JP2020024798A - Power generation system - Google Patents

Abstract

To notify a user of a situation of power generation so that the notification is usable from the viewpoint of the user.SOLUTION: Display for promoting power generation is performed on a display unit 64 of a remote control panel 46 by determining a predetermined condition is established when a count number n of a number of times of operation (a number of times of on/off operation) of a power consumption apparatus 24 (household appliance and lighting, etc.), an energy consumption apparatus, exceeds a predetermined count value (threshold value N) (n>N). Thereby, because the power consumption apparatus 24 has been used many times in the case of a factor other than a failure making the power generating system generate no power, display of a message on a display unit 64 of a remote control panel 46 can make a user recognize that power generation is advantageous.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a power generation system that generates power and supplies power.

  A cogeneration device, for example, a household fuel cell cogeneration device is a system in which a hot water storage unit and a fuel cell unit are provided in parallel.

  In the fuel cell unit, gas is continuously consumed for the purpose of power generation, and the heat generated by the power generation heats the water in the hot water storage unit to generate hot water.

  Power generation is basically always in operation, but there are exceptions.

(Exception 1) Failure

  The power generation operation stops due to the failure of the fuel cell unit.

(Exception 2) Countermeasures for trace leakage monitoring function

  For example, a microcomputer meter is equipped with a safety function for detecting leaks (particularly, minute leaks) of gas pipes. In the safety function, if the leakage continues for 30 days (when the alarm counter exceeds a threshold), an alarm is issued (flashing of an alarm lamp, etc.). The definition of “continuation” is that gas flows without an interval of one hour or more.

  On the other hand, unlike the other gas consuming devices, it is a normal specification that the fuel cell unit continuously consumes gas for the purpose of power generation. For this reason, a certain power generation suspension period is provided before 30 days elapse so that the safety function does not work.

(Exception 3) Power generation stoppage depending on user's operation

  For example, in the default specification immediately after the installation of the equipment, the operation of the fuel cell unit may be stopped, and the user may use the fuel cell unit without noticing the power generation stop state.

(Exception 4) Power generation suspension due to season

  Some fuel cells stop when the hot water storage tank is filled with hot water. In such a fuel cell, the power supply temperature is high in the summer, when heat demand is low, and the hot water storage tank is easily filled with hot water. May stop.

  Whether or not power is being generated may be reported, for example, by a remote control or the like provided in the living room. Therefore, even if the power is not generated at a time when the power can be generated, the user rarely has distrust.

  Therefore, if the fuel cell unit is not generating power at a time when it is preferable to generate power, it cannot be effectively used as a cogeneration device unless the fuel cell unit is actively notified that the fuel cell unit is not generating power.

  Patent Document 1 discloses a power generation system that performs power generation and supplies power, and includes at least a controller that controls starting and stopping of the power generation system, and an alarm that notifies an operation state of the power generation system. The controller, when the power generation system is not out of order and the period during which the power generation system is not generating power is equal to or longer than a predetermined first period, the power generation system is generated by the annunciator. There is disclosed a power generation system that provides notification information including at least one of operation information indicating that the operation has not been performed and setting information for confirming the operation setting of the power generation system.

Japanese Patent No. 6023978

  However, in Patent Literature 1, since the condition of the notification of the notification information is that the power generation system is faulty and the power is not generated for the first period or more, it is simply not generated regardless of the usefulness of the power generation. It just informs.

  Therefore, on the condition that the user has not generated power for the first period or more, the user cannot determine whether it is advantageous or disadvantageous to generate power by notifying that no power has been generated.

  An object of the present invention is to provide a power generation system capable of performing useful notification from the viewpoint of a user when notifying the state of power generation.

  The present invention is a power generation system that performs power generation and supplies electric power, and includes a control unit that controls at least start and stop of the power generation system, and a notification unit that notifies an operation state of the power generation system. The unit does not generate power due to factors other than the failure of the power generation system, and, regarding the operating state of the energy consuming equipment, when a predetermined condition is satisfied, the power generation system does not generate power in the notification unit. And the setting information for confirming the setting of the operation of the power generation system.

