JP6223136B2 - Cogeneration system - Google Patents

Description

  The present invention relates to a cogeneration system including a combined heat and power device that generates heat and electricity together, and a heat storage device that stores heat generated by the combined heat and power device.

  In a cogeneration system including a cogeneration device, for example, heat and electricity generated by the operation of one cogeneration device are consumed by separate heat demand units and power demand units. For this reason, if the timing for generating power demand and the timing for generating heat demand do not match, there may be cases where heat demand is not generated at the timing when the combined heat and power supply device is operated to cover the power demand. is there. Even in such a case, since the cogeneration system includes a heat storage device, the heat generated by the combined heat and power supply device can be temporarily stored in the power storage device and used when necessary. it can.

  However, if the state of a large amount of heat newly stored in the heat storage device continues, the heat storage amount in the heat storage device may reach the upper limit heat storage amount. If the cogeneration system is equipped with a radiator to release the heat stored in the heat storage device, even if the heat storage amount of the heat storage device reaches the upper limit heat storage amount, the radiator releases heat and the heat storage amount By taking a measure not to increase the temperature further, the thermoelectric generation operation of the combined heat and power supply device and the heat storage operation to the heat storage device can be continued.

When such a cogeneration system is not equipped with a radiator or the like for releasing the heat stored in the heat storage device, when the heat storage amount in the heat storage device reaches the upper limit heat storage amount, the thermoelectric generation operation of the combined heat and power supply device Must be stopped so that no further heat is stored in the heat storage device. That is, when the heat storage amount in the heat storage device reaches the upper limit heat storage amount, the supply of electricity from the combined heat and power supply device to the power demand is also stopped.
However, when there is a demand for power to be supplied from the combined heat and power supply device, it may be necessary to operate the combined supply and supply device to supply power even if heat is not required.

In Patent Document 1, when the fuel cell system is in a self-sustaining power generation state and the heat storage detector detects that the heat storage amount is equal to or greater than the first heat storage amount smaller than the fully stored state, At least one of drainage control for discharging hot water, notification for prompting use of hot water in the hot water storage tank, and data transmission for transmitting data for prompting use of hot water in the hot water storage tank to a device outside the fuel cell system It is described that control is performed.
In the system described in Patent Document 1, when performing discharge control for discharging hot water in the hot water storage tank, before executing the discharge, “to automatically drain the hot water storage tank to avoid full storage”, etc. The message is displayed on the display device.

JP 2013-109901 A

In the system described in Patent Document 1, it is possible to execute a countermeasure for informing the use of hot water in the hot water storage tank or a measure for transmitting data for prompting the use of hot water in the hot water storage tank to a device outside the fuel cell system. Although mentioned, even if such measures are taken, the hot water in the hot water storage tank is not always used. That is, the amount of heat stored in the hot water storage tank may not decrease. When a measure for discharging the hot water in the hot water storage tank is executed as in the system described in Patent Document 1, the amount of heat stored in the hot water storage tank is reduced at least by the amount of the discharged hot water.
However, in the system described in Patent Document 1, when performing the discharge control to discharge the hot water in the hot water storage tank, before executing the discharge, “In order to avoid the hot water storage tank becoming full, it will be automatically drained. Is displayed on the display device. As described above, displaying such a message on the display device every time the heat exhausting operation is performed makes the system more complicated than necessary.

  This invention is made | formed in view of said subject, The objective is to provide the cogeneration system which can perform control at the time of full storage of a thermal storage apparatus, without making a system complicated. .

In order to achieve the above object, the cogeneration system according to the present invention has the following features: a combined heat and power device that generates heat and electricity, and heat generated by the combined heat and power device using a heat storage medium. Heat stored in the heat storage device in the form of a heat storage device capable of storing heat up to an amount, a thermoelectric generation operation in which the combined heat and power supply device is operated to generate heat and electricity, and release of the heat storage medium A cogeneration system comprising an operation control means for controlling the heat release operation to be released,
From the user , when the heat storage amount in the heat storage device reaches the upper limit heat storage amount during the execution of the thermoelectric generation operation of the cogeneration device, a response to stop the thermoelectric generation operation of the cogeneration device, or An operation command receiving means for receiving a command to take any of the measures to continue execution of the thermoelectric generation operation of the cogeneration device while performing the heat release operation ,
The operation control means includes
The combined heat and power supply while performing the heat release operation when the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation of the heat and power supply device by the operation command receiving means. When the amount of heat stored in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation when the command to take a response to continue execution of the thermoelectric generation operation of the device is received, the thermoelectric generation Performing the heat release operation while continuing the operation,
When the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation of the cogeneration device from the user by the operation command receiving means, the thermoelectric generation operation of the cogeneration device is performed. When in the state of receiving a command to take a response to stop, if the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation, the thermoelectric generation is performed without executing the heat release operation. It is in the point comprised so that a driving | operation may be stopped.

