JP5526637B2 - Cogeneration system operation planning device and cogeneration system - Google Patents

Description

The present invention relates to an operation planning device for a cogeneration system that performs an operation plan for a generator based on a predicted value of at least one of electric power load demand and thermal load demand, and a cogeneration system including the same.

  Conventionally, with regard to cogeneration systems that use generators such as fuel cells and gas engines, future power demand and heat load demand are predicted based on power demand and heat load demand measured in the past. It has been proposed to perform an operation plan (see, for example, Patent Document 1).

JP 2007-220665 A

  However, in the generator operation plan shown in Patent Document 1, since the load prediction data is simulated based on the load data measured in the past, it is not prediction data reflecting an actual user action plan. There are many cases. Therefore, the operation of the generator and the actual load demand based on the user's behavior do not match, leading to a reduction in the energy efficiency of the cogeneration system.

This invention solves the said conventional subject, and it aims at providing the driving | running plan apparatus for cogeneration systems which reflected the user's actual action plan more than before, and a cogeneration system provided with the same.

In order to solve the above problem, the operation planning device for a cogeneration system according to the present invention displays the heat load demand predicted by the load demand predictor in a graph on the time axis and collects the exhaust heat of the generator. And a load demand updater for updating the magnitude of the thermal load demand displayed on the screen, the load demand updater, When the predicted value of the thermal load demand at a predetermined time of the thermal load demand displayed on the screen is updated by a user's touch operation on the screen, the power generation based on the updated thermal load demand The operation plan of the machine is updated by the operation planner . Further, the present invention includes an operation planner that creates an operation plan of a generator based on the thermal load demand predicted by the load demand predictor, and the magnitude of the thermal load demand predicted by the load demand predictor is displayed on the screen. Is displayed in a graph on the time axis, and the scheduled full heat time of the regenerator that collects and stores the exhaust heat of the generator is displayed on the screen, and the operation planner displays the thermal load displayed on the screen. A code that updates the operation plan of the generator based on the thermal load demand updated by the load demand updater that allows the user to update the magnitude of the thermal load demand at a predetermined time of demand by a touch operation on the screen. It may be an operation planning device for a generation system.

According to the operation planning device for a cogeneration system of the present invention, while confirming the initially predicted load data on the display, the predicted load data reflecting the user's action plan is appropriately updated, and the updated data is included in the updated data. Since it becomes possible to re-plan the operation on the basis of the operation, the operation plan of the generator is made in accordance with the load demand resulting from the actual action of the user than before.

The block diagram of the operation plan apparatus for cogeneration systems in Embodiment 1 of this invention The figure which shows an example of the data displayed on the indicator of the operation plan apparatus for cogeneration systems in Embodiment 1 of this invention The figure which shows an example of the update of the data display accompanying the touch operation on the screen of the indicator of the operation plan apparatus for cogeneration systems in Embodiment 1 of this invention. The flowchart regarding the update of the data display accompanying the touch operation on the screen of the indicator of the operation planning device for the cogeneration system in Embodiment 1 of the present invention. The figure which shows an example of the update of the data display after the operation re-plan based on the update data of the operation plan apparatus for cogeneration systems in Embodiment 1 of this invention The flowchart regarding the update of the data display accompanying the driving | operation re-plan of the driving | operation planning apparatus for cogeneration systems in Embodiment 1 of this invention. The figure which shows the other example of the update of the data display accompanying the touch operation on the screen of the indicator of the operation plan apparatus for cogeneration systems in Embodiment 1 of this invention. The figure which shows an example of the update of the data display accompanying the touch operation on the screen of the indicator of the operation plan apparatus for cogeneration systems in Embodiment 2 of this invention. The figure which shows the other example of the update of the data display accompanying the touch operation on the screen of the indicator of the operation plan apparatus for cogeneration systems in Embodiment 2 of this invention. The figure which shows an example of the update of the data display after the operation re-plan based on the update data of the operation plan apparatus for cogeneration systems in Embodiment 2 of this invention The figure which shows an example of the data displayed on the indicator of the operation plan apparatus for cogeneration systems in the modification of this invention The figure which shows an example of the setting of the hot water start time of the operation plan apparatus for cogeneration systems in the modification of this invention The figure which shows an example of the update of the data display after the driving | operation re-planning of the driving | operation planning apparatus for cogeneration systems in the modification of this invention

(Embodiment 1)
Hereinafter, a schematic configuration of a cogeneration system operation planning apparatus according to Embodiment 1 of the present invention and a cogeneration system including the same will be described with reference to FIG.

