemplified here prevents the total power used by the tenants 12a and 12b from exceeding the target supply power of the entire building 22 in the building 22 including the tenant A 12a and the tenant B 12b, and the tenant This is a target power control system 31 in which the affiliated staff can know the degree of contribution of the affiliated tenants 12a and 12b to the energy saving and cost saving activities and can work on specific energy saving and cost saving activities.
[0035]
  [Components of target power control system 31 and description thereof]
  The target power control system 31 shown in FIG. 5 includes a target power control device 171, a contract meter 150, a demand control device 141, a power meter 190, equipment 1 a, 2 a, 3 a, 4 b, 5 b, 6 b, an alarm lamp 162, and a computer 103. , 112, 122 and a printer 123. Here, the priority order which receives demand control is set to the equipment 1a, 2a, 3a, 4b, 5b, 6b.
[0036]
  The target power control device 171 includes a supply power measurement unit 60, an expected supply power calculation unit 70, a differential power calculation unit 80, a differential power distribution unit 90, a target power change unit 51, and a power data storage unit 102. The supply power measuring unit 60 receives supply power data from the contract meter 150 in synchronization with the demand time limit. The expected supply power calculation unit 70 calculates the expected supply power in the demand time period based on the data measured by the supply power measurement unit 60. The difference power calculation unit 80 calculates the difference between the predicted supply power and the target supply power of the building 22 when the predicted supply power is predicted to exceed the target supply power of the building 22 in the demand time period. The differential power distribution unit 90 distributes the differential power calculated by the differential power calculation unit 80 to each of the tenant A 12a and the tenant B 12b. Then, the target power change unit 51 reduces the target power of each of the tenants 12a and 12b by the power distributed by the differential power distribution unit 90 in synchronization with the demand time period.In additionHere, the target power changing unit 51 transmits the target power reduced by the power distributed by 90 by the differential power distribution unit to the demand control device 141, and changes the target power of the demand control device 141.
[0037]
  The demand control device 141 includes a tenant target power setting unit 43, an expected power usage calculation unit 250, and a target power display unit 260. The tenant target power setting unit 43 sets the target power of the tenants 12a and 12b. The expected usage power calculation unit 250 calculates the expected usage power of the tenants 12a and 12b based on the usage power data obtained from the power meter 190 provided in the tenants 12a and 12b. Then, when the expected power usage of the tenants 12a and 12b exceeds the target power of the tenants 12a and 12b, the alarm lamp 162 is turned on. Then, the power supply is shut off in order from the highest priority among the equipment installed in the tenants 12a and 12b. Thereafter, when there is a surplus in the power supply, the equipment devices 1a, 2a, 3a, 4b, 5b, and 6b are turned on to restart the equipment devices 1a, 2a, 3a, 4b, 5b, and 6b. (Hereinafter referred to as demand control in this embodiment.) The target power display unit 260 displays the target power.
[0038]
  Software that processes data stored in the power data storage unit 102 of the target power control device 171 is installed in the computers 103, 112, and 122. The computers 103, 112, and 122 include a printer 123 that prints data stored in the power data storage unit 102 or data processed by software.
[0039]
  [Connection form of target power control system 31]
  Here, the target power control device 171 is connected to the contract meter 150, the demand control device 141, and the computers 103, 112, and 122. Here, the computers 103, 112, and 122 are connected to the target power control apparatus 171 via the network 270. The equipment 1a, 2a, 3a, 4b, 5b, 6b is connected to a contract meter 150 and a power meter 190. The printer 123 is connected to the computers 103, 112, and 122.
[0040]
  [Control form of target power control system 31]
  Here, it is shown in FIG.Demand control device 141 andA control mode of the target power control device 171 will be described with reference to flowcharts shown in FIGS. 6 and 7. Here, FIG.Demand control device 141Shows the flow of processing to observe the target power of each of the tenants 12a and 12b set by the tenants 12a and 12b. FIG. 7 shows a flow of processing in which the target power control device 171 observes the target power of the entire building 22.
[0041]
  (1) Control of target power in the tenants 12a and 12b (processing Q)
  In the flowchart shown in FIG. 6, in step S <b> 16, the tenant member inputs the target power examined by each of the tenants 12 a and 12 b to the tenant target power setting unit 43. In step S17, the set target power is displayed on the target power display unit 260. In step S18, the expected usage power calculation unit 250 calculates the expected usage power of each of the tenants 12a and 12b based on the usage power data obtained from the power meter 190 installed in each of the tenants 12a and 12b. In step S19, it is confirmed whether the expected power usage of each of the tenants 12a and 12b exceeds the target power of each of the tenants 12a and 12b. As a result of the confirmation in step S19, if the predicted usage power of each of the tenants 12a and 12b does not exceed the target power of each of the tenants 12a and 12b, the process returns to step S18. As a result of the confirmation in step S19, if the predicted power usage of each of the tenants 12a and 12b exceeds the target power of each of the tenants 12a and 12b, the alarm lamps 162 respectively installed in the tenants 12a and 12b are displayed in step S20. Turn on and notify the tenant staff that demand control will be performed. In step S21, demand control is performed. In step S22, it is confirmed whether the expected power usage of each of the tenants 12a and 12b is lower than the target power of the tenant. As a result of the confirmation in step S22, if the predicted usage power of each of the tenants 12a and 12b is not yet lower than the target power of each of the tenants 12a and 12b, the process returns to step S21. As a result of the confirmation in step S22, if the expected power usage of each of the tenants 12a and 12b is lower than the target power of each of the tenants 12a and 12b, in step S23, the demand control device 141 causes the facility equipment 1a, The operation of 2a, 3a, 4b, 5b, 6b is resumed.