According to the above-described characteristic configuration, when the operation command accepting unit previously executes the thermoelectric generation operation of the combined heat and power supply device from the user, when the heat storage amount in the heat storage device reaches the upper limit heat storage amount, the thermoelectric generation of the combined heat and power supply device occurs. The operation control means is configured to accept a command to take either a response to stop the operation or a response to continue the execution of the thermoelectric generation operation of the cogeneration device while performing the heat release operation. When the heat storage amount in the heat storage device reaches the upper limit heat storage amount during the generation operation, the operation command accepting means is used to continue the execution of the thermoelectric generation operation of the cogeneration device while performing the heat release operation from the user. the state running heat release operation while continuing the execution of a thermoelectric generator operation if the state of the command is accepted (release permission state), accepts an instruction to take corresponding to stop the thermoelectric generation operation of the cogeneration device to take (If the above release enabled) lever stops thermoelectric generator operation without performing a heat release operation. That is, even if the heat release operation for releasing the heat stored in the heat storage device is performed, it is based on the permission received from the user.
In addition, the command to take the response to continue the execution of the thermoelectric generation operation of the cogeneration device while performing the heat release operation is the one that the operation command receiving means has previously received from the user, and the heat storage is performed while the thermoelectric generation operation is being executed. It is not configured to request a command from the user every time the amount of heat stored in the apparatus reaches the upper limit amount of heat stored. Therefore, in an emergency where the heat storage amount in the heat storage device reaches the upper limit heat storage amount during the execution of the thermoelectric generation operation, the heat release operation can be performed without going through the procedure for obtaining the notification to the user and the above command. Can be done. In addition, once the user has given a command to take measures to continue the execution of the thermoelectric generation operation of the combined heat and power unit while performing the heat release operation , the amount of heat stored in the heat storage device during the execution of the thermoelectric generation operation Since the command is not requested every time the upper limit heat storage amount reaches, the operation is not complicated for the user. Furthermore, when the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation of the cogeneration device, the user responds to stop the thermoelectric generation operation of the cogeneration device, or heat release operation It is possible to freely change the command to take any one of the measures to continue the execution of the thermoelectric generation operation of the cogeneration device while performing the There is no problem as a system on the condition of whether or not it is in a release permission state.
Therefore, it is possible to provide a cogeneration system capable of performing control when the heat storage device is fully stored without complicating the system.

  Another characteristic configuration of the cogeneration system according to the present invention is such that the heat storage device is configured to store heat using hot water as the heat storage medium, and the operation control unit performs the heat release operation. It is comprised so that hot water may be adjusted and discharge | released to preset temperature, The said operation command reception means exists in the point comprised so that the said preset temperature may be received from a user.

  According to the above characteristic configuration, the user can set the temperature of the hot water discharged by the heat release operation. As a result, the hot water temperature can be adjusted to a temperature according to the conditions of the hot water discharge destination. For example, the temperature of the discharged hot water temperature is adjusted to 40 ° C. so that the burned water does not cause burns even if it is touched by humans, or resin parts that may come into contact with the discharged hot water It is possible to adjust the temperature of the discharged hot water temperature so as not to adversely affect the temperature.

  Still another characteristic configuration of the cogeneration system according to the present invention is that the heat storage device is configured to store heat using hot water as the heat storage medium, and the operation control unit performs the heat release operation. The operation command receiving means is configured to receive the set discharge amount from the user.

  According to the above characteristic configuration, the user can set the amount of hot water discharged by the heat release operation. The heat release operation releases heat energy in exchange for continuing the thermoelectric generation operation of the combined heat and power supply apparatus, and is accompanied by a deterioration in energy saving performance. However, in this feature configuration, the user can prevent the energy saving performance from deteriorating more than necessary by limiting the amount of hot water discharged by the heat release operation to the set discharge amount.

  Still another characteristic configuration of the cogeneration system according to the present invention is that the operation control means is configured to discharge hot water into the bathtub in the heat release operation.

  According to the above characteristic configuration, since the hot water is discharged into the bathtub in the heat release operation, a special hot water flow path only for performing the heat release operation is not necessary. Moreover, if the bathtub is equipped with a faucet and hot water discharged by the heat release operation is stored in the bathtub, the hot water may be used later.

  Still another characteristic configuration of the cogeneration system according to the present invention lies in that a notification unit that notifies the user of the execution of the heat release operation is provided.

  According to the above characteristic configuration, the user is in a situation where the heat release operation is executed, that is, the heat storage amount in the heat storage device reaches the upper limit heat storage amount during the execution of the thermoelectric generation operation, that is, the heat Can know that there is a surplus.

It is a figure which shows the structure of a cogeneration system. It is a figure which shows the example of a screen displayed on the display part of a remote control device. It is a flowchart explaining the control when it becomes a full storage state in the state where manual operation is performed.

The configuration of the cogeneration system of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a cogeneration system. As shown in FIG. 1, the cogeneration system includes a cogeneration device 1 that generates heat and electricity together, and a hot water storage tank 4 as a heat storage device that stores heat generated by the cogeneration device 1 using a heat storage medium. And control of heat release operation that releases heat stored in the hot water storage tank 4 in the form of thermoelectric generation operation that operates the combined heat and power supply device 1 to generate heat and electricity together and discharge of the heat storage medium. The operation control means C which performs is provided. The operation control means C also controls the operation of various pumps and valves, which will be described later, and the operation of each device provided in the cogeneration system. In the present application, “heat release operation” refers to releasing heat in the form of releasing the heat storage medium to a place where no heat demand is generated at that time.

[Description of system configuration]
The combined heat and power supply apparatus 1 may have any configuration as long as it can generate heat and electricity together. For example, a device that includes a fuel cell or an engine and a generator driven by the engine and uses exhaust heat of the engine and generated power of the generator can be used as the combined heat and power supply device 1. Although illustration is omitted, for example, an inverter or the like is provided on the power generation output side of the cogeneration apparatus 1, and the inverter sets the output power of the cogeneration apparatus 1 to the same voltage and the same frequency as the electric power supplied from the commercial power system. Is configured to do. And the electric power output from an inverter is supplied to various electric power load apparatuses.

  The combined heat and power supply device 1 and the hot water storage tank 4 are connected using an exhaust heat circulation path L8 through which water (hot water) as a heat storage medium circulates. That is, the hot water is configured to circulate between the combined heat and power supply device 1 and the hot water storage tank 4 through the exhaust heat circulation path L8. The operation control means C circulates hot water between the combined heat and power supply device 1 and the hot water storage tank 4 while operating the combined heat and power supply device 1. The hot water has a role of cooling the combined heat and power supply device 1 and a role of recovering exhaust heat from the combined heat and power supply device 1.

