JP2018185085A - Energy supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an energy supply system capable of stopping the operation of a power generation part and resuming with the appropriate timing without regard for existing other energy feeder to which fuel gas is supplied via the same microcomputer meter.SOLUTION: When determining to satisfy the stop execution condition of a power generation part of a plurality of energy supply feeders E constituting feeders group, a server device 4 of the energy supply system executes a leakage determination avoidance stop processing of transmitting a command to stop the operation of the power generation part to a plurality of energy supply feeders E constituting the feeder group; and a situation in which there is no predetermined gas non-use state including that the state in which the total amount of fuel gas consumed by the plurality of energy supply feeders E constituting the feeder group is equal to or less than the set determination amount for more than the setting determination time is judged as leak judgement, a predetermined period shorter than the use period is determined as a stop execution.SELECTED DRAWING: Figure 1

Description

  The present invention includes an energy supply unit including a power generation unit that generates power using fuel gas supplied via a microcomputer meter, and a power generation side control unit that controls the operation of the power generation unit. When a fuel gas non-consumption state that satisfies a predetermined determination condition including that the gas flow rate is equal to or less than the set determination amount continues for the set determination time or more does not occur during the leakage determination period, an alarm is activated or fuel The present invention relates to an energy supply system configured to cut off the supply of gas.

  If the fuel gas non-consumption state that satisfies the predetermined determination condition including that the flow rate of the fuel gas is equal to or less than the set determination amount continues for the set determination time or more does not occur during the leakage determination period, the microcomputer meter Alarm is activated or fuel gas supply is shut off. When the microcomputer meter performs an alarm operation, for example, the worker who receives the notification has the trouble of shutting off the supply of the fuel gas and checking whether or not the fuel gas is actually leaking. Further, when the microcomputer meter cuts off the supply of fuel gas, there is a troublesome operation to restore the microcomputer meter to the fuel gas supply state. Therefore, it is preferable if the microcomputer meter can avoid the alarm operation due to the fact that the fuel gas non-consumption state has not occurred during the leakage determination period and can prevent the fuel gas supply from being cut off.

  However, in the energy supply system provided with the energy supply device having the power generation unit that generates power using the fuel gas supplied via the microcomputer meter, the operation and stop of the power generation unit are not repeated frequently, The power generation unit is often operated continuously for a relatively long period. Therefore, when the power generation unit continues operation beyond the leakage determination period (for example, 30 days), the flow rate of the fuel gas is obtained based on the set determination amount (for example, 1.0 L / h) or less. Since the fuel gas non-consumption state does not occur during the leakage determination period, a situation occurs in which the microcomputer meter operates as an alarm or shuts off the fuel gas supply.

The energy supply system described in Patent Document 1 includes an energy supply device that includes a power generation unit that generates power using fuel gas supplied via a microcomputer meter and a power generation side control unit that controls the operation of the power generation unit. . In this energy supply system, the energy supply apparatus is configured to be able to know the amount of fuel gas consumed by its power generation unit.
Then, after the operation of the power generation unit is stopped on the day (28 days) corresponding to 2 days before the leakage determination period (30 days) or the day (29 days) corresponding to 1 day before, the operation of the power generation unit is stopped. Determines whether or not the time during which fuel gas is not supplied to the energy supply device has continued for a predetermined time (60 minutes) corresponding to the set continuous time (60 minutes). It is configured to restart the power generation unit when the release condition is satisfied.

  Thus, in the energy supply system described in Patent Document 1, before the period in which the fuel gas non-consumption state does not occur reaches the leakage determination period, at least a period in which the fuel gas is not consumed in the power generation unit is intentionally provided. Thus, an attempt is made to generate a fuel gas non-consumption state.

Japanese Patent Laid-Open No. 2017-022078

  In the energy supply system described in Patent Document 1, it is not assumed that a plurality of energy supply devices that receive the supply of fuel gas from the same microcomputer meter are provided. For example, in a two-family house, a plurality of energy supply devices (power generation units such as fuel cells) are installed on the same site, and fuel is supplied to the plurality of energy supply devices via the same microcomputer meter. Gas may be supplied.

  Therefore, one energy supply device can know the amount of fuel gas consumed by its own energy supply device, but cannot know the amount of fuel gas consumed by another energy supply device. As a result, there is a problem that one energy supply device cannot accurately determine whether or not a fuel gas non-consumption state has occurred with respect to the microcomputer meter.

  The present invention has been made in view of the above-described problems, and its purpose is appropriate regardless of whether or not there is another energy supply device to which fuel gas is supplied via the same microcomputer meter. The point is to provide an energy supply system capable of stopping and restarting the operation of the power generation unit at a proper timing.

In order to achieve the above object, the characteristic configuration of the energy supply system according to the present invention includes a power generation unit that generates power using fuel gas supplied via a microcomputer meter, and a power generation side control that controls the operation of the power generation unit. The microcomputer meter has a fuel gas non-consumption state that satisfies a predetermined determination condition including a state where the flow rate of the fuel gas is equal to or less than a set determination amount for a set determination time or longer. An energy supply system configured to trigger an alarm or shut off the supply of fuel gas when it does not occur during a leak determination period;
A device group comprising a plurality of the energy supply devices to which fuel gas is supplied via the same microcomputer meter,
A server device capable of transmitting / receiving information to / from the plurality of energy supply devices via a communication line;
The server device receives and stores consumption information related to fuel gas consumption in the plurality of energy supply devices via the communication line, and a plurality of devices constituting the device group based on the consumption information. When it is determined that the power generation unit stop execution condition of the energy supply device is satisfied, a plurality of the energy supply constituting the device group is instructed to stop the operation of the power generation unit until the start prohibition release condition is satisfied. The state in which the total fuel gas consumption in the plurality of energy supply devices constituting the device group is equal to or less than the set determination amount is configured to execute leakage determination avoidance stop processing transmitted to the device. The stop execution condition is that a situation in which there is no predetermined gas non-use state including continuous for a set determination time continues for a predetermined period shorter than the leakage determination period. There to that point.
The energy supply device further includes a heat source unit that generates heat using fuel gas supplied via the microcomputer meter, and a heat source side control unit that controls the operation of the heat source unit. Also good.

  According to the above characteristic configuration, the server device has the same microcomputer meter based on the consumption information regarding the consumption amount of the fuel gas in the plurality of energy supply devices to which the fuel gas is supplied via the same microcomputer meter. If it is determined that the stop execution conditions of the power generation units included in the plurality of energy supply devices constituting the device group to which the fuel gas is supplied via the are satisfied, the operation of these power generation units is stopped until the start prohibition release condition is satisfied The leakage determination avoidance stop processing is executed to transmit the command to be transmitted to the plurality of energy supply devices constituting the device group. In this way, after the stop execution condition is satisfied, the operation of the power generation unit is stopped until the start prohibition release condition is satisfied, that is, a period for stopping the fuel gas consumption by the operation of the power generation unit is forcibly provided. Thus, the possibility that the microcomputer meter determines that the fuel gas non-consumption state has occurred during that time is increased.

Further, the server device has a predetermined gas non-use state in which a state in which the total fuel gas consumption in the plurality of energy supply devices constituting the device group is equal to or less than the set determination amount continues for a set determination time or longer. The stop execution condition is that no situation continues for a predetermined period shorter than the leakage determination period. In other words, the server device sets a predetermined period shorter than the leakage determination period before the microcomputer meter determines that the fuel gas non-consumption state does not occur during the leakage determination period. It is determined that the stop execution condition is satisfied, and the operation of the power generation unit is stopped. As a result, it can be expected that a situation in which the microcomputer meter performs an alarm operation or shuts off the supply of fuel gas is avoided.
Therefore, it is possible to provide an energy supply system capable of stopping and restarting the operation of the power generation unit at an appropriate timing regardless of whether there is another energy supply device to which fuel gas is supplied via the same microcomputer meter. .