  As shown in FIG. 1, the cogeneration operation planning apparatus 100 according to the present embodiment stores the history data of at least one of the storage device 106 and the past power load demand and heat load demand stored in the storage device 106. A load demand predictor 104 that predicts at least one of a future power load demand and a heat load demand based on the prediction data of the load demand of at least one of the power load demand and the heat load demand stored in the storage 106 The operation planner 107 that performs the operation plan of the generator 111 and the heat accumulator 112 on the basis of the prediction data of at least one of the power load demand and the heat load demand stored in the storage unit 106, A graph generator 102 that generates a graph displaying the size on the time axis, and generated by the graph generator 102 Based on the content of the touch operation on the screen determined from the detection signal of the display 101 that displays the displayed graph on the screen, the contact detector 113 that detects the contact of the display 101 with the screen, and the detection signal of the contact detector 113. A predicted load demand updater 103 that updates at least one of the predicted data of the power load demand and the heat load demand stored in the storage unit 106.

  The cogeneration system according to the present embodiment includes a cogeneration unit that performs operation based on the operation plan planned by the cogeneration operation planning device 100 in addition to the cogeneration operation planning device 100 according to the present embodiment described above. The power load demand measuring device 108 that measures the power load demand of the power load that receives the power supply from the cogeneration unit, and the heat load demand meter that measures the heat load demand of the heat load that receives the heat supply from the cogeneration unit 109. The combined heat and power unit controls the power generation operation of the generator 111 and the heat storage operation of the heat accumulator 112 based on the operation plan created by the operation planner 107. The power load demand and the heat load demand measured by the power load demand measuring device 108 and the heat load demand measuring device 109 are stored in the storage device 106 as history data of the past power load demand and the heat load demand.

  Next, in the above-described cogeneration operation planning apparatus 100, when the prediction data of the power load demand is displayed on the display device 101, the prediction data of the power load demand and the operation plan by the touch operation on the screen by the user. An embodiment in which the change is made will be described.

By operating a setting button provided on the remote controller as the display device 101, the user selects display of forecast data of power load demand for a predetermined day (in this example, 2009/2/24 (Tuesday)) Then, as shown in FIG. 2, on the remote control screen, the magnitude of the predicted value of power load demand (hereinafter referred to as history predicted power load demand) predicted by the load demand predictor 104 is on the vertical axis, and the time axis is on the horizontal axis. A graph will be displayed. In this graph, the time zone in which the power generation operation of the generator 111 planned by the operation planner 107 based on the prediction data of the power load demand is executed, the start time of the power generation operation, and the stop time of the power generation operation are displayed together. The In this example, as shown in FIG. 2, it is displayed on the screen that a power generation operation with a start time of 18:00 and a stop time of 22:00 is planned. The user looks at the prediction data of the power load demand displayed on the remote control and determines that the power load demand data (hereinafter referred to as the user predicted power load demand) predicted from the action schedule of the day is different from the predetermined data. When a predetermined touch operation is executed in the display area on the screen displaying the power load demand in response to the power load demand in time, this is detected by the contact detector 113, and depending on the content of the detected touch operation To change the predicted value of power load demand. As the touch operation, for example, as shown in FIG. 3, a power load at a time that needs to be changed (in this example, a time zone from 13: 00 to 15:00 and a time zone from 18: 00 to 22:00) A part of the graph displaying the demand is touched with a touch pen, the touch pen is moved while maintaining the touch on the screen, and the magnitude of the power load demand is changed by releasing the touch pen from the screen. The changed power load demand is reflected in a graph displayed on the remote controller screen upon completion of the touch operation. The touch operation is not an operation with a touch pen,
It may be a touch operation with a user's finger.