  Hot water is stored in the hot water storage tank 4 in a form that forms temperature stratification. A relatively low temperature hot water is stored in the lower part of the hot water storage tank 4, and a relatively high temperature hot water is stored in the upper part of the hot water storage tank 4. Inside the hot water storage tank 4, a hot water storage temperature sensor 25, a hot water storage temperature sensor 26, a hot water storage temperature sensor 27, and a hot water storage temperature sensor 28 are provided from the lower side to the upper side. Since hot water is stored in the hot water storage tank 4 in a form that forms temperature stratification, the hot water storage temperature sensor 28 provided on the uppermost side measures the temperature of the hottest hot water and is provided on the lowermost side. The hot water storage temperature sensor 25 measures the temperature of hot water at the lowest temperature side.

  The cogeneration apparatus 1 is supplied with relatively low temperature hot water taken out from the lower side of the hot water storage tank 4 through the exhaust heat circulation path L8. The relatively hot water after recovering the exhaust heat of the combined heat and power supply device 1 (that is, the hot water after being used for cooling the combined heat and power supply device 1) passes through the exhaust heat circulation path L8 and enters the hot water storage tank 4 inside. It flows upward. Thus, the relatively low temperature hot water stored in the hot water storage tank 4 is heated by the combined heat and power supply device 1 and then stored in the hot water storage tank 4 as relatively high temperature hot water. The temperature sensor 38 provided in the exhaust heat circulation path L8 detects the temperature of hot water supplied to the combined heat and power supply apparatus 1. The temperature sensor 39 provided in the exhaust heat circulation path L8 detects the temperature of the hot water after the exhaust heat is recovered by the combined heat and power supply apparatus 1. The detection results of the temperature sensor 38 and the temperature sensor 39 are transmitted to the operation control means C and stored in the storage means S.

  In the present embodiment, a hot water storage three-way valve 19 is provided in the middle of the exhaust heat circulation path L8 from the combined heat and power supply device 1 to the hot water storage tank 4. The exhaust heat circulation path L8 branches from the hot water storage three-way valve 19 to the bypass path L9. The bypass path L9 is connected to a junction part in the middle of the exhaust heat circulation path L8 from the hot water storage tank 4 to the combined heat and power supply device 1. Hot water can be circulated by bypassing the hot water storage tank 4. Specifically, when the temperature of hot water detected by the temperature sensor 39 (that is, the temperature of hot water returning from the combined heat and power supply device 1) is lower than a predetermined temperature, the operation control means C causes the hot water storage three-way valve 19 to By switching to the side flowing through the bypass path L9 instead of the tank 4 side, it is avoided that low-temperature hot water returns to the hot water storage tank 4. Then, after flowing through the bypass L9, when the temperature of the hot water supplied to the combined heat and power supply device 1 and raised in temperature becomes equal to or higher than a predetermined temperature at the detection portion of the temperature sensor 39, the hot water storage three-way valve 19 is turned on. The hot water is returned to the hot water storage tank 4. For example, when the combined heat and power supply device 1 is started, the amount of exhaust heat from the combined heat and power supply device 1 is very small, so even if hot water (that is, low-temperature hot water) is supplied from the hot water storage tank 4 to the combined heat and power supply device 1, it is supplied. Hot water having a temperature close to that of the hot water returns from the combined heat and power supply device 1. Even in such a case, the hot water is allowed to flow through the bypass L9 until the temperature of the hot water detected by the temperature sensor 39 reaches a predetermined temperature or higher.

  The hot water stored in the hot water storage tank 4 can be taken out from the hot water outlet L1 connected to the upper inside of the hot water storage tank 4. An upstream three-way valve 13, an auxiliary heat source device 5, a branch portion 42, and a downstream three-way valve 14 are provided in this order in the middle of the hot water supply passage L <b> 1. Further, a pressure switch 29 is provided between the hot water storage tank 4 and the upstream three-way valve 13 in the middle of the hot water outlet L1, and the water amount sensor 30 and the upstream side between the upstream three-way valve 13 and the auxiliary heat source device 5 are provided. A temperature sensor 31 is provided, and a downstream temperature sensor 32 is provided between the auxiliary heat source device 5 and the branch portion 42.

  The auxiliary heat source device 5 is a device that can heat hot water by consuming fuel and generating heat. For example, the auxiliary heat source device 5 can be operated in a heating operation state in which supplied gas is combusted and hot water is heated using the combustion heat or the like. The operation of the auxiliary heat source device 5 is controlled by the operation control means C.

  The pressure switch 29 has a function of detecting the water pressure inside the hot water outlet L1. For example, if the hot water pressure at the part where the pressure switch 29 is provided is equal to or higher than a set value, the pressure switch 29 outputs an ON state. On the other hand, when the hot water pressure at the portion where the pressure switch 29 is provided becomes less than the set value, the pressure switch 29 outputs an OFF state. The detection result of the pressure switch 29 is transmitted to the operation control means C and stored in the storage means S.

The water amount sensor 30 measures the flow rate of the hot water flowing through the hot water supply passage L1 downstream of the upstream side three-way valve 13. The detection result of the water amount sensor 30 is transmitted to the operation control means C and stored in the storage means S.
The upstream temperature sensor 31 measures the temperature of hot water before flowing into the auxiliary heat source device 5. That is, when the auxiliary heat source device 5 is in the heating operation state, the upstream temperature sensor 31 measures the temperature of the hot water before being heated by the auxiliary heat source device 5.
The downstream temperature sensor 32 measures the temperature of the hot water after flowing out from the auxiliary heat source device 5. That is, when the auxiliary heat source device 5 is in the heating operation state, the downstream temperature sensor 32 measures the temperature of the hot water after being heated by the auxiliary heat source device 5.

  The hot water supply passage L1 branches off the hot water supply passage L5 at the branching portion 42 downstream of the auxiliary heat source device 5, and the hot water circulation passage L3 and the bath circulation passage L4 at the downstream three-way valve 14 downstream of the branching portion 42. Can be divided.