[0042]
  (2) Control of target supply power in the entire building 22
  In the flowchart shown in FIG. 7, in step S24, the supply power measurement unit 60 receives supply power data from the contract meter 150 in synchronization with the demand time limit. In step S <b> 25, the expected supply power calculation unit 70 calculates the expected supply power in the demand time period based on the data measured by the supply power measurement unit 60. In step S <b> 26, it is confirmed whether the expected supply power exceeds the target supply power of the building 22. If the predicted supply power of the building 22 does not exceed the target supply power of the building 22 as a result of the confirmation in step S26, the process returns to step S24. If the predicted supply power of the building 22 exceeds the target supply power of the building 22 as a result of the confirmation in step S26, the alarm lamp 162 installed in the tenants 12a and 12b is turned on in step S27. In step S <b> 28, the difference power calculation unit 80 calculates the difference between the expected supply power and the target supply power of the building 22. In step S29, the differential power distribution unit 90 distributes the differential power calculated by the differential power calculation unit 80 equally to the tenant A12a and the tenant B12b. In step S30, the target power changing unit 51 reduces the target power of each of the tenants 12a and 12b by the power distributed by the differential power distribution unit 90 in synchronization with the demand time period. In step S <b> 31, the target power changing unit 51 transmits the target power reduced by the power distributed by the differential power distribution unit 90 to the demand control device 141. In step S <b> 32, the tenant target power setting unit 43 changes the target power of the demand control device 141 and displays the target power on the target power display unit 260. In step S16 of process Q, the recalculated target power is re-input. The subsequent processing is performed as described in the processing Q.
[0043]
  [Power data management]
  Here, the power data storage unit 102 built in the target power control device 171 stores the power values received from the contract meter 150 and the power meter 190.
[0044]
  [Features of target power control system]
  (1)
  The demand control device 141 is in the tenants 12a and 12b. Personnel belonging to the tenants 12a and 12b can easily change the connection between the equipment devices 1a, 2a, 3a, 4b, 5b, and 6b and the demand control device 141, so the energy saving and cost-saving activities of the building 22 are actively carried out. Can be done.
[0045]
  (2)
  Here, the power data storage unit 102 of the target power control apparatus 171 stores the power data received from the contract meter 150 and the power meters 190 of the tenants 12a and 12b in time series. The computers 103, 112, and 122 provided in the tenants 12 a and 12 b are connected to the power data storage unit 102 via the network 270. Therefore, the computers 103, 112, and 122 can download power data from the power data storage unit 102. Moreover, since the software which can process electric power data is installed in computer 103,112,122, the downloaded data can be processed. The downloaded data can also be printed by the printer 123.
[0046]
  <Modification of Second Embodiment>
  (1) Modification of alarm lamp 162
  In the second embodiment, the alarm lamp 162 is used to notify the tenant staff that the target power has been changed, but instead, this may be notified by broadcasting.
[0047]
  (2) Modification of differential power distribution unit 90
  In the second embodiment, the differential power distribution unit 90 equally distributes the differential power calculated by the differential power calculation unit 80 to the tenants 12a and 12b. However, the differential power distribution unit 90 calculates the differential power based on the ratio of the target power. Alternatively, the difference power may be distributed based on the ratio of the difference in power used in each of the tenants 12a and 12b from the target power of each of the tenants 12a and 12b.
[0048]
  Also, if any of the tenants 12a and 12b is in the peak power usage period and is likely to exceed the target supply power of the building 22, the target power of the tenants 12a and 12b not in the peak usage power period is temporarily It is also conceivable that the target power of the tenants 12a and 12b in the power usage peak time zone is given a margin by that amount. In this way, not only can the target power be changed by simple calculation, but if the target power is changed according to the situation, it is possible to cope with a sudden change in the power usage environment of the tenants 12a and 12b. Become.