  According to the present invention, the notification unit notifies the operating status of the power generation system. In this notification unit, when the power generation system is not generating power due to a factor other than a failure, and with respect to the operation state of the energy consuming equipment, when predetermined conditions are satisfied, operation information indicating that the power generation system is not generating power and Notification information including at least one of the setting information for confirming the setting of the operation of the power generation system is notified.

  Thus, when notifying the power generation status, it is possible to perform useful notification from the viewpoint of the user.

  The present invention is characterized in that an operation state of the energy consuming equipment is analyzed based on power transition information obtained from a power smart meter.

  By analyzing a comprehensive power transition, the power smart meter can recognize, for example, which of a plurality of power consuming devices, which are energy consuming devices, is operating and which is not.

  Based on this power transition information, the operation state of the energy consuming equipment can be monitored.

  In the present invention, the operation state of the energy consuming facility is the number of times of operation of the energy consuming facility, and the case where the number of times of operation of the energy consuming facility is equal to or more than a predetermined number is defined as satisfying the condition. I have.

  By setting the operation state of the energy consuming facility to the number of times of operation of the energy consuming facility, the energy consumption state (for example, the power consumption state) of the energy consuming facility can be grasped.

  In the present invention, the operation condition of the energy consuming facility is a cumulative power consumption value of the energy consuming facility, and the condition is satisfied when the cumulative power consumption value of the energy consuming facility becomes a predetermined value or more. It is characterized by:

  By setting the operation state of the energy consuming facility to the accumulated power consumption value of the energy consuming facility, the energy consumption state (for example, the power consumption state) of the energy consuming facility can be grasped.

  In the present invention, the power generation system is applied as a fuel cell unit attached to a hot water storage unit, whereby a cogeneration device is configured, and the fuel cell unit consumes gas for power generation, and With the accompanying heat generation, the water in the hot water storage unit is heated to generate hot water.

  The heat generated by the power generation of the fuel cell unit can be used for heating the hot water stored in the hot water storage unit.

  The notification about the power generation in the cogeneration device is useful when the gas and electricity coexist and the energy is effectively used.

  In the present invention, the condition is satisfied when the energy consuming facility is a hot water facility that receives hot water from the hot water storage unit and supplies hot water, and the number of times of hot water supply of the hot water facility becomes a predetermined number or more. It is characterized by.

  When the number of times of hot water supply of the hot water supply equipment increases, the amount of hot water in the hot water storage tank decreases, and accordingly, it is necessary to heat the hot water by power generation. Therefore, when the power generation system is not generating power due to a factor other than a failure and the number of times of hot water supply of the hot water supply system is equal to or more than a predetermined number, the operation information indicating that the power generation system is not generating power and the operation of the power generation system Notification information including at least one of the setting information for confirming the setting is notified.

  Thus, when notifying the power generation status, it is possible to perform useful notification from the viewpoint of the user.

  In the present invention, the condition is satisfied when the energy consuming facility is a hot water facility that receives hot water from the hot water storage unit and supplies hot water, and a cumulative value of hot water supplied by the hot water facility becomes a predetermined value or more. It is characterized by:

  When the cumulative value of hot water supplies of the hot water supply equipment increases, power is consumed according to the operation of the hot water supply equipment, and it is necessary to generate power accordingly. Therefore, when the power generation system is not generating power due to a factor other than a failure, and when the cumulative value of hot water supply of the hot water supply equipment is equal to or more than a predetermined value, the operation information indicating that the power generation system is not generating power and the operation of the power generation system Notification information including at least one of the pieces of setting information for confirming the setting.

  Thus, when notifying the power generation status, it is possible to perform useful notification from the viewpoint of the user.

  As described above, according to the present invention, the use status of the energy consuming equipment can be used as a trigger for notification of the power generation status, and the notification can promote the utility of the power generation to the user.

  ADVANTAGE OF THE INVENTION According to this invention, when notifying the state of a power generation, there exists an effect that useful notification from a user's standpoint can be performed.