  The hot water circulation path L3 returns to the downstream three-way valve 14 via the downstream three-way valve 14, the heating heat exchanger 7, the junction 46, the circulation pump 20, the upstream three-way valve 13, and the auxiliary heat source device 5. Follow the path. When hot water is circulating in the hot water circulation path L3 and the auxiliary heat source device 5 is in the heating operation state, the heating heat exchanger 7 is supplied with hot water heated by the auxiliary heat source device 5. .

  The heating circulation path L7 is a path through which the heating heat medium circulates in order through the heating pump 22, the heating heat exchanger 7, and the heating device 2. A heating water tank 8 in which a heating heat medium is temporarily stored is also provided in the middle of the heating circuit L7. In the present embodiment, the heating medium is water (hot water).

  In the heat exchanger 7 for heating, heat exchange is performed between hot water flowing through the hot water circulation path L3 and a heating heat medium flowing through the heating circulation path L7. When the auxiliary heat source device 5 is in the heating operation state, the hot water flowing through the hot water circulation path L3 is heated by the auxiliary heat source device 5 and then flows into the heating heat exchanger 7. And in the heat exchanger 7 for heating, the heat which the hot water after heating by the auxiliary heat source apparatus 5 is transmitted to the heating medium which flows through the circulation path for heating is transmitted. Then, the heating medium after being heated in the heating heat exchanger 7 is supplied to the heating device 2 through the heating circuit L7. The heating medium after heat consumption in the heating device 2 flows into the heating heat exchanger 7 through the heating circuit L7 and is heated.

  In the middle of the heating circuit L 7, a temperature sensor 40 is provided between the heating heat exchanger 7 and the heating device 2, and a temperature sensor 41 is provided between the heating device 2 and the heating water tank 8. The temperature sensor 40 measures the temperature of the heating medium that flows into the heating device 2, and the temperature sensor 41 measures the temperature of the heating medium that flows out of the heating device 2. The detection results of the temperature sensor 40 and the temperature sensor 41 are transmitted to the operation control means C and stored in the storage means S.

  The bath circulation path L4 is connected to the downstream three-way valve 14, the bath heat exchanger 6, the junction 50, the junction 46, the circulation pump 20, the upstream three-way valve 13, and the auxiliary heat source device 5. Follow the path back to the valve 14. When hot water is circulating in the bath circuit L4 and the auxiliary heat source device 5 is in the heating operation state, the hot water after being heated by the auxiliary heat source device 5 is supplied to the bath heat exchanger 6. .

  The bathtub water circulation path L6 is a path through which hot water circulates between the bath pump 21 and the bathtub 3 in order. When the faucet of the bathtub 3 is opened, hot water is discharged from the faucet, so that hot water does not return from the bathtub 3 to the bath heat exchanger 6.

  In the bath heat exchanger 6, heat exchange between hot water flowing through the bath circulation path L4 and hot water flowing through the bathtub water circulation path L6 is performed. When the auxiliary heat source device 5 is in the heating operation state, the hot water flowing through the bath circuit L4 is heated by the auxiliary heat source device 5 and then flows into the bath heat exchanger 6. And in the heat exchanger 6 for baths, the heat which the hot water after having been heated by the auxiliary heat source device 5 is transmitted to the hot water flowing through the bathtub water circulation path L6. And the hot water after temperature rising in the heat exchanger 6 for baths is supplied to the bathtub 3 through the bathtub water circulation path L6.

  A bath water level sensor 35, a bath temperature sensor 36, and a bath water flow switch 37 are provided between the bathtub 3 and the junction 45 in the middle of the bath water circulation path L6. The bath water level sensor 35 measures the water level of hot water stored in the bathtub 3. The bath temperature sensor 36 measures the temperature of hot water stored in the bathtub 3. The detection results of the bath water level sensor 35 and the bath temperature sensor 36 are transmitted to the operation control means C and stored in the storage means S.

  The bath water flow switch 37 has a function of detecting the circulation of the bathtub water circulation path L6. For example, when the bath pump 21 is operated when a certain amount of hot water is stored in the bathtub 3, hot water circulates in the bathtub water circulation path L6, and the bath water flow switch 37 outputs an ON state. On the other hand, when a certain amount of hot water is not stored in the bathtub 3, since the hot water does not circulate in the bathtub water circulation path L6 even when the bath pump 21 is operated, the bath water flow switch 37 outputs an OFF state. The detection result of the bath water flow switch 37 is transmitted to the operation control means C and stored in the storage means S. Moreover, the operation control means C stops the bath pump 21 after confirming the output result of the on-state or the off-state by the bath water flow switch 37.

  A hot water supply path L5 is connected to a junction 45 provided in the middle of the bathtub water circulation path L6. The hot water supply passage L5 is connected to a branching portion 42 that branches from the downstream side of the auxiliary heat source device 5 in the middle of the hot water supply passage L1. That is, the hot water flowing through the hot water supply path L5 is hot water discharged from the upper side of the hot water storage tank 4 or hot water discharged from the upper side of the hot water storage tank 4 and further heated by the auxiliary heat source device 5. . The hot water supply passage L1 branches at the branching portion 44 into a hot water supply passage L5a connected to the currant or the like and a hot water supply passage L5b connected to the bathtub 3 (tub water circulation passage L6). In the middle of the hot water supply path L5b, a hot water valve 17 and a water amount sensor 34 are provided. The detection result of the water amount sensor is transmitted to the operation control means C and stored in the storage means S. The operation of the hot water valve 17 is controlled by the operation control means C. When the operation control means C newly supplies hot water from the hot water supply passage L5 to the bath water circulation passage L6, the total flow rate of hot water detected by the water amount sensor 34 is a desired total flow rate (for example, one time as described later). The hot water filling valve 17 is opened so as to be 20 L (liter) released in the heat release operation.