Another characteristic configuration of the energy supply system according to the present invention is that the server device is related to a plurality of the energy supply devices constituting the device group to which fuel gas is supplied via the same microcomputer meter. Storing the unique identification information given to each of the energy supply devices in association with each other,
The energy supply apparatus is configured to transmit the consumption information together with the identification information to the server apparatus.

  According to the above characteristic configuration, the server device is assigned to each of the plurality of energy supply devices with respect to the plurality of energy supply devices constituting the device group to which the fuel gas is supplied via the same microcomputer meter. Unique identification information is stored in association with each other. Therefore, the server device receives consumption information on the consumption amount of the fuel gas in the energy supply device received together with the identification information from the energy supply device constituting the device group to which the fuel gas is supplied via a specific microcomputer meter. , Managing the fuel gas consumption information related to the fuel gas consumption in the energy supply device received together with the identification information from the energy supply device constituting the same device group to which fuel gas is supplied via the same microcomputer meter it can. Then, the server device determines whether or not the stop execution condition of the power generation unit of the energy supply device is satisfied based on the consumption information of the plurality of energy supply devices constituting the specific device group managed in association with each other. And whether the activation prohibition release condition is satisfied can be determined.

  According to still another feature of the energy supply system according to the present invention, the server device is configured such that the power generation unit included in the plurality of energy supply devices constituting the device group stops operation by the stop process for avoiding leakage determination. A state in which the total fuel gas consumption in the energy supply devices constituting the device group is equal to or less than the set determination amount for a predetermined standby period after the set determination time. It is in the point which makes the said start prohibition cancellation | release condition that there existed no gas non-use state.

  According to the above characteristic configuration, the server device is configured to provide information on the basis of which the microcomputer meter determines whether or not a fuel gas non-consumption state has occurred (consumption of fuel gas in a plurality of energy supply devices and other devices). It is determined whether or not the start prohibition release condition is satisfied using information close to (quantity) (consumption amount of fuel gas in a plurality of energy supply devices). As a result, when the server device determines that the start prohibition release condition has been satisfied during the standby period and commands the restart of the operation of the power generation unit, the microcomputer meter also generates a fuel gas non-consumption state during the standby period. The possibility of determining that it has been increased. Therefore, after the stop execution condition is satisfied, the operation of the power generation unit can be resumed at an appropriate timing after the operation of the power generation unit is stopped.

Still another characteristic configuration of the energy supply system according to the present invention includes a power generation unit that generates power using fuel gas supplied via a microcomputer meter, and a power generation side control unit that controls the operation of the power generation unit. The microcomputer meter includes a fuel gas non-consumption state satisfying a predetermined determination condition including a state in which the flow rate of the fuel gas is equal to or less than a set determination amount for a set determination time or longer. An energy supply system configured to alarm or shut off the supply of fuel gas when it does not occur during
A device group comprising a plurality of the energy supply devices to which fuel gas is supplied via the same microcomputer meter,
A server device capable of transmitting / receiving information to / from the plurality of energy supply devices via a communication line;
The server device is the other energy supply device received from the other energy supply device via the communication line among the one energy supply device and the other energy supply device constituting the device group. The second consumption information on the consumption amount of the fuel gas is transmitted to one of the energy supply devices,
The power generation side control unit of one of the energy supply devices includes the first consumption amount information regarding the consumption amount of the fuel gas in the energy supply device of itself and the first consumption information received from the server device in the other energy supply device. 2 When it is determined that the power generation unit stop execution condition of the plurality of energy supply devices constituting the device group is satisfied based on the consumption information, the operation of the power generation unit of the energy supply device is started. Leakage determination avoidance for transmitting a command to stop the power generation unit of another energy supply device until the prohibition release condition is satisfied and to stop the operation of the power generation unit of the other energy supply device until the start prohibition release condition is satisfied to the other energy supply device A total amount of fuel gas consumed by a plurality of the energy supply devices that are configured to execute a stop process and constitute the device group is determined by the setting value. The situation where there is no predetermined gas non-use state that includes a state where the amount is less than or equal to the amount continues for the set determination time or longer is that the stop execution condition is that the state continues for a predetermined period shorter than the leakage determination period. .

  According to the above characteristic configuration, the server device is the other energy supply device received from the other energy supply device via the communication line among the one energy supply device and the other energy supply devices constituting the device group. The second consumption amount information relating to the consumption amount of the fuel gas is transmitted to one energy supply device. As a result, the power generation side control unit of one energy supply device has the first consumption information on the consumption amount of the fuel gas in its own energy supply device and the fuel gas in the other energy supply device received from the server device. It is possible to know the second consumption information related to the consumption. And if the electric power generation side control part of one energy supply apparatus judges with the stop execution condition of the electric power generation part which an apparatus group has satisfy | filled based on those 1st consumption information and 2nd consumption information, the apparatus group The operation of the power generation unit of its own energy supply device is stopped until the start prohibition release condition is satisfied, and the power generation unit of another energy supply device so that the fuel gas non-consumption state occurs with respect to the microcomputer meter that supplies fuel gas to The leakage determination avoidance stop processing is executed to transmit a command to stop the operation until the start prohibition release condition is satisfied to the other energy supply device. In this way, after the stop execution condition is satisfied, the operation of the power generation unit of the energy supply device constituting the device group is stopped until the start prohibition release condition is satisfied, that is, the consumption of fuel gas due to the operation of the power generation unit is reduced. By forcibly providing the period to be stopped, the possibility that the microcomputer meter determines that the fuel gas non-consumption state has occurred during that time increases.

  Particularly in this feature configuration, the power generation side control unit of one energy supply device sets a predetermined period shorter than the leakage determination period, so that the fuel gas non-consumption state is set between the leakage determination period by the microcomputer meter. Before it is determined that the power generation unit does not occur, it is determined that the stop execution conditions for the power generation units of the plurality of energy supply devices constituting the device group are satisfied, and the operation of the power generation unit is stopped. As a result, it can be expected that a situation in which the microcomputer meter performs an alarm operation or shuts off the supply of fuel gas is avoided.

Still another characteristic configuration of the energy supply system according to the present invention relates to a plurality of the energy supply devices constituting the device group in which the server device is supplied with fuel gas via the same microcomputer meter. Storing unique identification information assigned to each of the plurality of energy supply devices in association with each other;
The other energy supply device transmits the second consumption information together with the identification information to the server device.

  According to the above characteristic configuration, the server device is assigned to each of the plurality of energy supply devices with respect to the plurality of energy supply devices constituting the device group to which the fuel gas is supplied via the same microcomputer meter. Unique identification information is stored in association with each other. Therefore, even if the server apparatus receives the second consumption information related to the fuel gas consumption in the energy supply apparatus from other energy supply apparatuses together with the identification information, the server apparatus transmits the consumption information to which energy supply apparatus. You can identify what to do.

  Still another characteristic configuration of the energy supply system according to the present invention is that the power generation side control unit of one energy supply device includes a plurality of the energy supply devices constituting the device group by the leakage determination avoidance stop process. The state in which the total fuel gas consumption in the energy supply device constituting the device group is equal to or less than the set determination amount during a predetermined standby period after the power generation unit having stopped operating The starting prohibition canceling condition is that there is a predetermined gas non-use state including continuous for more than the determination time.