  Note that the movement direction of the touch pen is, for example, when the user predicted power load demand is larger than the history predicted power load demand (in this example, the user predicted power load demand and the history prediction at 13: 00 to 15:00. (Corresponding to the relationship with the power load demand) is upward, and the user predicted power load demand is smaller than the historical predicted power load demand (in this example, the user predicted power load at 18: 00 to 22:00) (Corresponding to the relationship between the demand and the historical predicted power load demand) is changed so that the power load demand displayed on the screen approaches the user predicted power load demand by moving the touch pen downward. The touch operation is merely an example, and any form may be used as long as the predicted value of the power load demand is changed by a touch operation on the display area of the power load demand. The touch operation is limited to the above contents. It is not a thing.

  Further, in the above example, the power during the time when the touch operation is performed (in this example, the time zone of 13: 0 to 15:00 and the time zone of 18:00 to 22:00 in this example) Although it is configured so that the predicted value of load demand is changed, it is not limited to the above example. For example, when a touch operation involving a change in the magnitude of the power load demand is performed on a part of the graph in which the power load demand for a predetermined time is displayed, the predetermined time and A mode in which the predicted value of the power load demand at different time is changed by the predicted load demand updater 103 may be adopted. Specifically, as shown in FIG. 7, when the predicted value of power load demand for a predetermined time (in this example, the time zone from 13:00:00 to 15:00) is smaller than the user predicted power demand, The touch pen is brought into contact with a part of the graph showing the predicted value of the power load demand for the predetermined time, and the touch pen is moved upward while maintaining the contact, so that the predicted value of the power load demand is the user predicted power. Increase in demand. At this time, the predicted load demand updater 103 obtains the predicted value of the power load demand at another time when the predicted value of the power load demand is relatively large (in this example, the time zone from 18: 00 to 22:00). Reduce. Then, the updated predicted value of power load demand is reflected in the graph displayed on the screen of the remote controller as the operation of the touch pen is completed. In the above example, when a touch operation for increasing the magnitude of the power load demand for a predetermined time is performed, the magnitude of the power load demand for the other time decreases. In addition, when a touch operation for reducing the magnitude of the power load demand for a predetermined time is performed, the magnitude of the power load demand for another time may be increased.

  Next, the flow operation of the operation planning device for a cogeneration system accompanying the touch operation for changing the power load demand will be described with reference to FIG. When the touch operation is executed in a state where the predicted power load demand data is displayed (step S101), the predicted load demand updater 103 updates the predicted value of the power load demand from the operation content of the touch operation. (Step S102) The prediction data of the power load demand including the updated predicted value is stored in the storage device 106 (Step S103). The graph generator 102 reads the updated prediction data of the power load demand stored in the storage device 106 again, creates a new graph based on the read prediction data again (step S104), and displays the display 101. This is displayed on the screen (step S105).

  Next, the user has determined that the prediction data displayed on the screen of the display unit 101 is in accordance with his / her own action schedule with the update of the prediction data of the power load demand by the touch operation. In this case, as shown in FIG. 5, the contact detector 113 detects this by touching the display portion of the driving re-plan on the screen with a touch pen, and the driving planner 107 is updated based on this detection signal. The power generation operation of the generator 111 is re-planned based on the prediction data of the power load demand, and the time zone when the power generation operation of the re-planned generator 111 is executed, the start time of the power generation operation, and the stop time of the power generation operation are Then, it is displayed again on the display unit 101 together with the updated prediction data of the power load demand.

  Here, the flow operation of the operation planning device for a cogeneration system accompanying the touch operation for operation re-planning will be described with reference to FIG. After the update of the predicted value of power load demand by the user's touch operation shown in FIG. 4 is completed, the predicted load demand updater 103 is operated by touching the operation re-planning button displayed on the screen (step S201). The operation planner 107 re-plans the power generation operation of the generator 111 based on the predicted power load demand data updated by (Step S202). Then, the re-planned power generation time zone of the generator 111 (13: 0 to 15:00 in this example) is stored in the storage device 106 (step S203), and the graph generator 102 is stored in the storage device 106. The re-planned power generation time zone is read out, a new graph is created based on the read power generation time zone (step S204), and this is displayed on the screen of the display 101 (step S205).

(Embodiment 2)
Hereinafter, the cogeneration system operation planning apparatus according to the second embodiment of the present invention and the cogeneration system including the same will be described. The apparatus configuration is the same as the cogeneration operation planning apparatus of Embodiment 1 and the cogeneration system including the same except that the heat accumulator 112 is a hot water storage tank, and the description thereof will be omitted.