  The hot water stored in the hot water storage tank 4 is replenished via the water supply channel L2. The water supply channel L2 is connected to a water supply source such as clean water. The water supply path L2 includes a water supply path L2a connected to the hot water storage tank 4, a water supply path L2b connected to the heating water tank 8, a water supply path L2c connected to the hot water supply path L5, and a water supply connected to the bath circulation path L4. Branch to Road L2d.

  The water pressure is constantly applied to the water supply channel L2a, and the water pressure is also applied to the hot water storage tank 4 to which the water supply channel L2a is connected. Therefore, the water supply pressure is also applied in each water channel connected to the hot water storage tank 4, and hot water is pushed out by the water supply pressure when the tip of each water channel is opened.

  When the water supply from the water supply source to the water supply channel L2 is shut off, for example, hot water flows from the hot water storage tank 4 to the bathtub 3 through the hot water supply channel L1, the hot water supply channel L5, and the bathtub water circulation channel L6. Then, the water pressure in the hot water storage tank 4, the hot water outlet L1, etc. remains lowered due to the loss of the water supply pressure due to the water cut. And when the water pressure in the hot water path L1 falls below the set value, the pressure switch 29 provided in the middle of the hot water path L1 detects the OFF state.

  The water supply channel L <b> 2 b branches from a branching portion 47 provided in the middle of the water supply channel L <b> 2 and reaches the heating water tank 8. A supply water closing valve 11 and a heating supply water valve 18 are provided in the middle of the water supply path L2b. The supply water closing valve 11 is always open, and the operation of the heating supply water valve 18 is controlled by the operation control means C. For example, when the water level of the heating water tank 8 is lowered, the operation control means C opens the heating replenishing water valve 18 so as to raise the water level, and causes water to flow into the heating water tank 8.

  The water supply path L2c branches from the branch part 48 provided in the middle of the water supply path L2, and reaches the junction part 43 with the hot water supply path L5. A water proportional valve 16 is provided in the middle of the water supply path L2c. A hot water proportional valve 15 is provided in the hot water supply path L5 upstream of the junction 43. A hot water supply temperature sensor 33 that measures the temperature of flowing hot water is provided in the hot water supply passage L5 on the downstream side of the junction 43. The detection result of the hot water supply temperature sensor 33 is transmitted to the operation control means C and stored in the storage means S. Operation of the water proportional valve 16 and the hot water proportional valve 15 is controlled by the operation control means C. The operation control means C controls the flow rate of the relatively hot water supplied from the hot water supply path L5 to the junction 43 so that the temperature of the hot water detected by the hot water temperature sensor 33 becomes a desired temperature. 15, and the flow rate of the relatively low temperature clean water supplied from the water supply channel to the junction is controlled by the water proportional valve 16.

  The water supply path L2d branches from the branch part 49 provided in the middle of the water supply path L2, and reaches the junction part 50 provided in the middle of the bath circulation path L4. A circulation proportional valve 12 is provided in the middle of the water supply channel L2d. The operation control means C controls the circulation proportional valve 12 to be open when the hot water heated by the auxiliary heat source device 5 is stored in the hot water storage tank 4, and closes the circulation proportional valve 12 otherwise. To control. Specifically, the operation control means C operates the auxiliary heat source device 5 while operating the circulation pump 20 and operates the circulation proportional valve 12 when the hot water heated by the auxiliary heat source device 5 is stored in the hot water storage tank 4. Is controlled in an open state, and hot water is supplied to two paths, that is, a hot water circulation path L3 (circulation pump 20 → upstream three-way valve 13 → auxiliary heat source device 5 → downstream three-way valve 14 → merging section 46 → circulation pump 20). In addition, a state is created in which hot water flows in another path (circulation pump 20 → upstream three-way valve 13 → hot water storage tank 4 → branch portion 49 → circulation proportional valve 12 → merging portion 50 → circulation pump 20). Here, the hot water heated by the auxiliary heat source device 5 is mixed with the hot water after passing through the circulation pump 20, and the hot water after passing through the circulation pump 20 is stored in the upstream three-way valve 13. Since it is distributed to the tank 4 side and the auxiliary heat source device 5 side, hot water heated by the auxiliary heat source device 5 is stored in the hot water storage tank 4 as a result.

  A water supply temperature sensor 23 and a water supply water amount sensor 24 are provided between the branch portion 47 and the branch portion 48 provided in the middle of the water supply path L2. The detection results of the feed water temperature sensor 23 and the feed water amount sensor 24 are transmitted to the operation control means C and stored in the storage means S.

  In the cogeneration system of the present embodiment, the operation control means C operates a thermoelectric generation operation in which the combined heat and power supply device 1 is operated to generate heat and electricity, and heat that releases heat stored in the hot water storage tank 4. Control the discharge operation. In the present embodiment, hot water stored in the hot water storage tank 4 is discharged to the outside of the hot water storage tank 4, thereby performing a heat release operation for releasing the heat stored in the hot water storage tank 4. The “heat release operation” of the present invention is an operation that is urgently performed for the first purpose to reduce the amount of heat stored in the hot water storage tank 4, and heat is supplied to somewhere (that is, from the hot water storage tank 4. The purpose is not to use the hot water released. In addition, it does not deny that the heat released to the outside of the hot water storage tank 4 is used by performing the heat release operation.

  The operation control means C can be realized by using an arithmetic processing device capable of performing various information processing, for example, via a remote control device R provided in a kitchen, bathroom, dressing room, etc. in the home and a communication line (not shown). Connected. The remote control device R includes a display unit r1 that displays information, an information input unit r2 that receives input of command information from a user, and a voice output unit r3 that outputs information by voice messages, ringing sounds, and the like. The display unit r1 can be realized by using a device (for example, a liquid crystal display device) that can display character information and the like. The information input unit r2 can be realized using an operation button or the like, or can be realized using an image button displayed on the touch panel type display unit r1. The storage means S can be realized using a semiconductor memory or the like, and stores information handled by the cogeneration system. Note that the storage unit S may be any case provided separately from the operation control unit C or the remote control device R, or may be incorporated in the operation control unit C or the remote control device R.