  According to the above characteristic configuration, the power generation side control unit of one energy supply device provides information (a plurality of energy supply devices and other information) that is used as a basis when the microcomputer meter determines whether or not a fuel gas non-consumption state has occurred. It is determined whether or not the start prohibition release condition is satisfied, using information (consumption amount of fuel gas in a plurality of energy supply devices) that is close to the consumption amount of fuel gas in this device. As a result, when the power generation side control unit determines that the start prohibition cancellation condition has been satisfied during the standby period and restarts the operation of the power generation unit, the fuel meter non-consumption state also occurs in the microcomputer meter during the standby period. The possibility of determining that it has been increased. Therefore, after the stop execution condition is satisfied, the operation of the power generation unit can be resumed at an appropriate timing after the operation of the power generation unit is stopped.

It is a figure which shows the structure of an energy supply system. It is a figure which shows the structure of the energy supply apparatus with which an energy supply system is provided. It is the figure which described the structure of the heat source unit concretely. It is the figure which described the structure of the electric power generation unit concretely. It is a flowchart explaining the leak determination avoidance process which a server apparatus performs. It is a flowchart explaining the leak determination avoidance process which a power generation side control part performs. It is a figure which shows the structure of the energy supply system of 3rd Embodiment.

An energy supply system according to an embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of an energy supply system. FIG. 2 is a diagram illustrating a configuration of an energy supply device E included in the energy supply system. The energy supply system includes a device group including a plurality of energy supply devices E (E1, E2) to which fuel gas is supplied via the same microcomputer meter M. As shown in FIG. 2, each energy supply device E controls the operation of the cogeneration unit 41 and the cogeneration unit 41 as the power generation unit A that generates power using the fuel gas supplied via the microcomputer meter M. A power generation unit 40 having a power generation side control unit 92 is provided. In addition, the energy supply system includes a server device 4 that can transmit and receive information to and from the plurality of energy supply devices E via the communication line 3. In the present embodiment, each energy supply device E includes a heat source unit B that generates heat using the fuel gas supplied via the microcomputer meter M, and a heat source side control unit 25 that controls the operation of the heat source unit B. Is further provided. In addition, the power generation unit 40 of the present embodiment includes a power generation side communication unit 93, a power generation side storage unit 94, and a flow meter Fa. Further, the heat source unit 10 of the present embodiment includes a heat source side communication unit 26, a heat source side storage unit 27, and a flow meter Fb.
Specific configurations of the power generation unit 40 and the heat source unit 10 will be described later.

  In the present embodiment, a plurality of energy supply devices E1 and E2 are installed in the same facility 5 (for example, a residence or a business office). Therefore, the fuel gas G is supplied to the plurality of energy supply devices E1 and E2 via the gas pipe 1 connected to the downstream side of the same microcomputer meter M. The gas pipe 1 is also connected to another gas consuming device 2 such as a gas stove, and the fuel gas G is supplied. For example, in a two-family house or the like, two energy supply devices E are installed in the same facility 5 as shown in FIG. 1, and these two energy supply devices E are routed through the same microcomputer meter M. Fuel gas is supplied. In such a case, one energy supply device E can know the amount of fuel gas consumed by its own energy supply device E, but directly knows the amount of fuel gas consumed by another energy supply device E. It is not possible.

  In the microcomputer meter M, a fuel gas non-consumption state that satisfies a predetermined determination condition including a state in which the flow rate of the fuel gas G is equal to or less than the set determination amount continues for the set determination time does not occur during the leakage determination period. In some cases, it has a function of operating an alarm or shutting off the supply of the fuel gas G. For example, in the case of an ultrasonic microcomputer meter M, the determination condition (that is, the flow rate of the fuel gas G) for determining that the fuel gas is not consumed in the leakage determination period (for example, 30 days) of the microcomputer meter M. Is the set determination amount (for example, 1.0 L / h) or less, the integrated value of the duration when the state is equal to or greater than the set determination time (for example, 2 minutes or more) is the set value or more (for example, 60 minutes). If the (condition) is not satisfied, the microcomputer meter M operates as an alarm or cuts off the supply of the fuel gas G.

[Heat source unit 10]
As illustrated in FIG. 3, the heat source unit 10 is configured as a general hot water heater, and heats hot water W supplied via the heat source side water intake section 20 a to a preset hot water supply temperature to supply hot water. In addition to performing a so-called hot water supply operation for supplying to the plug 30, a heating operation for heating the heating medium H flowing through the heating circulation path 34 for circulating the heated heating medium to the heating radiator 33 is performed. The external interface is provided at one end of the water supply pipe 20 and is provided with a heat source side water intake portion 20 a for taking hot water W into the water supply pipe 20 from the outside, and the hot water W of the water supply pipe 20 provided at the other end of the water supply pipe 20. The heat source side water discharge part 20b that discharges the heat to the outside, the heat source side heat medium receiving part 16a that is provided on one end side of the heat medium flow path 16 and takes in the heat medium H from the outside into the heat medium flow path 16 and the heat medium flow path 16 A heat source side heat medium discharge part 16b that discharges the heat medium H of the heat medium flow path 16 to the outside, a fuel gas supply part 14 that takes in a fuel gas G such as city gas, and the like are provided. The water supply pipe 20 is provided with a bypass adjustment valve 24 in a form in which the upstream side and the downstream side of the hot water supply heat exchanger 11b are connected.

  By connecting the heat source side water outlet 20b to the hot water tap 30, hot water W discharged from the heat source side water outlet 20b is supplied to the hot water tap 30. Further, the heat source side heat medium receiving unit 16a and the heat source side heat medium discharging unit 16b take in the heat medium H that circulates in the heating circuit 34 provided between the heat radiator 33 such as a hot water floor heating panel or the like. It is connected to the heating circulation path 34 in a discharge form. The heating circulation path 34 has a predetermined flow rate out of the total amount of the heat medium H discharged from the heat source side heat medium discharge section 16 b to the heating radiator 33 provided in the heating circulation path 34 via the forward header 31. On the other hand, the heat medium H that has passed through the heating radiator 33 passes through the return header 32 and passes through the power generation side heat medium flow path 104 that guides the entire amount of the heat medium H that has passed through the return header 32 to the power generation unit 40. It is arranged to flow back to the heat source side heat medium receiving portion 16a.

  The heat source unit 10 is provided with a heat source side control unit 25 that includes a computer that controls the operation of the burners 11a and 12a and controls the operation of various auxiliary machines such as valves and pumps.

The heat source unit 10 takes in the hot water supply heating part 11 for heating the hot water W taken in the heat source side water intake part 20a and discharged from the heat source side water discharge part 20b, and the heat source side heat medium receiving part 16a. And a heating unit 12 for heating the heating medium H discharged from the discharge unit 16b. The hot water supply heating unit 11 and the heating heating unit 12 correspond to the heat source unit B of the present invention.
The hot water supply heating unit 11 exchanges heat between the burner 11a for burning the fuel gas G supplied via the regulating valve 11c with the combustion air supplied by the fan 13 and the high-temperature combustion gas discharged from the burner 11a. The hot water supply heat exchanger 11b that heats the hot water W flowing through the water supply pipe 20 is configured.
The heating heating unit 12 exchanges heat between the burner 12a for burning the fuel gas G supplied through the regulating valve 12c with the combustion air supplied by the fan 13 and the high-temperature combustion gas discharged from the burner 12a. And a heating heat exchanger 12b for heating the heat medium H flowing through the heat medium flow path 16.