  In the operation planning device for cogeneration according to the present embodiment, when the prediction data of the heat load demand is displayed on the display device 101, the prediction data of the heat load demand and the operation plan are obtained by a touch operation on the screen by the user. One form to be changed will be described.

  By operating a setting button provided on the remote controller as the display device 101, the user selects display of prediction data of the heat load demand for a predetermined day (2009/2/24 (Tuesday) in this example). Then, as shown in FIG. 8, the size of the predicted value of the thermal load demand predicted by the load demand predictor 104 (hereinafter referred to as historical predicted thermal load demand) is displayed on the remote control screen, and the time axis is the horizontal axis. A graph will be displayed. In this graph, the time zone in which the hot water storage operation of the cogeneration system planned by the operation planner 107 based on the prediction data of the thermal load demand is executed, the start time of the hot water storage operation, and the stop time of the hot water storage operation are also displayed. Is done. In this example, as shown in FIG. 8, a hot water storage operation in which the start time is 6:00 and the stop time is 8:00, and a hot water storage operation in which the start time is 19:00 and the stop time is 21:00 are planned. Is displayed on the screen. The display 101 also shows on the graph that the hot water storage tank is stopped when the hot water is full at 21:00. Here, the hot water storage operation is defined as an operation in which the heat generated by the power generation operation of the generator 111 is exhausted and recovered in a hot water storage tank as the heat accumulator 112.

  The user looks at the prediction data of the heat load demand displayed on the remote control, and determines that the user is different from the heat load demand data predicted from the action schedule of the day (hereinafter referred to as the user predicted heat load demand). In response to the heat load demand in time, the touch detector 113 detects this by performing a predetermined touch operation in the display area on the screen displaying the heat load demand, and the content of the detected touch operation The predicted value of heat load demand is changed according to As the touch operation, for example, as shown in FIG. 8, a heat load during a time that needs to be changed (in this example, a time zone from 16:00 to 18:00 and a time zone from 19:00 to 21:00) A part of the graph displaying the demand is touched with a touch pen, the touch pen is moved while maintaining the touch on the screen, and the size of the heat load demand is changed by releasing the touch pen from the screen. The changed heat load demand is reflected in the graph displayed on the screen of the remote controller when the touch operation is completed. The touch operation may be a touch operation with a user's finger instead of an operation with a touch pen.

Note that the movement direction of the touch pen is, for example, when the user predicted heat load demand is larger than the history predicted heat load demand (in this example, the user predicted heat load demand and the history prediction at 16:00 to 18:00 (Corresponding to the relationship with the thermal load demand) is the upward direction, and when the user predicted thermal load demand is smaller than the historical predicted thermal load demand (in this example, the user predicted thermal load at 21: 00 to 23:00) The demand is changed so that the heat load demand displayed on the screen approaches the user predicted heat load demand. The touch operation is merely an example, and any form may be used as long as the predicted value of the heat load demand is changed by a touch operation on the display area of the heat load demand. It is not a thing.

  In the above example, the heat of the time when the touch operation is performed (in the above example, the time zone of 16:00 to 18:00 and the time zone of 21: 0 to 23:00 in this example) Although it is configured so that the predicted value of load demand is changed, it is not limited to the above example. For example, when a touch operation involving a change in the magnitude of the heat load demand is performed on a part of the graph in which the heat load demand for a predetermined time is displayed, the predetermined time and You may employ | adopt the form by which the predicted value of the heat load demand of another different time is changed by the predicted load demand updater 103. FIG. Specifically, as shown in FIG. 9, when the predicted value of the thermal load demand for a predetermined time (in this example, the time zone from 16:00 to 18:00) is smaller than the user predicted power demand, The touch pen is brought into contact with a part of the graph showing the predicted value of the heat load demand for the predetermined time, and the touch pen is moved upward while maintaining the contact, so that the predicted value of the heat load demand is calculated by the user predicted power. Increase in demand. At this time, the predicted load demand updater 103 obtains the predicted value of the thermal load demand at another time when the predicted value of the thermal load demand is relatively large (in this example, the time zone of 21: 0 to 23:00). Reduce. Then, the updated predicted value of the heat load demand is reflected on the graph displayed on the screen of the remote controller as the operation of the touch pen is completed. In the above example, when the touch operation for increasing the magnitude of the heat load demand for a predetermined time is performed, the magnitude of the heat load demand for the other time is reduced. In addition, when a touch operation for reducing the magnitude of the heat load demand for a predetermined time is performed, the magnitude of the heat load demand for another time may be increased.