It is a schematic diagram of a cogeneration device according to the present embodiment. FIG. 2 is a block diagram illustrating a configuration of a controller according to the present embodiment. It is a front view of the operation remote control panel concerning this Embodiment. It is a front view of the operation remote control panel which concerns on this Embodiment, (A) is the state which is actively performing the notification which urges power generation (this embodiment), (B) is the notification which urges power generation actively. Shows a non-execution state (comparative example). It is a flowchart which controls the timing of the notification which prompts the power generation according to the present embodiment.

  FIG. 1 is a schematic diagram of a household fuel cell cogeneration device according to the present embodiment (hereinafter, referred to as “ENE-FARM 10” in the present embodiment) as an example of the cogeneration device of the present invention. It is shown.

  The energy farm 10 is a system in which a hot water storage unit 12 and a fuel cell unit 14 are provided side by side. It should be noted that juxtaposition does not mean that they are physically adjacent to each other, but means that they cooperate with each other. That is, the hot water storage unit 12 and the fuel cell unit 14 may be installed separately from each other and connected by piping, electric wiring, or the like.

  The energy farm 10 is controlled by a controller 16.

  Hot water storage unit 12 includes a hot water storage tank 32. In addition, the fuel cell unit 14 takes in a gas (for example, city gas 13A) from the gas supply pipe 18 to purify hydrogen, and generates power by performing processing centering on reforming with hydrogen and oxygen. A stack 22 for storing electricity and an inverter 28 for converting the electric power (DC) stored in the stack 22 into AC and supplying it to a power consuming device 24 such as home appliances (home appliances) and lighting in a house 48 are provided. .

  Note that, in FIG. 1, home appliances and lighting are listed as typical examples of the power consuming devices 24, but in the present embodiment, the power consuming devices 24 are required in the house 48 including home appliances and lighting. All the electric components indicate power consuming devices (for example, the control target devices 12D and 14D (see FIG. 2) related to the ENE-FARM 10, a remote control panel 46 described later, a gas fan heater 54, and the like). In addition, the power consuming device 24 forms a part of the energy consuming device.

  The fuel cell unit 14 generates heat when power is generated by the stack 22, and thus needs to be cooled.

  On the other hand, in the hot water storage unit 12, tap water or the like is taken into the hot water storage tank 32 (water supply), and is provided inside the house 48 and constitutes an energy consuming device together with the power consuming device 24. ) Must be heated (heated) to use it for hot water supply and for heat exchange in floor heating and air conditioning equipment.

  For this reason, the fuel cell unit 14 includes the heat exchanger 30, and heat generated by power generation in the stack 22 and water supplied to the hot water storage tank 32 provided in the hot water storage unit 12 via the water pipe 33. Heat exchange with

  The water pipe 33 is provided with a heater (mainly an electric heater) not shown, and the water pipe 33 and peripheral devices may be prevented from freezing by heating the water pipe 33 with the heater.

  The inverter 28 that forms a part of the fuel cell unit 14 is connected to a switching unit 62 that controls switching with a commercial power supply 60. The switching unit 62 switches the power supply source (the power generated by the fuel cell unit 14 or the power from the commercial power supply 60) based on an instruction from the controller 16.

  A power smart meter 63 is attached downstream of the switching unit 62 as a meter for monitoring the power consumption state.

  The power generated by the fuel cell unit 14 or the power from the commercial power supply 60 is input to the power smart meter 63 depending on the switching by the switching unit 62 and supplied to the power consuming device 24. I have. In other words, when the user uses the power consuming device 24, any power is supplied, and there is no problem.

  The power smart meter 63 is connected to the controller 16, and a power source is displayed on a remote control panel 46 controlled by the controller 16.

  The power smart meter 63 analyzes the transition of the consumed power (power consumption, the amount of power per unit time and the amount of power change, and the time and time zone of consumption, etc.), and thereby the rated power consumption is calculated in advance. It is possible to identify the type of the known power consuming device 24 and recognize the operation state (including the ON / OFF timing). The transition of the power consumed by the power consuming device 24 is sent to the controller 16.