In addition, a third temperature sensor 21 that detects the temperature of hot water W taken from the heat source side water inlet 20a (hereinafter sometimes referred to as “heat source side water inlet temperature”) and a heat source side outlet A fourth temperature sensor 22 for detecting the temperature of hot water W discharged from 20b (hereinafter sometimes referred to as “heat source side outlet temperature”) and a water switch 23 for detecting the flow of hot water W are disposed. .
On the other hand, in the heat medium flow path 16, a first temperature sensor 17 that detects the temperature of the heat medium H taken from the heat source side heat medium receiving unit 16 a (hereinafter sometimes referred to as “heat source side heat medium temperature”). And a second temperature sensor 18 for detecting the temperature of the heat medium H discharged from the heat source side heat medium discharge section 16b (hereinafter sometimes referred to as “heat source side heat output medium temperature”), and the heat medium H is sent out. A heat medium pump 19 is arranged.

  With this configuration, the heat source side control unit 25 heats the hot water W supplied from the heat source side water intake unit 20a to a set hot water supply temperature set in advance by a remote controller (not shown) and supplies the hot water supply 30 to the hot water tap 30. It becomes possible to execute a heating operation in which the heating medium H circulating in the heating circulation path 34 provided between the heating radiator 33 and the heating radiator 33 is heated to a preset target temperature.

[Power generation unit 40]
As illustrated in FIG. 4, the power generation unit 40 is configured as an integrated type in which various devices are arranged in one housing 60 provided in parallel with the heat source unit 10 described above. The power generation unit 40 has, as external interfaces, a power generation side water intake portion 80a that takes hot water W (water) from the water supply, a power generation side water discharge portion 78a that discharges the hot water W toward the heat source unit 10, and a drainage channel that drains the hot water storage tank 90. 74, a drain valve 75, a power generation side heat medium receiving portion 58a that takes in the heating medium H from the heat source unit 10 side, a power generation side heat medium discharge portion 58b that discharges the heat medium H to the heat source unit 10 side, and the like. Yes.
Furthermore, a combined heat and power supply unit 41 provided on the power generation unit 40 side and a power generation side control unit 92 including a computer for controlling the operation of various auxiliary machines such as valves and pumps are provided.

  The cogeneration unit 41 as the power generation unit A included in the power generation unit 40 is a fuel cell power generation device, an engine-driven power generation device, or the like. For example, in the case of a fuel cell power generation device, a reforming processing device that reforms the supplied fuel gas G and a fuel cell that generates power using hydrogen obtained by the reforming processing are provided. If it is an engine drive type generator, it will have an engine which consumes fuel gas G as fuel, and operates, and a generator driven by the engine. The electric power generated in the combined heat and power supply unit 41 is supplied to an external electric power load or the like in a form linked with a commercial power supply through an inverter or the like as appropriate. Further, the heat generated by the combined heat and power supply unit 41 is used for heating the hot water W, and a hot water storage tank 90 for storing the heated hot water W is provided.

  The cogeneration unit 41 has a structure cooled by cooling water C flowing through a cooling water jacket (not shown) provided therein, for example, and is provided with a cooling water circulation path 42 through which the cooling water C circulates. Yes. In the cooling water circulation path 42, a cooling water pump 46 that sends out the cooling water C along the circulation direction of the cooling water C, an electromagnetic valve 47 that can interrupt the flow of the cooling water C, and a cooling water jacket ( A sixth temperature sensor 50 for detecting the cooling water entering temperature to the heating heat exchanger 56 provided on the downstream side of the cooling water jacket with the cooling water C discharged from the cooling water jacket, a heat medium to be described later A heat exchanger 56 for heating that exchanges heat between the heat medium H that flows through the bypass 104b and the cooling water C that has exited the cooling water jacket in the cooling water circulation path 42, and outlet cooling water for the heating heat exchanger 56 An eighth temperature sensor 57 for detecting the temperature, a cooling water three-way regulating valve 45 for controlling the distribution flow rate of the cooling water C flowing through the cooling water circulation path 42 side and the cooling water bypass path 43 side, and the cooling water C Bufferer that temporarily stores And click 51 is arranged in the order of description.

  The buffer tank 51 is provided with a fifth temperature sensor 49 for detecting the cooling water merging temperature on the downstream side which is merged by the cooling water three-way regulating valve 45 at the temperature of the cooling water C temporarily stored. . Moreover, the hot water W supplied to the power generation side water inlet 80 a is appropriately replenished to the buffer tank 51 as the cooling water C through the replenishment water channel 53 and the electromagnetic valve 52. The cooling water bypass passage 43 is provided with a hot water storage heat exchanger 55 for exchanging heat between the hot water W stored in the hot water storage tank 90 and the cooling water C, and detects the outlet cooling water temperature of the hot water storage heat exchanger 55. A seventh temperature sensor 54 is provided.

  That is, in a state where heat is generated in the combined heat and power supply unit 41, the heat medium pump 19 is operated, the heat medium H is passed through the heating heat exchanger 56, and the cooling water pump 46 is operated. When the cooling water C is circulated through the cooling water circulation path 42, the cooling water C heated through the combined heat and power supply unit 41 passes through the hot water storage heat exchanger 55 and the heating heat exchanger 56, thereby causing the hot water W and Heat exchange is performed with the heat medium H, and the heat and power supply unit 41 is supplied again.

  In addition, the cooling water circulation path 42 is a solenoid valve that adjusts the flow rate of the cooling water C that flows through the combined heat and power supply unit bypass path 44 that connects the upstream side and the downstream side of the combined heat and power supply unit 41 and the combined heat and power supply unit bypass path 44. 48 and an electromagnetic valve 47 that adjusts the flow rate of the cooling water circulation path 42 just before the inlet of the combined heat and power supply unit 41 is provided. Thereby, in a state where the cooling water C is circulating in the cooling water circulation path 42, the electromagnetic valve 47 disposed on the upstream side of the combined heat and power supply unit 41 is closed and the electromagnetic valve disposed in the combined heat and power supply unit bypass path 44. By opening the valve 48, the entire amount of the cooling water C can be passed through the combined heat and power supply unit bypass passage 44 by bypassing the combined heat and power supply unit 41.

  In addition, if description is added regarding the arrangement | positioning position of the heat exchanger 56 for heating, the heat exchanger 56 for heating will cool in the flow direction of the cooling water C in the cooling water circulation path 42 in the downstream of the cogeneration part 41. The connection part of the water circulation path 42 and the combined heat and power supply bypass path 44 and the upstream connection part of the cooling water bypass path 43 and the cooling water circulation path 42 (upstream connection in the cooling water C flow direction in the cooling water bypass path 43 Between the two parts).

The hot water storage tank 90 is configured as a sealed tank in which hot water W is supplied to the lower part 90b and hot water W is taken out from the upper part 90a to the power generation side water discharge part 78a.
The upper pipe line 66 connected to the upper part 90 a of the hot water storage tank 90 is connected to a power generation side water discharge part 78 a via a hot water three-way regulating valve 77 and a hot water pipe 78, and upstream of the hot water three-way regulating valve 77. Is provided with a ninth temperature sensor 76 for detecting the temperature of hot water W taken out from the upper portion 90a of the hot water storage tank 90 to the upper conduit 66 (hereinafter sometimes referred to as “tank extracted hot water temperature”). The detection of the temperature of the hot water taken out from the tank may be performed by the temperature sensor 91a provided at the top of the plurality of temperature sensors 91 distributed in the vertical direction of the hot water storage tank 90, instead of the ninth temperature sensor 76. I do not care.
The hot water / three-way regulating valve 77 is connected to a water supply pipe 82 leading to the power generation side water intake section 80a. Further, the hot water outlet line 78 and the water supply line 82 are connected by a bypass line 86, and an electromagnetic valve 87 capable of interrupting the flow of the hot water W is disposed in the bypass line 86.
That is, the hot and cold three-way regulating valve 77 mixes hot water W supplied from the water supply pipe 82 with mixing ratio adjustment with hot water W supplied from the upper portion 90a of the hot water storage tank 90 to the power generation side water discharge section 78a. Functions as a possible mixing section.
Note that, on the downstream side of the connection portion of the hot water supply pipe 78 with the bypass pipe 86, the flow rate sensor 79 that detects the flow rate of the hot water W and the power generation side water discharge section 78a are discharged along the flow direction of the hot water W. A tenth temperature sensor 81 that detects the temperature of the hot water W (hereinafter, may be referred to as “power generation side outlet temperature”) is arranged in the order described.
On the other hand, on the upstream side of the connection part of the water supply pipe line 82 with the bypass pipe line 86, the pressure reducing valve 84 for adjusting the pressure of the hot water W and the power generation side water intake part 80a are supplied along the flowing direction of the hot water W. An eleventh temperature sensor 85 for detecting the temperature of the hot water W and a check valve 83 for preventing the back flow of the hot water W are arranged in the order described.