  Next, the flow operation of the operation planning device for a cogeneration system accompanying the touch operation for changing the heat load demand is based on the predicted value of the heat load demand from the predicted value of the power load demand. Since it is the same as the flow operation of the operation planning device for a cogeneration system accompanying the touch operation for changing the power load demand described based on FIG.

  Next, the user has determined that the prediction data displayed on the screen of the display unit 101 is in accordance with his / her own action schedule with the update of the heat load demand prediction data by the touch operation. In this case, as shown in FIG. 10, by touching the display portion of the driving re-plan on the screen with the touch pen, this is detected by the contact detector 113, and the driving planner 107 is updated based on this detection signal. Re-schedule the hot water storage operation of the cogeneration system based on the predicted heat load demand, and update the time zone during which the hot water storage operation of the re-planned system is executed, the start time of the hot water storage operation, and the stop time of the hot water storage operation It is displayed again on the display unit 101 together with the predicted heat load demand data.

  In addition, the flow operation of the operation planning device for the cogeneration system accompanying the touch operation for the operation re-planning is that the object to be changed along with the touch operation is the hot water storage operation of the cogeneration system from the time period of the generator operation Since it is the same as the flow operation of the operation planning device for the cogeneration system accompanying the touch operation for the operation re-planning described based on FIG.

(Modification)
Next, a modified example of a cogeneration system operation planning apparatus and a cogeneration system including the same will be described.

  The operation planning device for a cogeneration system according to the present modification operates a setting button provided with a remote controller as the display device 101, so that a predetermined day (in this example, 2009/2/24 (Tuesday)). When the user selects the display of the predicted heat load demand, the predicted value of the heat load demand predicted by the load demand predictor 104 (hereinafter referred to as the historical predicted heat load) is displayed on the remote control screen as shown in FIG. The graph is displayed so that the magnitude of (demand) is on the vertical axis and the time axis is on the horizontal axis. In this graph, as in the case of the second embodiment, the time zone in which the hot water storage operation of the cogeneration system planned by the operation planner 107 is executed based on the prediction data of the thermal load demand is displayed. In a modification, the historical prediction heat load demand in the time zone in which hot water filling to the bathtub is executed is displayed differently from the historical prediction heat load demand in other time zones. Specifically, for example, when the historical predicted heat load demand is displayed as a bar graph as shown in FIG. 11, the historical predicted heat in the time zone in which the hot water filling to the bathtub is executed in the color of the bar graph, the fill pattern, etc. The load demand is displayed so as to be different from the historical predicted heat load demand in other time zones.

  In the above hot water filling time zone, as shown in FIG. 12, the hot water start time is selected by pressing the left and right buttons with a touch pen, and when the desired start time is reached for the user, the enter button is pressed. By doing so, the hot water filling time zone is set. In this example, when the hot water filling start time is set, the hot water filling time period (30 minutes in this example) is preset from the length of hot water filling time (30 minutes in this example) held in the storage device 106 in advance. : 00-21: 30) is set.

  Here, when the hot water filling start time set by the user's operation is after the time when the hot water storage operation of the fuel cell system is stopped due to the hot water storage tank becoming full as shown in FIG. That is, before the hot water filling is started, when the hot water storage operation of the cogeneration system is stopped due to the hot water storage tank being full, when the operation re-planning button is pressed with the touch pen, the contact detector 113 is used. Based on this detection signal, the operation planner 107 replans the hot water storage operation of the cogeneration system so that the hot water storage tank does not become full before the hot water filling is started.

  FIG. 13 is a graph in which the hot water storage operation time zone re-planned by the operation re-planning 107 is displayed. As is clear from this figure, immediately after the hot water filling is started by executing the operation re-planning. (In this example, the hot water storage operation that was executed from 19:00 to 21:00) moved to a later time (20:00 in this example), so that the hot water storage tank became a hot water filling time. The operation is continued without becoming full. Furthermore, since the hot water in the hot water storage tank is used in large quantities due to the hot water filling in the bathtub, the operation time of the hot water storage operation is extended as compared with that before the replanning, so that energy saving is improved.