  A microcomputer meter 50 is attached to the gas supply pipe 18. A branch portion 18A is provided on the downstream side of the microcomputer meter 50, and one branch pipe 18B serves as a pipeline for supplying gas to the fuel processor 20. The other branch pipe 18C is a pipe for supplying gas to gas appliances (the stove 52, the gas fan heater 54, etc.) in the house 48.

  The microcomputer meter 50 has a plurality of functions of measuring the flow rate of the supplied gas and monitoring an abnormality in the supply of the gas. The main monitoring functions include an abnormal outflow monitoring function, a seismic function, a pressure monitoring function, and a long-time use monitoring function.

  In addition, the microcomputer meter 50 has a "micro leak monitoring function" as a safety function, although it does not actively shut off gas supply, in addition to the main monitoring function described above.

  In the micro leak monitoring function, an alarm is issued (flashing of an alarm lamp, etc.) when the micro leak continues for 30 days.

  The “trace amount” is a gas flow rate that is not determined to be abnormal by the above-described abnormal outflow monitoring function, pressure monitoring function, and long-time use monitoring function, and is determined from a predetermined permissible leakage range per unit time.

  Further, the definition of “continuation” is that gas flows without an interval of one hour or more. In other words, a flow interruption of less than one hour (for example, 59 minutes) is recognized as “continuation”.

  Here, since the ENE-FARM 10 normally consumes gas for the purpose of power generation, a certain power generation stop period is provided before 30 days elapse so that the trace leakage monitoring function does not work. I have to. As an example, once every 27 days of continuous operation, a power generation suspension period of a fixed time (24 hours) is provided, and the alarm counter of the safety function is reset.

  (Configuration of Controller 16)

  As shown in FIG. 2, the controller 16 includes a microcomputer 34 including a CPU 34, a RAM 36, a ROM 38, an I / O 40, and a bus 42 such as a data bus and a control bus connecting these.

  The I / O 40 is connected to a controlled device 12D of the hot water storage unit 12 and a controlled device 14D of the fuel cell unit 14, and controls respective operations under the control of the controller 16.

  Further, a remote control panel 46 is connected to the I / O 40. The remote control panel 46 is installed inside a house 48 (see FIG. 1) in which the ENE-FARM 10 is installed, and has a function of allowing a user to input a command regarding the ENE-FARM 10 and display a state of the ENE-FARM 10. Have.

  The water temperature in the hot water storage tank 32 (see FIG. 1) is classified into a plurality of temperature layers. The I / O 40 is connected to a plurality of thermistors 51 (not shown in FIG. 1) for detecting the temperature of the hot water stored in the hot water storage tank 32.

  Water becomes the upper layer as the temperature increases. For this reason, the water temperature in the hot water storage tank 32 is such that the temperature of the uppermost layer is high (high temperature), the temperature decreases toward the lower layer, and the temperature of the lowermost layer is low (low temperature).

  The thermistor 51 detects the temperature of each layer (for example, when classified into four layers, each of the four layers) in the hot water storage tank 32. The controller 16 controls water supply timing, water supply amount, and the like from the water pipe 33 based on the temperature detected by the thermistor 51.

  FIG. 3 is a front view of remote control panel 46 according to the present embodiment.

  As shown in FIG. 3, the remote control panel 46 has a rectangular appearance, and a display unit 64 is disposed above the main panel 56.

  The main panel 56 below the display unit 64 is an arrangement area 68 for a plurality of operation switch groups.

  The operation switch group is a so-called hard switch in which operation switches related to hot water supply and power generation are arranged. The function of each operation switch is indicated on the switch operation surface. For example, the upper part of the operation switch group is described as “power generation setting”, “menu / return”, “▼”, “▲”, and “confirmed” in order from the left of FIG.

  The lower part of the operation switch group is described in order from the left in FIG. 3 as “power generation setting”, “today's record”, “call”, and “automatic bath”.

  As an example, the operation switch described as “power generation setting” can switch the power generation mode each time the operation switch is operated. In addition, by operating the operation switch described as “Today's record”, the screen can be switched to a screen in which the power consumption state can be visually observed.