  Further, the water supply pipe 82 is connected to the bottom pipe line 72 connected to the lower part 90b of the hot water storage tank 90 via a check valve 89. With this configuration, in the hot water storage tank 90, hot water is supplied from the upper part 90a. At the same time that W is taken out, hot water W is supplied from the lower portion 90 b through the water supply line 82 and the bottom line 72.

The heating circulation path 34 will be described in detail. The heating circulation path 34 includes a power generation side heat medium flow path 104 that guides the entire amount of the heat medium H that has passed through the return header 32 to the power generation unit 40, and a power generation side heat medium. A heat medium bypass passage 104 b that bypasses part or all of the heat medium H flowing through the flow path 104 to the heating heat exchanger 56 side is provided.
If the explanation is added, the power generation side heat medium flow path 104 is provided inside the case of the power generation unit 40 via the power generation side heat medium receiving portion 58a and the power generation side heat medium discharge portion 58b. It is connected to the flow path 104a. Further, a heat medium three-way adjustment valve 113 is provided that can adjust the distribution flow rate of the heat medium H to the power generation side heat medium flow path 104a side in the casing and the heat medium bypass path 104b side.
The in-casing power generation side heat medium flow path 104a has a heat medium temperature at the downstream side of the portion where the heat medium flowing through both the in-housing power generation side heat medium flow path 104a and the heat medium bypass path 104b joins. A twelfth temperature sensor 102b for detecting the merging temperature is provided.
Although the details will be described later, the power generation side control unit 92 controls the distribution flow rate of the heat medium H to the power generation side heat medium flow path 104a side and the heat medium bypass path 104b side in the housing by the heat medium three-way adjustment valve 113. The heat medium circulation state control is executed in the form of adjustment.
Here, the power generation unit 40 according to the embodiment does not include a heat medium pump that pumps the heat medium H in the casing, and has a discharge pressure of the heat medium pump 19 provided in the heat source unit 10. Heat medium is circulated.

[Server device 4]
The energy supply system includes a server device 4 that can transmit and receive information to and from a plurality of energy supply devices E via the communication line 3. The server device 4 receives and stores consumption information regarding the consumption of fuel gas at the plurality of energy supply devices E via the communication line 3. In the present embodiment, the power generation unit 40 and the heat source unit 10 are connected by the information communication line 6, and the consumption amount of the fuel gas in the heat source part B of the heat source unit 10 via the information communication line 6 is the heat source. It is transmitted from the unit 10 to the power generation unit 40. As a result, the power generation side control unit 92 of the power generation unit 40 can know the total consumption amount of the fuel gas G in the heat and power supply unit 41 and the heat source unit B of its own energy supply device E, and the total fuel gas Is transmitted to the server device 4 via the communication line 3 as the consumption information.

  Specifically, the power generation unit 40 of the energy supply device E1 transmits first consumption amount information regarding the consumption amount of the fuel gas G in the energy supply device E1 to the server device 4 at a predetermined timing. Similarly, the power generation unit 40 of the energy supply device E2 transmits the second consumption amount information regarding the consumption amount of the fuel gas G in the energy supply device E2 to the server device 4 at a predetermined timing. Therefore, the server device 4 can know the total consumption amount of the fuel gas G in the plurality of energy supply devices E1 and E2 to which the fuel gas G is supplied via the same microcomputer meter M. The consumption information also includes time information indicating at which time or time the consumption is measured.

[Leakage judgment avoidance process]
The server device 4 includes a plurality of devices constituting the device group based on the consumption information (first consumption information and second consumption information) received from the plurality of energy supply devices E constituting the device group as described above. If it is determined that the stop execution condition of the combined heat and power supply unit 41 of the energy supply device E is satisfied, a plurality of energies constituting the device group are instructed to stop the operation of the combined heat and power supply unit 41 until the start prohibition release condition is satisfied. The leakage determination avoidance stop process transmitted to the supply device E is executed.

  In the present embodiment, the server device 4 has a predetermined state including a state in which the total fuel gas consumption in the plurality of energy supply devices E constituting the device group is equal to or less than the set determination amount continues for the set determination time or longer. The stop execution condition is that a state in which no gas is not used continues for a predetermined period shorter than the leakage determination period.

  Further, the server device 4 configures the device group during a predetermined standby period after the combined operation of the heat and power supply units 41 included in the plurality of energy supply devices E constituting the device group by the leakage determination avoidance stop process. The start prohibition cancellation condition is that there is a predetermined gas non-use state including a state in which the total fuel gas consumption in the energy supply device E is equal to or less than the set determination amount for a set determination time or longer.

FIG. 5 is a flowchart for explaining leakage determination avoidance processing performed by the server device 4. In the leakage determination avoidance process shown in FIG. 5, when the stop execution condition of the combined heat and power supply unit 41 of the plurality of energy supply devices E to which the fuel gas is supplied via the same microcomputer meter M is satisfied, the combined heat and power supply A plurality of processes are included such as a leakage determination avoidance stop process for instructing to stop the operation of the unit 41 until the start prohibition release condition is satisfied, and a process for instructing transmission of a message to refrain from using fuel gas.
Further, as described above, the power generation unit 40 and the heat source unit 10 are each provided with the flow meter Fa and the flow meter Fb that measure the flow rate of the fuel gas G, and the first consumption information and the 2 Consumption information is transmitted from the energy supply device E to the server device 4 via the communication line 3. As a result, the server device 4 calculates the total consumption amount of the fuel gas G in the plurality of energy supply devices E (the combined heat and power supply unit 41 and the heat source unit B) to which the fuel gas is supplied via the same microcomputer meter M. Can be recognized.

  First, in the server device 4, the total consumption amount of the fuel gas G in the plurality of energy supply devices E constituting the device group to which the fuel gas is supplied via the same microcomputer meter M is equal to or less than the set determination amount. It is determined whether or not a state in which there is no first gas non-use state including that the state continues for a set determination time or more continues for a predetermined period (26 days) shorter than the leakage determination period (30 days) (# 10). . In the present embodiment, the first gas non-use state is a state in which the total consumption amount of the fuel gas G in the plurality of energy supply devices E (the combined heat and power supply unit 41 and the heat source unit B) is equal to or less than the set determination amount for 60 minutes. This is a state where there are four consecutive times.