[Operation at full storage]
Hereinafter, the operation of the cogeneration system when the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount during execution of the thermoelectric generation operation will be described. In the following description, the state where the heat storage amount in the hot water storage tank 4 has reached the upper limit heat storage amount may be expressed by the term “full storage”. Moreover, although mentioned later for details, "the state which reached the upper limit heat storage amount (full storage state)" is the temperature of the coldest hot water stored in the hot water storage tank 4 in the form which forms temperature stratification. When the hot water storage temperature sensor 25 for measuring the temperature reaches the upper limit hot water temperature required for hot water when used for heat recovery from the combined heat and power supply device 1 (that is, cooling water for the combined heat and power supply device 1), that is, a hot water storage tank 4 indicates a state in which the temperature of all the hot water stored in 4 has reached the upper limit hot water temperature.

  In the cogeneration system of the present embodiment, the combined heat and power supply device 1 can be operated either automatically or manually. The operation control means C automatically operates the cogeneration apparatus 1 when an automatic operation is instructed by the remote controller R from the user. For example, in the automatic operation, the cogeneration apparatus 1 is automatically operated based on the predicted power load and the predicted heat load predicted from the past power load and heat load. On the other hand, when the manual operation is instructed from the user by the remote control device R, the operation control means C is used according to the operation start command and the operation stop command received by the remote control device R or used by the remote control device R. The cogeneration apparatus 1 is operated in the operation time zone received from the person.

FIG. 2 is a diagram illustrating an example of a screen displayed on the display unit r1 of the remote control device R.
FIG. 2A is an example of a screen when the user instructs which of the above-described “automatic operation” and “manual operation” to operate the cogeneration apparatus 1. The operation control means C causes the display unit r1 of the remote control device R to display a screen as shown in FIG. FIG. 2A shows a state in which an arrow (“⇒”) corresponds to “manual operation”, and indicates that the user has commanded “manual operation”. When the user desires “automatic driving”, the information input unit r2 may be used to make the arrow correspond to “automatic driving”.
As described above, the “driving command receiving means for receiving a driving command from a user” according to the present invention can be realized using the information input unit r2.

  When the cogeneration apparatus 1 is operated in the automatic operation and the manual operation, the operation control means C performs a thermoelectric generation operation in which the cogeneration apparatus 1 is operated to generate heat and electricity together. The heat recovery operation for recovering the water to the hot water storage tank 4 is also performed. As a result, when the thermoelectric generation operation of the combined heat and power supply apparatus 1 is performed, the hot water storage tank 4 always stores heat. Therefore, when the amount of heat newly stored in the hot water storage tank 4 exceeds the heat demand in the hot water supply application (including the hot water supply application in the bathtub 3), the heat storage amount in the hot water storage tank 4 increases.

  And the amount of heat storage in the hot water storage tank 4 may reach the upper limit heat storage amount (that is, a full storage state). For example, the operation control means C is required for hot water when the hot water storage temperature sensor 25 that measures the temperature of the coldest hot water stored in the hot water storage tank 4 is used for heat recovery from the combined heat and power supply device 1. When the upper limit hot water temperature is reached, that is, when the temperature of all hot water stored in the hot water storage tank 4 reaches the upper limit hot water temperature, the heat storage amount in the hot water storage tank 4 has reached the upper limit heat storage amount. judge.

  In other words, since the hot water in the hot water storage tank 4 is used for heat recovery from the combined heat and power supply device 1, that is, used to cool the combined heat and power supply device 1, hot water having a temperature higher than the upper limit hot water temperature is used. 1 can not be supplied. That is, the upper limit hot water temperature corresponds to the upper limit temperature allowed as cooling water for the combined heat and power supply device 1. Therefore, when the hot water storage temperature sensor 25 that measures the temperature of hot water existing near the hot water supplied to the combined heat and power supply apparatus 1 detects the upper limit hot water temperature, the operation control means C stores the amount of heat stored in the hot water storage tank 4. Is determined to have reached the upper limit heat storage amount. That is, in this embodiment, the upper limit amount of heat storage is not necessarily defined by a constant heat storage amount threshold in the hot water storage tank 4 but is defined by the temperature of a specific location of the hot water storage tank 4 or the like. Therefore, not only when judging based only on the temperature detected by the hot water storage temperature sensor 25 of the hot water storage tank 4 as described above, whether the temperature of the hot water storage temperature sensor 26 at the upper part has reached the upper limit hot water temperature, Even if it is determined whether or not the heat storage amount in the hot water storage tank 4 has reached the upper limit heat storage amount based on whether or not the detected temperatures of both the hot water storage temperature sensor 25 and the hot water storage temperature sensor 26 have reached the upper limit hot water temperature. Good.

  In the present embodiment, the operation control means C responds to stopping the thermoelectric generation operation of the combined heat and power supply device 1 when the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount, or the heat stored in the hot water storage tank 4. It is configured to take any one of the measures of continuing the execution of the thermoelectric generation operation of the combined heat and power supply device 1 while releasing the heat to the outside. And what kind of response | compatibility the driving | running control means C takes is comprised so that a user may preset using the remote control apparatus R. FIG.