  In the cogeneration system of this modification, the prediction data of the heat load demand, the hot water storage operation time zone, and the time when the hot water is full are displayed on the display 101, and the hot water filling to the bathtub is executed. The historical predicted heat load demand in a certain time zone is configured to be displayed differently from other historical predicted heat load demands. However, if at least the time when the hot water is full and the hot water start time are displayed as the display on the display device 101, the user can determine whether or not the operation re-planning should be performed, and the heat load demand can be determined. There is no need to display the prediction data, the hot water storage operation time zone, and the like.

As described above, in this modification, for the convenience of the user, the hot water filling time for the bathtub is set after the time when the operation of the cogeneration system is stopped due to the hot water storage tank becoming full. In addition, by displaying at least the time when the hot water is full and the hot water start time on the display device 101, the fact can be recognized and the user can be prompted to execute an operation re-plan for hot water storage operation. Then, when the user actually instructs the execution of the operation re-plan, the operation planner 107 re-plans the hot water storage operation of the cogeneration system so that the hot water does not become full before the start of filling the bathtub. The system can continue to operate for a longer period of time than before, and energy efficiency is improved.

According to the operation planning apparatus for a cogeneration system according to the present invention, it becomes possible to make an operation plan for a generator in accordance with a load demand resulting from an actual action of a user, so that it can be used for business use and household use. It is useful as a cogeneration system.

DESCRIPTION OF SYMBOLS 100 Cogeneration operation plan apparatus 101 Indicator 102 Graph generator 103 Predictive load demand updater 104 Load demand predictor 106 Memory | storage device 107 Operation planer 108 Power load demand measuring instrument 109 Thermal load demand measuring instrument 110 Operation controller 111 Power generation Machine 112 heat accumulator 113 contact detector 120 cogeneration system

Claims (8)

A screen that displays the magnitude of the thermal load demand predicted by the load demand predictor in a graph on the time axis, and displays the scheduled full heat time of the regenerator that collects and stores the exhaust heat of the generator;
A load demand updater that allows a user to update the magnitude of the thermal load demand displayed on the screen,
When the predicted value of the thermal load demand at a predetermined time of the thermal load demand displayed on the screen is updated by a user 's touch operation on the screen, the load demand updater updates the heat demand. Causing the operation planner to update the operation plan of the generator based on the load demand;
Cogeneration operation planning device . The cogeneration operation planning apparatus according to claim 1, wherein the load demand updater displays the updated magnitude of the thermal load demand on the screen. The screen further displays a hot water start time of the bathtub on the time axis.
The operation planning device for cogeneration according to claim 1 or 2. The screen performs a display different from the heat demand in other periods, regarding the heat demand in the hot water filling period to the bathtub,
The operation planning device for cogeneration according to claim 1 or 2. A hot water filling time setting device capable of updating the hot water filling start time;
4. When the hot water filling time is updated by the hot water filling time setting device, the screen updates the scheduled full heat time on the time axis based on the operation plan updated by the operation planner. Or the operation plan apparatus for cogeneration of 4. In the state where the thermal load demand is displayed on the screen, when the predicted thermal load demand at a predetermined time is updated, at least a part of the predicted thermal load demand at another time is also displayed. Updated,
The operation planning device for cogeneration according to claim 1 or 2. An operation planner that creates a generator operation plan based on the thermal load demand predicted by the load demand predictor,
The magnitude of the thermal load demand predicted by the load demand predictor is displayed on the screen in a graph on the time axis, and the estimated full time of the regenerator that collects and stores the exhaust heat of the generator is displayed on the screen. The operation planner is updated by a load demand updater that allows a user to update the magnitude of the thermal load demand at a predetermined time of the thermal load demand displayed on the screen by a touch operation on the screen. Updating the generator operation plan based on the thermal load demand;
Operation planning device for cogeneration system. A cogeneration system comprising: the operation planning device for a cogeneration system according to claim 7; a generator; and a heat accumulator for collecting and storing exhaust heat of the generator.

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