Then, the server device 4 determines that the stop execution condition is satisfied when the state in which the first gas is not used continues for 26 days, and determines that each of the plurality of energy supply devices E constituting the device group is satisfied. The power generation unit 40 is instructed to prohibit activation to prohibit activation of the cogeneration unit 41 (# 11). As a result, the power generation side control unit 92 of each power generation unit 40 executes an operation stop process for stopping the operation of the combined heat and power supply unit 41.
The server device 4 returns to the beginning of this flowchart when it is determined in # 10 that the state in which the first gas is not in use has not passed for 26 days.

  Next, when the server apparatus 4 recognizes that all of the combined heat and power supply units 41 have stopped in # 12, the server apparatus 4 starts measuring the first set stop period (standby period of the present invention) T1, and the first set stop period ( (Waiting period) It is determined whether or not the second gas is not used until T1 expires (# 13, # 14). In the present embodiment, in the second gas non-use state, the total consumption amount of the fuel gas G in the plurality of energy supply devices E (the combined heat and power supply unit 41 and the heat source unit B) constituting the device group is equal to or less than the set determination amount. It is a state where there existed twice that this state continues for 60 minutes. In addition, the server device 4 can recognize that the combined heat and power supply unit 41 has stopped when, for example, the consumption amount of fuel gas in the power generation unit 40 included in each energy supply device E becomes zero. Alternatively, the server device 4 may be configured to receive information indicating that the combined heat and power supply unit 41 has been stopped from the power generation unit 40.

  When the server device 4 determines that the second gas non-use state has been present before the first set stop period (waiting period) T1 expires, the server device 4 determines that the activation prohibition release condition is satisfied, The cancellation of the start prohibition is transmitted to the power generation unit 40 of each energy supply device E (# 19), and it is determined that there is no second gas non-use state until the first set stop period (standby period) T1 expires. In this case, transmission of a message to refrain from using the gas is transmitted to the power generation unit 40 of each energy supply device E (# 15). As described above, the server device 4 is the information that is the basis when the microcomputer meter M determines whether or not the fuel gas non-consumption state has occurred (in the combined heat and power supply unit 41, the heat source unit B, and other gas consuming devices 2). It is determined whether or not the start prohibition release condition is satisfied using information (consumption amount of fuel gas in the combined heat and power supply unit 41 and the heat source unit B) that is close to the fuel gas consumption amount). As a result, when the server device 4 determines that the start prohibition cancellation condition is satisfied during the standby period and commands the restart of the operation of the combined heat and power supply unit 41, the microcomputer meter M also does not consume fuel gas during the standby period. The possibility that it is determined that has occurred increases. Therefore, after the stop execution condition is satisfied, the operation of the cogeneration unit 41 can be resumed at an appropriate timing after the operation of the cogeneration unit 41 is stopped.

  Thereafter, in # 16, the server apparatus 4 starts measuring the second set stop period T2, and receives it from the plurality of energy supply apparatuses E constituting the apparatus group until the second set stop period T2 expires. Based on the consumed amount information, it is determined whether or not the third gas is not used (# 17, # 18). In the present embodiment, the third gas non-use state is that the total consumption amount of the fuel gas G in the plurality of energy supply devices E (the combined heat and power supply unit 41 and the heat source unit B) constituting the device group is equal to or less than the set determination amount. This state is a state where there is once a continuous state for 60 minutes. When the server device 4 determines that the third gas non-use state has been present before the second set stop period T2 expires, the server device 4 determines that the start prohibition cancel condition is satisfied, and cancels the start prohibition. To the power generation unit 40 of each energy supply device E (# 19), and if it is determined that there is no third gas non-use state before the second set stop period T2 expires, the process returns to # 17.

Second Embodiment
The energy supply system of the second embodiment is different from the above-described embodiment in that one energy supply device E performs a leakage determination avoidance process. Although the energy supply system of 2nd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

  In the present embodiment, the power generation side control unit 92 of one energy supply device E among the plurality of energy supply devices E constituting the device group has a first consumption related to the amount of fuel gas consumed by the energy supply device E itself. Based on the amount information and the second consumption information in the other energy supply devices E received from the server device 4, the stop execution condition of the combined heat and power unit 41 of the plurality of energy supply devices E constituting the device group is satisfied. If it is determined, the operation of the cogeneration unit 41 of its own energy supply device E is stopped until the start prohibition release condition is satisfied so that the fuel gas non-consumption state occurs with respect to the microcomputer meter M that supplies fuel gas to the device group. And a command to stop the operation of the cogeneration unit 41 of the other energy supply device E until the start prohibition release condition is satisfied is transmitted to the other energy supply device E. Mode to execute the judgment avoiding stop process.

  When there are a plurality of energy supply devices E constituting the device group, which energy supply device is used as the one energy supply device can be appropriately set. For example, an energy supply device having a long accumulated working day (that is, installed earlier in time) or an energy supply device having a long accumulated energization time automatically becomes the one energy supply device. It may be set. Alternatively, a switch for switching between “main” and “subordinate” is provided in the power generation unit 40 constituting the energy supply device, and the energy supply device to which the user switches the switch to “main” is the one energy supply described above. The energy supply device E that is switched to “subordinate” by the user may be the other energy supply device.

  And in this embodiment, the electric power generation side control part 92 of one energy supply apparatus E has the state in which the consumption of the total fuel gas in the several energy supply apparatus E which comprises an apparatus group becomes below a setting determination amount. The stop execution condition is that a situation in which there is no predetermined gas non-use state including continuing for the set determination time or longer continues for a predetermined period shorter than the leakage determination period.

  Further, the power generation side control unit 92 of one energy supply device E waits for a predetermined time after the combined operation of the heat and power supply units 41 included in the plurality of energy supply devices E constituting the device group by the leakage determination avoidance stop process. During the period, there was a predetermined gas non-use state including a state where the total fuel gas consumption in the energy supply device E constituting the device group is equal to or less than the set determination amount for a set determination time or more. This is the activation prohibition release condition.

  Therefore, among the plurality of energy supply devices E constituting the device group, the other energy supply devices E obtain second consumption information related to the consumption amount of the fuel gas G in the heat / electricity supply unit 41 and the heat source unit B. The data is transmitted to the server device 4 via the communication line 3 at a predetermined timing. Then, the server device 4 receives the second consumption amount related to the consumption amount of the fuel gas G in the energy supply device E (the combined heat and power supply unit 41 and the heat source unit B) received from the other energy supply device E via the communication line 3. Information is transmitted to one energy supply device E at a predetermined timing via the communication line 3. As a result, one energy supply device E receives the second consumption information from the server device 4 in addition to the first consumption information related to the consumption amount of the fuel gas in its own energy supply device E. You can also know consumption information. Therefore, the power generation side control unit 92 of one energy supply device E includes a plurality of energy supply devices E (a combined heat and power supply unit 41 and a heat source) that constitute a device group to which the fuel gas G is supplied via the same microcomputer meter M. The total amount of fuel gas G consumed in part B) can be known.

  FIG. 6 is a flowchart for explaining leakage determination avoidance processing performed by the power generation side control unit 92 of the power generation unit 40 of one energy supply device E. In the leakage determination avoidance process shown in FIG. 6, when the stop execution condition of the combined heat and power unit 41 included in the plurality of energy supply devices E constituting the device group is satisfied, the operation of the own combined heat and power supply unit 41 is started prohibition canceling condition. And a plurality of processes such as a leakage determination avoidance stop process for giving a command to stop the operation of the other combined heat and power supply unit 41 until the start prohibition release condition is satisfied.