FIG. 2B shows that when the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount, the thermoelectric generation operation of the combined heat and power supply device 1 is stopped, or the heat stored in the hot water storage tank 4 is released to the outside. It is an example of a screen when the user instructs in advance using the remote control device R whether to take any of the measures of continuing the execution of the thermoelectric generation operation of the combined heat and power supply device 1. Specifically, in FIG. 2 (b), the user is asked the question “What will you do when fully charged?”, In addition, the response “Stop power generation” and “ By displaying the response “continuous operation”, the user can stop the thermoelectric generation operation of the combined heat and power supply device 1 or can release the heat stored in the hot water storage tank 4 to the outside. It is going to accept an instruction as to which of the responses to continue execution of the thermoelectric generation operation is desired. FIG. 2B shows a state in which an arrow: “⇒” corresponds to “continuous operation by discharging hot water”, and the user releases the heat stored in the hot water storage tank 4 to the outside while releasing the heat. It is shown that the response | compatibility which continues execution of the thermoelectric generation driving | operation of the co-feeder 1 was instruct | indicated.
The state in which the “continuous operation by discharging hot water” is set by the user is assumed to be the state in which the “release permitted state” is set in the present embodiment.

  In the present embodiment, when the response “stop power generation” is taken, the operation control means C stops the thermoelectric generation operation of the cogeneration apparatus 1, and accordingly, the exhaust heat of the cogeneration apparatus 1 is transferred to the hot water storage tank 4. Also stop collecting. As a result, an increase in the amount of heat stored in the hot water storage tank 4 is suppressed.

  On the other hand, when the response “continuous operation by discharging hot water” is taken, the operation control means C executes the heat release operation while continuing the execution of the thermoelectric generation operation of the cogeneration apparatus 1. In the heat release operation, the operation control means C reduces the amount of heat stored inside the hot water storage tank 4 by releasing hot water stored in the hot water storage tank 4 to the outside. For example, the operation control means C performs a heat release operation in which the hot water proportional valve 15 and the hot water valve 17 provided in the hot water supply path L5 are opened to discharge the hot water stored in the hot water storage tank 4 to the bathtub 3. It can be carried out.

  Further, in this embodiment, hot water as a heat storage medium is stored in the hot water storage tank 4 to store heat in the hot water storage tank 4, and hot water is discharged from the hot water storage tank 4 to release heat from the hot water storage tank 4 (that is, The heat release operation is performed). And the user can set the accumulated amount of hot water and the temperature of hot water that are allowed to be released when performing the heat release operation. For example, in this embodiment, 20 L (liter) of hot water is released in one heat release operation. However, even if the amount of heat stored in the hot water storage tank 4 once becomes less than the upper limit heat storage amount due to the heat release operation, the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount and then releases heat again. Driving may be performed. For example, when the heat release operation for releasing 20 L of hot water is repeated many times, the cumulative amount of hot water released by these multiple heat release operations may become very large. Therefore, in the present embodiment, it is possible to set an upper limit value for the cumulative amount of hot water discharged by the heat release operation and prevent the heat release operation exceeding the upper limit value of the cumulative hot water amount from being performed. FIG. 2C and FIG. 2D are examples of these setting screens.

  Specifically, in FIG. 2 (c), the user is asked the question "What is the upper limit of the accumulated hot water amount to be released?" An instruction to accept a response to set the upper limit 100 L (liters) for the accumulated hot water to be performed or a response to set the upper limit 200 L for the accumulated hot water to be discharged is received. FIG. 2C shows a state in which an arrow: “⇒” corresponds to “upper limit 100 L”, indicating that the user has issued a command to set the accumulated hot water amount to be released to “upper limit 100 L”. Has been. The accumulated hot water amount can be appropriately set and changed, for example, a value accumulated in conjunction with the operation state of the combined heat and power supply device 1 or a value accumulated within a predetermined period. When the accumulated hot water volume is a value that is integrated in conjunction with the operating state of the combined heat and power supply device 1, for example, the combined heat and power supply device 1 starts to generate electricity, starts to integrate, and is reset to zero when generation is stopped. it can. Alternatively, when the accumulated hot water amount is a value accumulated within a predetermined period, for example, the accumulation is started from 0:00, and is reset to zero at 0:00, 24 hours later, and the accumulation is started again. Can be set.

  Further, in FIG. 2D, a question “What is the temperature of the hot water to be released?” Is displayed to the user, and in addition, the temperature of the hot water to be released is set to “unlimited”, and the temperature of the hot water to be released. Is set to “40 ° C. or lower”, and a response to set the temperature of the discharged hot water to “42 ° C. or lower” is to be received. In FIG. 2 (d), the state corresponding to the arrow: “⇒” is shown for “40 ° C. or lower”, and the user issues a command to set the temperature of the discharged hot water to “40 ° C. or lower”. It has been shown.

  For example, when the temperature of the water supplied from the water supply path L2 to the hot water storage tank 4 is 15 ° C., the 15 ° C. water is transferred from the hot water storage tank 4 to the combined heat and power supply device 1 for exhaust heat recovery in the combined heat and power supply device 1. The hot water of about 56 ° C. returns from the combined heat and power supply device 1 to the hot water storage tank 4. As a result, when the temperature of the hot water to be discharged is set to “unlimited”, the hot water of about 56 ° C. stored in the hot water storage tank 4 is discharged. When the temperature of the discharged hot water is set to “40 ° C. or less” and when the temperature of the discharged hot water is set to “42 ° C. or less”, as will be described later, this about 56 stored in the hot water storage tank 4 Heat is released after water is mixed with hot water at 0 ° C. to adjust the temperature. Since the amount of hot water released in one heat release operation (for example, 20 L described above) is the amount of hot water after the final temperature adjustment, even if the same “20 L” is released, When 20 L of 56 ° C. hot water is discharged from the hot water storage tank 4 as it is, and when 20 L of hot water is discharged after adjusting the temperature by adding water to the 56 ° C. hot water, it actually decreases from the hot water storage tank 4. The amount of heat is different. In other words, when 20 L of 56 ° C hot water is discharged from the hot water storage tank 4 as it is, it is actually reduced from the hot water storage tank 4 than when 20 L is discharged after mixing water from other places with hot water of about 56 ° C in the hot water storage tank 4. The amount of heat to be increased.