  In the remote control panel 46 shown in FIG. 3, the arrangement position, number, function, shape, and the like of the display unit 64 and the operation switches may be changed depending on the model, year, version, and the like. The shape of the panel 46 is not limited.

  Here, the display section 64 of the remote control panel 46 displays whether or not power is being generated (display mode 1). In addition, the display unit 64 of the remote control panel 46 displays the power supply source (commercial power supply or the fuel cell unit 14 of the ENE-FARM 10) and the power consumption (（kW) (display mode 2). Further, if necessary, the status of power sale and purchase and the self-sufficiency rate of power are displayed (display mode 3). In the following:

  In this manner, by visually checking the display (display mode 1 to display mode 3 and the like) on the display unit 64 of the remote control panel 46, the current power status can be confirmed.

  However, power generation may not be performed based on various reasons, such as balance with commercial power, temperature of hot water in hot water storage tank 32 on hot water storage unit 12 side, and avoidance of false detection in monitoring minute leaks. Therefore, the user does not feel any discomfort even when informing that power is not being generated in the display state of the display unit 64 of the remote control panel 46.

  In other words, power is supplied from the commercial power supply even if the power generation setting state is off, even though it is time to generate power, so the user does not notice this and the power consuming device 24 may be used.

  Therefore, in the present embodiment, the power generation function of the fuel cell system 14 of the ENE-FARM 10 does not generate power due to a factor other than a failure (that is, it can generate power but does not generate power), and When a predetermined condition is satisfied with respect to the operation state of the (power consuming device 24 or the hot water supply facility 49), the operation information indicating that the fuel cell system 14 is not generating power and the fuel cell system are displayed on the display unit 64 of the remote control panel 46. The notification information including at least one of the setting information for confirming the setting of the driving of No. 14 is notified.

  More specifically, as an energy consuming facility, for the power consuming device 24, the number of times of operation of the power consuming device 24 is counted, and when the count value n exceeds a predetermined threshold value N, A message (for example, as shown in FIG. 4A, “Power generation is stopped (power generation is possible). The number of times the power consuming device has been used has increased. Recommended.])

  That is, since it is predicted that the more times the power consuming device 24 is operated, the more power is consumed, the user is positively notified that the power generation is possible and the power generation is stopped. In particular, when the power consuming device 24 is a water heater, since the hot water in the hot water storage tank 32 is consumed, the user is actively notified that the power generation is stopped even though the power generation is possible. Is also effective for maintaining a comfortable living environment.

  For example, in the comparative example shown in FIG. 4B, it can be recognized that no power is generated. However, there is a reason for each of a state where power is being generated and a state where power is not being generated. Therefore, in the display mode shown in FIG. There is little distrust.

  Thus, in the present embodiment, a message is displayed (FIG. 4A) to increase the recognition by notifying the user.

  The notification of the message is not limited to the display, but may be another notification mode such as a voice notification, a light emission of a warning light, or a combination of a plurality of notification modes. Further, the timing of the notification may be carefully selected so as to notify the user when power generation is required or when the user passes the vicinity of the remote control panel 46 by a human sensor or the like.

  The operation of the present embodiment will be described below with reference to the flowchart of FIG.

  In step 100, the power generation state is determined. If it is determined in step 100 that power generation is being performed, the process proceeds to step 102, and it is determined whether a message prompting power generation is currently being displayed.

  If an affirmative determination is made in step 102, the process proceeds to step 104 to instruct the end of the display of the message prompting the power generation, which is being displayed on the display unit 64 of the remote control panel 46, and this routine ends (return is defined as Means that the control returns to step 100 after executing other control (not shown). Note that the processing in the flow of steps 100 → 102 → 104 corresponds to a situation when the user notices the message displayed on the display unit 64 of the remote control panel 46 and performs an instruction operation to start power generation. .

  If a negative determination is made in step 102, this routine ends. The processing of the flow from step 100 to step 102 corresponds to a situation where power generation is performed regardless of the message.

  On the other hand, when it is determined in step 100 that the power generation is stopped, the process proceeds to step 106, and the previous determination determines whether or not the power generation is being performed.