First, the power generation side control section 92 of the energy supply apparatus E1 includes all the energy supply apparatuses E (the combined heat and power supply section 41 and the heat source section B) that constitute the apparatus group to which the fuel gas G is supplied via the same microcomputer meter M. ) In which there is no first gas non-use state including a state in which the total consumption amount of the fuel gas G is equal to or less than the set determination amount is longer than the set determination time is shorter than the leakage determination period (30 days). It is determined whether or not a predetermined period (26 days) has continued (# 30). If 26 days have elapsed, it is determined that the stop execution condition has been satisfied, and the combined heat and power supply unit 41 of its own energy supply device E1 is determined. Is set to prohibit the start of the power, and the other energy supply device E2 is instructed to prohibit the start of the combined heat and power supply unit 41 via the server device 4 (# 31). Stop driving 41 Shutdown process is executed to (# 32). Moreover, also in other energy supply apparatus E2, the electric power generation side control part 92 performs the operation | movement stop process which stops the driving | operation of the own heat and power supply part 41 itself.
When the power generation side controller 92 of the energy supply device E1 determines that # 26 has not passed for 26 days, the process returns to the beginning of this flowchart.

  Next, in # 33, the power generation side control unit 92 of the energy supply device E1 starts measuring the first set stop period (standby period) T1 until the first set stop period (standby period) T1 expires. In the meantime, it is determined whether or not the second gas is not used (# 34, # 35). In the present embodiment, in the second gas non-use state, the total consumption amount of the fuel gas G in the plurality of energy supply devices E (the combined heat and power supply unit 41 and the heat source unit B) constituting the device group is equal to or less than the set determination amount. It is a state where there existed twice that this state continues for 60 minutes.

  When the power generation side control unit 92 of the energy supply device E1 determines that the second gas is not used before the first set stop period (standby period) T1 expires, the activation prohibition release condition is satisfied. It determines with satisfy | filling, and cancels starting prohibition of the combined heat and power supply part 41 of its own energy supply apparatus E1, and commands cancellation of starting prohibition of the combined heat and power supply part 41 to the other energy supply apparatus E2 (# 40). . Note that the power generation side control unit 92 of the energy supply device E1 refrains from using the gas when it is determined that there is no second gas non-use state before the first set stop period (standby period) T1 expires. Is transmitted to the user with its own remote controller (not shown) or the like, and the other energy supply device E2 is instructed to transmit a message to refrain from using the gas (# 36). As a result, the other energy supply device E2 also transmits a message to refrain from using the gas.

  As described above, the power generation side control unit 92 of one energy supply device E provides information (a thermoelectric supply unit 41 and a heat source unit) that is a basis for the microcomputer meter M to determine whether or not a fuel gas non-consumption state has occurred. Whether or not the start prohibition release condition is satisfied using information (consumption of fuel gas in the heat and power supply unit 41 and the heat source unit B) that is close to the consumption amount of fuel gas in B and other gas consuming devices 2) Determine. As a result, when the power generation side control unit 92 of one energy supply device E determines that the start prohibition cancellation condition is satisfied during the standby period and restarts the operation of the combined heat and power supply unit 41 of each energy supply device E, the microcomputer The possibility that the meter M determines that the fuel gas non-consumption state has occurred during the standby period is also increased. Therefore, the operation of the combined heat and power unit 41 of each energy supply device E can be resumed at an appropriate timing after the operation of the combined heat and power unit 41 of each energy supply device E is stopped by satisfying the stop execution condition.

  After that, in # 37, the power generation side control unit 92 of the energy supply device E1 starts measuring the second set stop period T2, and the third gas non-use state until the second set stop period T2 expires. Is determined (# 38, # 39). In the present embodiment, the third gas non-use state is that the total consumption amount of the fuel gas G in the plurality of energy supply devices E (the combined heat and power supply unit 41 and the heat source unit B) constituting the device group is equal to or less than the set determination amount. This state is a state where there is once a continuous state for 60 minutes.

  When the power generation side control unit 92 of the energy supply device E1 determines that the third gas non-use state has existed until the second set stop period T2 expires, the power generation side control unit 92 determines that the start prohibition release condition is satisfied. Then, the activation prohibition of the cogeneration unit 41 of its own energy supply device E1 is canceled and the activation prohibition of the cogeneration unit 41 is instructed to the other energy supply device E2 (# 40), and the second setting is made. If it is determined that the third gas is not in use before the stop period T2 expires, the process returns to # 37.

<Third Embodiment>
The energy supply system of the third embodiment is different from the above-described embodiment in the information transmission method between the plurality of energy supply apparatuses E. Although the energy supply system of 3rd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

  FIG. 7 is a diagram illustrating a configuration of an energy supply system according to the third embodiment. As shown in the figure, in the energy supply system of the third embodiment, the server device 4 communicates with the energy supply device E provided in each of the plurality of facilities 5 (5A, 5B) via the communication line 3. Information can be sent and received. Specifically, the server device 4 exchanges information between the energy supply device E (E1, E2) provided in the facility 5A and the energy supply device E (E3, E4) provided in the facility 5B. Can send and receive. In such a case, the server device 4 needs to determine which combination of energy supply devices E is installed in the same facility 5, that is, whether the fuel gas G is supplied from the same microcomputer meter M. There is. That is, the combination of the energy supply device E1 and the energy supply device E2 is provided in the same facility 5A, and the combination of the energy supply device E3 and the energy supply device E4 is provided in the same facility 5B. Need to recognize.

  In the energy supply system according to the third embodiment, the server device 4 relates to a plurality of energy supply devices E constituting a device group to which fuel gas is supplied via the same microcomputer meter M. The unique identification information assigned to each of the information is stored in association with each other. As shown in Table 1 below, the unique identification information of the energy supply device E is, for example, the serial number of the power generation unit 40 included in each energy supply device E. The server device 4 stores information as shown in Table 1. In the example shown in Table 1, the facility 5A is assigned “A0001” as the customer ID, and the customer ID is “F100013” that is the identification information of the energy supply device E1 and the identification information of the energy supply device E2. “F100044” is associated. Further, “A0002” is assigned as a customer ID to the facility 5B, and “F100021” as identification information of the energy supply device E3 and “F100022” as identification information of the energy supply device E4 are associated with the customer ID. It has been.

  As shown in FIG. 5 of the first embodiment, if the server device 4 performs the leakage determination avoidance process, each energy supply device E has its own energy supply device E (the combined heat and power supply unit 41 and the heat source unit). The consumption amount information regarding the consumption amount of the fuel gas in B) is transmitted to the server device 4 together with the production number (identification information) of the power generation unit 40. For example, when the server apparatus 4 receives the identification information “F100013” together with the consumption information, it is the information transmitted from the energy supply apparatus E1, the information regarding the facility 5A, and the same It can be recognized that the information is associated with consumption information of the energy supply device E2 installed in the facility 5A. In this way, even if the server device 4 receives consumption information from a plurality of energy supply devices E, the server device 4 refers to the information shown in Table 1 to determine which energy supply device E has the received consumption information. It is possible to manage and store whether the information is associated with the consumption information. Then, the server apparatus 4 determines whether or not the stop execution condition of the combined heat and power supply unit 41 is satisfied and the activation prohibition release condition are satisfied based on the consumption information of the plurality of energy supply apparatuses E managed in association with each other. It can be determined whether or not it has been done.

  In addition, as shown in FIG. 6 of the second embodiment, if one energy supply device E performs the leakage determination avoidance process, the other energy supply devices E have their own energy supply devices E (cogeneration). 2nd consumption information regarding the consumption of the fuel gas in the part 41 and the heat source part B) is transmitted to the server device 4 together with the identification information. For example, when the server apparatus 4 receives the identification information “F100044” together with the consumption information, it is the information transmitted from the energy supply apparatus E2, the information regarding the facility 5A, and the same It can be recognized that the information is associated with the consumption information of the energy supply device E1 installed in the facility 5A, and that the consumption information of the energy supply device E2 should be transmitted to the energy supply device E1. In this way, the server device 4 provides the second consumption information related to the fuel gas consumption from the energy supply device E to the energy supply device E (the combined heat and power supply unit 41 and the heat source unit B) together with the second identification information. When receiving, it is possible to specify to which energy supply device E the second consumption information should be transmitted.