[0049]
【The invention's effect】
  A target power control system according to claim 1soCan set target power for each of multiple groups. For this reason,Each group member can know the degree of contribution of the group to energy saving and cost saving activities, and can work on specific energy saving and cost saving activities.In this target power control system, the supply power measurement means measures the total supply power to the plurality of groups in synchronization with the demand time limit. Then, the expected supply power calculation means calculates the expected supply power in the demand time period based on the data measured by the supply power measurement means. For this reason, it is possible to quickly predict and cope with the total supply power to the plurality of groups exceeding the target supply power of the aggregate. Further, in this target power control system, when the difference power calculation means predicts that the expected supply power exceeds the target supply power of the aggregate in the demand time period, the difference between the expected supply power and the target supply power of the aggregate is calculated. Calculate the difference. The differential power distribution unit distributes the differential power to each of the plurality of groups. Then, the target power changing means reduces the target power of each of the plurality of groups by the power distributed by the differential power distribution means in synchronization with the demand time period.Because of thisThis target powerControl systemsoEven in situations where the peak power usage time zones of several groups overlap and the total power usage of multiple groups exceeds the target supply power of the aggregate, aggregation is achieved by reducing the target power of each of the multiple groups. The target power supply of the body can be observed.Further, in this target power control system, only the minimum necessary power is distributed to each of the plurality of groups so that the power supplied to the plurality of groups does not exceed the target supply power of the aggregate. For this reason, in this target power control system, the burden on each of the plurality of groups can be reduced.Further, if demand monitoring means and demand control means are introduced into each of the plurality of groups and the target power of each of the plurality of groups can be observed, more comfortable power management can be performed.
[Brief description of the drawings]
FIG. 1 is a block diagram of a conventional target power control system (demand control system).
FIG. 2 is a block diagram of a target power control system according to the first embodiment of the present invention.
FIG. 3 is a flowchart showing a flow for controlling target power in a small factory according to the first embodiment of the present invention.
FIG. 4 is a flowchart showing a flow of controlling target supply power for the entire factory according to the first embodiment of the present invention.
FIG. 5 is a block diagram of a target power control system according to a second embodiment of the present invention.
FIG. 6 is a flowchart showing a flow of controlling target power of a tenant according to the second embodiment of the present invention.
FIG. 7 is a flowchart showing a flow for controlling the target supply power of a building according to the second embodiment of the present invention.
[Explanation of symbols]
  1a, 2a, 3a, 4b, 5b, 6b, 7c, 8c, 9c Equipment
  11a, 11b, 11c Small factory
  12a, 12b Tenant
  21 factory
  22 Building
  41 Computer for small factory (multi-group target power setting means)
  42 Small factory target power input routine (multi-group target power setting means)
  43 Tenant target power input routine (multi-group target power setting means)
  52 Target power recalculation routine
  53 Recalculation target power transmission routine
101 Power data management computer (power data storage means)
102 Power data storage unit (power data storage means)
103 Computer (Power data storage means)
111 Power Data Management Computer (Power Data Processing Means)
112 Computer (Power data processing means)
121 power data management computer (power data output means)
122 Computer (Power data output means)
123 Printer (Power data output means)
141 Demand control device
150 Contract meter
161 Alarm
162 Alarm lamp
170, 171 Target power control device
172 Program execution part
190 Electric power meter
220 Contract meter reading routine
230 Small Factory Power Meter Reading Routine
240 Small Factory Demand Monitoring Routine
241 Expected power consumption calculation routine
250 Expected power consumption calculator
260 Target power display
270 network

Claims (6)

A plurality of equipment (1a, 2a, 3a, 4b, 5b, 6b) separated into a plurality of groups;
A plurality of group target power setting devices (41, 42, 43) for setting a target power for each of the plurality of groups (11a, 11b, 12a, 12b);
Supply power measuring means (60) connected to the plurality of facility devices and the plurality of group target power setting devices, and measuring supply power to the plurality of groups in synchronization with a demand time period, and the supply power measurement An expected supply power calculation means (70) for calculating an expected supply power in the demand time period based on data measured by the means, and an aggregate (21, 22) in which the expected supply power is composed of all groups in the demand time period. When it is predicted that the target supply power will be exceeded, the difference power calculation means (80) for calculating the difference between the expected supply power and the target supply power of the aggregate, and the difference calculated by the difference power calculation means Differential power distribution means (90) for distributing power to each of the plurality of groups, and each of the plurality of groups in synchronization with the demand time period The target power, target power control system and a target power controller (51, 52, 53) and a target power changing means for reducing only power allocated by the power difference distribution means (30, 31). The group target power setting device includes demand control means for performing demand control for a plurality of equipment belonging to the group.
The target power control system according to claim 1. The differential power distribution unit distributes the differential power to each of the plurality of groups based on a target power ratio of each of the plurality of groups.
The target power control system according to claim 1 or 2. The differential power distribution unit distributes the differential power to each of the plurality of groups based on a ratio of a value obtained by subtracting power used for each of the plurality of groups from target power of each of the plurality of groups.
The target power control system according to claim 1 or 2. The differential power distribution unit distributes the differential power equally to each of the plurality of groups.
The target power control system according to claim 1 or 2. The target power control device includes power data storage means (101, 102, 103) for storing power data in time series , and power for processing the power data stored in the power data storage means (101, 102, 103). and data processing means (111, 112), <br/> claim, further comprising a power data output means (121, 122, 123) for outputting the processed data obtained by the power data processing means (111, 112) The target power control system (30, 31) according to any one of 1 to 5 .

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