  If an affirmative determination is made in step 106, it is determined that power generation has been stopped in this determination, the process proceeds to step 108, the count value n is reset (n = 0), and the process proceeds to step 110.

  When a negative determination is made in step 106, it is determined that the power generation has been stopped, and the process proceeds to step 112 to determine whether a message prompting power generation is being displayed. When a negative determination is made in step 112, it is determined that the power generation is stopped and before the message is displayed, and the process proceeds to step 110.

  If an affirmative determination is made in step 112, it is determined that power generation is stopped and a message is being displayed, and this routine ends.

  In step 110, the power transition information is fetched from the power smart meter 63, and then the process proceeds to step 114 to estimate the operation state of the power consuming device 24. The estimation of the operation state in step 114 is the presence or absence of the ON / OFF operation.

  In the next step 116, it is determined whether or not an on / off operation has been performed on a part or all of the power consuming device 24. Note that some of the power consuming devices 24 switch between different power consumptions of “strong”, “medium”, and “weak” in the ON state, and adjust power consumption by stepless shifting, such as a sliding resistor. However, this switching may be ignored or considered.

  If a negative determination is made in step 116, it is determined that it is not time to count up, and this routine ends.

  If an affirmative determination is made in step 116, it is determined that it is time to count up, and the flow proceeds to step 118, where the count value n is incremented (n = n + 1), and the flow proceeds to step 120.

  In step 120, the threshold value N to be compared with the count value n is read, and then the process proceeds to step 122, where the count value n is compared with the threshold value N (n: N).

  If it is determined in step 122 that n> N (affirmative determination), it is determined that it is time to display a message, and the process proceeds to step 124 to display a message prompting power generation on the display unit 64 of the remote control panel 46. , And the routine ends.

  The message is, as shown in FIG. 4A, "Power generation is stopped (power generation is possible). As the number of uses of the power consuming equipment 24 has increased, it is recommended to generate electricity. And the user notices that the display mode is different from the usual display mode due to the highlighted display mode as compared with the comparative example of FIG. 4B. It is possible to reduce the time when the operation to be performed is forgotten and the power generation cannot be effectively used.

  If it is determined in step 122 that n ≦ N (negative determination), it is determined that it is not time to display a message, and this routine ends.

  As described above, in the present embodiment, the count value n of the number of times of operation (the number of on / off operations) of the power consuming device 24 (such as home appliances and lighting) as the energy consuming device is equal to the predetermined count value (threshold value N). ) Is exceeded (n> N), it is determined that the predetermined condition is satisfied, and a display urging the power generation is displayed on the display unit 64 of the remote control panel 46 (see FIG. 4A). Accordingly, when the power generation system is not generating power due to a factor other than a failure, since the power consuming device 24 is frequently used, displaying the message on the display unit 64 of the remote control panel 46 makes the power generation useful. The user can be made aware of this.

  The energy consuming equipment may be the hot water supply equipment 49, and the presence or absence of the display of the message may be determined based on the number of operations of the hot water supply equipment 49. Further, the presence or absence of a message display may be determined based on the hot water supply amount accumulated value of hot water supply equipment 49.

  Hot water supply equipment 49 does not consume power directly like power consuming equipment 24,

By using the hot water supply equipment 49, the amount of hot water in the hot water storage tank 32 is reduced, and it is preferable to heat the water supplied into the hot water storage tank 32 by power generation. Therefore, the use (the number of operations) of the hot water supply equipment 49 affects the necessity of power generation, and can be said to be an energy consuming device.

  The hot water supply 49 does not directly consume power unlike the power consuming device 24, but the power is consumed to a considerable extent by using the hot water supply 49. Therefore, since the accumulated amount of the salary of the hot water supply equipment 49 affects the necessity of power generation, it can be said that the equipment is an energy consuming device.

  Also, in the comparison of the number of times of operation, the fact that the type of each power consuming device 24 can be determined by analyzing the power transition information from the power smart meter 63 is utilized, for example, by using the rated consumption of each of the power consuming devices 24. Weighting may be performed based on the power to provide a difference in the threshold value N of the number of operations.