<Another embodiment>
<1>
In the above-described embodiment, the configuration of the energy supply system has been described with a specific example, but the configuration can be changed as appropriate.
For example, although the ultrasonic microcomputer meter M is illustrated in the above embodiment, the present invention can be applied to a film microcomputer meter M. In this case, the determination condition for determining that the fuel gas non-consumption state has occurred is, for example, a state in which the flow rate of the fuel gas G is equal to or less than the set determination amount (for example, 1.0 L / h). It is set to a condition that continues for a set determination time or longer (for example, 60 minutes or longer).
In addition, although the configuration in which the hot water storage tank 90 is provided in the power generation unit 40 is described in the above embodiment, the energy supply system in which the hot water storage tank 90 is not provided or the energy in which the hot water storage tank 90 is provided separately from the power generation unit 40 are described. The configuration of the energy supply system such as the supply system can be changed as appropriate.

<2>
In the above-described embodiment, specific numerical values are given to describe the contents of processing performed in the energy supply system. However, these numerical values are described for illustrative purposes and can be changed as appropriate.
For example, the leakage determination period, the predetermined period, the standby period, and the like have been described with specific numerical values, but these numerical values can be changed as appropriate.
In addition, the contents of the first gas non-use state, the second gas non-use state, and the third gas non-use state have been described with specific numerical values, but these numerical values can be changed as appropriate.

  In the above embodiment, the example in which the serial number is unique identification information given to the combined heat and power supply unit 41 (power generation unit 40) and the heat source unit B (heat source unit 10) has been described. It is good. For example, the product numbers and MAC addresses of the combined heat and power supply unit 41 (power generation unit 40) and the heat source unit B (heat source unit 10) may be used as identification information.

<3>
Note that the configurations disclosed in the above embodiments (including other embodiments) can be applied in combination with the configurations disclosed in the other embodiments as long as no contradiction arises. The embodiment disclosed in FIG. 1 is an exemplification, and the embodiment of the present invention is not limited thereto, and can be appropriately modified without departing from the object of the present invention.

  The present invention provides an energy supply capable of stopping and resuming the operation of the power generation unit at an appropriate timing regardless of whether or not there is another energy supply device E to which fuel gas is supplied via the same microcomputer meter M. Available to the system.

3 Communication line 4 Server device 10 Heat source unit 11 Heating unit for hot water supply (heat source unit B)
12 Heating part for heating (heat source part B)
40 Power generation unit 41 Heat and power supply unit (Power generation unit A)
92 Power generation side control part A Power generation part B Heat source part E (E1, E2, E3, E4) Energy supply device

Claims (7)

An energy supply device having a power generation unit that generates power using fuel gas supplied via a microcomputer meter, and a power generation side control unit that controls the operation of the power generation unit,
The microcomputer meter is configured such that a fuel gas non-consumption state that satisfies a predetermined determination condition including a state in which the fuel gas flow rate is equal to or less than a set determination amount continues for a set determination time or more does not occur during the leakage determination period. An energy supply system configured to alarm or shut off the fuel gas supply,
A device group comprising a plurality of the energy supply devices to which fuel gas is supplied via the same microcomputer meter,
A server device capable of transmitting / receiving information to / from the plurality of energy supply devices via a communication line;
The server device is
Receiving and storing consumption information related to the consumption of fuel gas in the plurality of energy supply devices via the communication line;
When it is determined that the power generation unit stop execution condition of the plurality of energy supply devices constituting the device group is satisfied based on the consumption information, the operation of the power generation unit is started until the start prohibition release condition is satisfied It is configured to execute a leakage determination avoidance stop process for transmitting a command to stop to a plurality of the energy supply devices constituting the device group,
A situation in which there is no predetermined gas non-use state in which a state in which the total fuel gas consumption in the plurality of energy supply devices constituting the device group is equal to or less than the set determination amount continues for the set determination time or longer. However, the energy supply system has the stop execution condition that a predetermined period shorter than the leakage determination period is continued. The server device is associated with each of the plurality of energy supply devices with respect to the plurality of energy supply devices constituting the device group to which fuel gas is supplied via the same microcomputer meter. Store the associated identification information,
The energy supply system according to claim 1, wherein the energy supply device transmits the consumption information together with the identification information to the server device.   The server device configures the device group during a predetermined waiting period after the power generation units included in the plurality of energy supply devices constituting the device group are stopped by the leakage determination avoidance stop process. The activation prohibition canceling condition is that there is a predetermined gas non-use state including a state in which a total fuel gas consumption amount in the energy supply device is equal to or less than the set determination amount continues for the set determination time or longer. The energy supply system according to claim 1 or 2. An energy supply device having a power generation unit that generates power using fuel gas supplied via a microcomputer meter, and a power generation side control unit that controls the operation of the power generation unit,
The microcomputer meter is configured such that a fuel gas non-consumption state that satisfies a predetermined determination condition including a state in which the fuel gas flow rate is equal to or less than a set determination amount continues for a set determination time or more does not occur during the leakage determination period. An energy supply system configured to alarm or shut off the fuel gas supply,
A device group comprising a plurality of the energy supply devices to which fuel gas is supplied via the same microcomputer meter,
A server device capable of transmitting / receiving information to / from the plurality of energy supply devices via a communication line;
The server device is
Consumption of the fuel gas in the other energy supply device received from the other energy supply device via the communication line among the one energy supply device and the other energy supply device constituting the device group Transmitting the second consumption information on the quantity to one energy supply device,
The power generation side control unit of one of the energy supply devices is
The device group is configured based on the first consumption amount information regarding the consumption amount of the fuel gas in the energy supply device of itself and the second consumption amount information in the other energy supply device received from the server device. If it is determined that the power generation unit stop execution condition of the plurality of energy supply devices is satisfied, the operation of the power generation unit of the energy supply device is stopped until the start prohibition release condition is satisfied, and the other energy Configured to execute a leakage determination avoidance stop process for transmitting a command to stop the operation of the power generation unit of the supply device until the start prohibition release condition is satisfied to the other energy supply device,
A situation in which there is no predetermined gas non-use state in which a state in which the total fuel gas consumption in the plurality of energy supply devices constituting the device group is equal to or less than the set determination amount continues for the set determination time or longer. However, the energy supply system has the stop execution condition that a predetermined period shorter than the leakage determination period is continued. The server device is associated with each of the plurality of energy supply devices with respect to the plurality of energy supply devices constituting the device group to which fuel gas is supplied via the same microcomputer meter. Store the associated identification information,
The energy supply system according to claim 4, wherein the other energy supply device transmits the second consumption information together with the identification information to the server device.   The power generation side control unit of one of the energy supply devices has a predetermined waiting period after the power generation units included in the plurality of energy supply devices constituting the device group stop operation by the leakage determination avoidance stop process. A predetermined gas non-use state including a state in which a total fuel gas consumption amount in the energy supply device constituting the device group is equal to or less than the set determination amount continues for the set determination time or more The energy supply system according to claim 4, wherein the activation prohibition cancellation condition is set to be present.   The said energy supply apparatus further has the heat source part which generate | occur | produces heat using the fuel gas supplied via the said microcomputer meter, and the heat source side control part which controls the driving | operation of the said heat source part. The energy supply system according to any one of the above.

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