  Furthermore, when the energy consuming device is the power consuming device 24, the operation state is not limited to the number of times of operation, but may be a cumulative power consumption value of the power consuming device 24. That is, based on the power transition information from the power smart meter 63, the power consumption of each power consuming device 24 is estimated and accumulated. When the value exceeds a predetermined value, it is determined that the predetermined condition is satisfied, and a display prompting power generation is displayed on the display unit 64 of the remote control panel 46 (see FIG. 4A). Good.

  In the present embodiment, the operation state (the number of operations, etc.) is recognized based on the power transition information from the electric power smart meter 63. However, the number of operations is determined by turning on or off some or all of the energy consuming devices. The off operation may be directly monitored.

10 ENE-FARM (cogeneration equipment)
12 Hot water storage unit 12D Controlled equipment 14 Fuel cell unit 14D Controlled equipment 16 Controller (control unit)
18 Gas supply pipe 18A Branch 18B Branch 18C Branch 20 Fuel processor 22 Stack (power generation unit)
24 Power Consumption Equipment 28 Inverter 30 Heat Exchanger 32 Hot Water Storage Tank 33 Water Pipe 34 CPU
36 RAM
38 ROM
40 I / O
42 Bus 44 Microcomputer 46 Remote control panel 48 House 49 Hot water supply equipment 50 Microcomputer meter 51 Thermistor 52 Stove 54 Gas fan heater 56 Main panel 58 Operation switch 60 Commercial power supply 62 Switching unit 63 Smart meter 64 Display unit (notification unit)

The present invention is a power generation system that performs power generation and supplies power, and includes a control unit that controls at least start and stop of the power generation system, and a notification unit that notifies an operation state of the power generation system. The unit is configured such that, when the power generation system does not generate power due to a factor other than a failure, and when the number of times of operation of the energy consuming equipment is equal to or more than a predetermined number of times , the notification unit does not generate power. It is characterized in that notification information including at least one of information and setting information for confirming operation setting of the power generation system is notified.

The present invention is applied as a fuel cell unit attached to a hot water storage unit to constitute a cogeneration device, wherein the fuel cell unit consumes gas for the purpose of power generation, and generates heat with the power generation. A power generation system that heats water in a hot water storage unit to generate hot water, comprising: a control unit that controls at least the start and stop of the power generation system; and a notification unit that notifies an operation state of the power generation system, The control unit, when the power generation system does not generate power due to a factor other than a failure, and, when the number of hot water supply of hot water supply equipment that receives hot water from the hot water storage unit and supplies hot water is equal to or greater than a predetermined number, At least one of the operation information indicating that the power generation system is not generating power and the setting information for confirming the operation setting of the power generation system in the notification unit. It is characterized by notifying broadcast information including one of information.

FIG. 1 shows a domestic fuel cell cogeneration device according to the present embodiment as an example of a cogeneration device of the present invention (hereinafter, referred to as “ ENEFARM (registered trademark) 10” in the present embodiment). Is shown.

ENE-FARM (registered trademark) 10 is a system in which a hot water storage unit 12 and a fuel cell unit 14 are provided side by side. Note that the juxtaposition is not limited to being physically adjacent, but means that they cooperate with each other. That is, the hot water storage unit 12 and the fuel cell unit 14 may be installed separately from each other and connected by piping, electric wiring, or the like.

ENE-FARM (registered trademark) 10 is controlled by a controller 16.

Note that, in FIG. 1, home appliances and lighting are listed as typical examples of the power consuming devices 24, but in the present embodiment, the power consuming devices 24 are required in the house 48 including home appliances and lighting. All of the electric components indicate power consuming devices (for example, control target devices 12D and 14D (see FIG. 2) related to ENE-FARM (registered trademark) 10; a remote control panel 46 and a gas fan heater 54, which will be described later). In addition, the power consuming device 24 forms a part of the energy consuming device.

Here, since ENE-FARM (registered trademark) 10 normally consumes gas for the purpose of power generation, a certain power generation stoppage is made before 30 days elapse so that the trace leakage monitoring function does not work. A period is set. As an example, once every 27 days of continuous operation, a power generation suspension period of a fixed time (24 hours) is provided, and the alarm counter of the safety function is reset.

Further, a remote control panel 46 is connected to the I / O 40. Remote control panel 46 is installed inside the ENEFARM ® 10 subject of the house 48 which is disposed (see FIG. 1), or enter the command with respect ENEFARM (registered trademark) 10 is a user, Enefarm (Registered Trademark) A function of displaying the status of 10 is provided.

Here, the display unit 64 of the remote control panel 46 displays whether or not power generation is in progress (display mode 1). In addition, the display unit 64 of the remote control panel 46 displays the power supply source (commercial power supply or the fuel cell unit 14 of ENE-FARM (registered trademark) 10) and the power consumption (（kW) thereof. display form 2) is, furthermore, if necessary, electric power selling and buying electricity status and power self-sufficiency of that designed to render (display form 3).

Therefore, in the present embodiment, the power generation function of the fuel cell system 14 of the ENE-FARM (registered trademark) 10 does not generate power due to a factor other than a failure (that is, it can generate power but does not generate power), and When the predetermined condition is satisfied with respect to the operation state of the energy consuming equipment (the power consuming equipment 24 or the hot water supply equipment 49), the operation information indicating that the fuel cell system 14 is not generating power is displayed on the display unit 64 of the remote control panel 46. And the notification information including at least one of the setting information for confirming the operation setting of the fuel cell system 14 is notified.

10 ENE FARM (registered trademark) (cogeneration equipment)
12 Hot water storage unit 12D Controlled equipment 14 Fuel cell unit 14D Controlled equipment 16 Controller (control unit)
18 Gas supply pipe 18A Branch 18B Branch 18C Branch 20 Fuel processor 22 Stack (power generation unit)
24 Power Consumption Equipment 28 Inverter 30 Heat Exchanger 32 Hot Water Storage Tank 33 Water Pipe 34 CPU
36 RAM
38 ROM
40 I / O
42 Bus 44 Microcomputer 46 Remote control panel 48 House 49 Hot water supply equipment 50 Microcomputer meter 51 Thermistor 52 Stove 54 Gas fan heater 56 Main panel 58 Operation switch 60 Commercial power supply 62 Switching section 63 Smart meter 64 Display section (notification section)

Claims (7)

A power generation system that generates power and supplies power,
A control unit that controls at least the start and stop of the power generation system,
A notification unit that notifies the operating status of the power generation system,
The control unit is configured such that, when the power generation system does not generate power due to a factor other than a failure and the operation state of the energy consuming equipment, a predetermined condition is satisfied, the power generation system generates power using the notification unit. A power generation system, comprising: notification information including at least one of operation information indicating that the power generation is not performed and setting information for confirming operation setting of the power generation system.   The power generation system according to claim 1, wherein an operation state of the energy consuming facility is analyzed based on power transition information obtained from a power smart meter. The operation state of the energy consuming facility is the number of times the energy consuming facility operates,
3. The power generation system according to claim 1, wherein the condition is satisfied when the number of operations of the energy consuming facility is equal to or more than a predetermined number. 4. The operation state of the energy consuming facility is a cumulative power consumption value of the energy consuming facility,
3. The power generation system according to claim 1, wherein the condition is satisfied when a cumulative power consumption value of the energy consuming equipment is equal to or greater than a predetermined value. 4.   The power generation system is applied as a fuel cell unit attached to a hot water storage unit, whereby a cogeneration device is configured.The fuel cell unit consumes gas for power generation, and generates heat due to the power generation. The power generation system according to any one of claims 1 to 4, wherein the water in the hot water storage unit is heated to generate hot water. The energy consuming equipment is hot water supply equipment that receives hot water from the hot water storage unit and supplies hot water,
The power generation system according to claim 5, wherein the condition is satisfied when the number of times of hot water supply of the hot water supply facility is equal to or more than a predetermined number. The energy consuming equipment is hot water supply equipment that receives hot water from the hot water storage unit and supplies hot water,
The power generation system according to claim 5, wherein the condition is satisfied when a cumulative value of hot water supply of the hot water supply facility is equal to or greater than a predetermined value.