FIG. 3 is a flowchart for explaining the control when the full storage state is reached.
In the present embodiment, a description will be given of the control when the combined heat and power supply device 1 is in a manual operation and becomes full.
In the present embodiment, when the operation control means C enters the fully-accumulated state when the combined heat and power supply device 1 is automatically operated, the thermoelectric power generation device C regardless of whether or not the above-mentioned “release permitted state” is set. The thermoelectric generation operation of the co-feeder 1 is stopped and the heat release operation is not executed. That is, in the present embodiment, the heat release operation is not performed while the cogeneration apparatus 1 is automatically operated.

  In step # 10, the operation control means C determines whether or not it is in a fully charged state. In this embodiment, the operation control means C is used when the hot water storage temperature sensor 25 that measures the temperature of the coldest hot water stored in the hot water storage tank 4 is used for heat recovery from the combined heat and power supply device 1. When the upper limit hot water temperature required for hot water is reached, that is, when the temperature of all hot water stored in the hot water storage tank 4 reaches the upper limit hot water temperature, the amount of heat stored in the hot water storage tank 4 becomes the upper limit heat storage amount. It is determined that the “full state” has been reached. And operation control means C will transfer to process # 12, when it determines with it being in a full state in process # 10 (when the judgment result of process # 10 of Drawing 3 is "Yes"). On the other hand, when the operation control means C determines in step # 10 that the battery is not fully charged (when the determination result in step # 10 in FIG. 3 is “No”), the operation control means C returns to the beginning of this flowchart. To do.

  In step # 12, the operation control means C determines whether or not it is in a release permission state. Specifically, the operation control means C refers to the information stored in the storage means S, and as shown in FIG. 2 (b), the user releases the hot water in the hot water storage tank 4 while discharging the hot water. It is determined whether or not the cooperating device 1 is allowed to operate continuously (that is, whether or not the “release permitted state” is set). And operation control means C will transfer to process # 14, when it judges with it being in a discharge permission state in process # 12.

  On the other hand, if it is determined that the release permission state is not set in step # 12, the operation control means C moves to step # 16 and stops the heat release operation (that is, shifts from being executed to being stopped). Alternatively, the thermoelectric generation operation of the cogeneration apparatus 1 is shifted to the stop state. As a result, hot water is not released from the hot water storage tank 4, and the exhaust heat of the combined heat and power supply device 1 can be restricted from being stored in the hot water storage tank 4 beyond the upper limit heat storage amount.

  In step # 14, the operation control means C performs the heat release operation and continues the thermoelectric generation operation of the cogeneration apparatus 1. When performing the heat release operation, the operation control means C adjusts the temperature of the discharged hot water to the set temperature of the hot water set when performing the discharge operation, as shown in FIG. For example, 20 L of hot water at that temperature is discharged. Specifically, the operation control means C opens the hot water valve 17 and is proportional to the hot water so that the temperature of the hot water detected by the hot water temperature sensor 33 provided in the hot water supply passage L5 becomes the set hot water temperature. The opening degree of the valve 15 and the water proportional valve 16 is adjusted. Based on the detection result of the water amount sensor 34 provided in the middle of the hot water supply path L5b, the operation control means C confirms that the amount of hot water released has reached, for example, 20 L which is discharged by one heat release operation. I can know. Further, the operation control means C stores the accumulated amount of hot water released in the past heat release operation in the storage means S.

  The operation control means C may notify the user of the execution of the heat release operation when performing this heat release operation. For example, the operation control means C displays the execution of the heat release operation as character information using the display unit r1 of the remote control device R, or outputs a voice message or ringing sound using the audio output unit r3. Can be notified. In this case, the display unit r1 and the audio output unit r3 of the remote control device R function as the “notification unit” of the present invention.

  In addition, the operation control means C refers to the information on the accumulated hot water amount released in the past heat release operation stored in the storage means S, and the accumulated hot water amount is the heat as shown in FIG. The upper limit value of the accumulated hot water amount set when performing the discharge operation (the “upper limit 100L” and “upper limit 200L” illustrated in FIG. 2 (c), hereinafter, simply “100L”, “200L”, etc. (Describe) is reached. When the accumulated hot water amount that has been released has reached the set upper limit value, the operation control means C restricts the discharge of hot water beyond that (that is, stops the heat release operation), and thereafter the upper limit heat storage amount. Is reached, the thermoelectric generation operation of the cogeneration apparatus 1 is stopped.

  As described above, the present invention is configured to accept in advance permission for performing the heat release operation from the user, and the operation control means C has an upper limit on the amount of heat stored in the hot water storage tank 4 during the thermoelectric generation operation. When the amount of stored heat has been reached, if the release permission state has received permission to perform the heat release operation from the user, the heat release operation is executed while continuing the execution of the thermoelectric generation operation. The thermoelectric generation operation of the cogeneration apparatus 1 is stopped without executing the heat release operation. That is, even if the heat release operation for releasing the heat stored in the hot water storage tank 4 is performed, it is based on the permission received from the user.

  In addition, the release permission state is received from the user in advance, and whenever the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount during the execution of the thermoelectric generation operation of the combined heat and power supply device 1, It is not configured to request permission. Therefore, in an emergency where the heat storage amount in the hot water storage tank 4 has reached the upper limit heat storage amount during execution of the thermoelectric generation operation of the combined heat and power supply apparatus 1, it is not necessary to go through a procedure for obtaining notification and permission to the user. However, the heat release operation can be performed. In addition, once the user has given permission to perform the heat release operation, every time the amount of heat stored in the hot water storage tank 4 reaches the upper limit heat storage amount during execution of the thermoelectric generation operation of the cogeneration apparatus 1. Since permission is not required, the operation is not complicated for the user. Furthermore, since the user can freely change whether or not to permit the heat release operation using the remote control device R, the user's intention confirmation (that is, whether or not the release is permitted). ) There is no problem as a system. Therefore, it is possible to provide a cogeneration system that can perform control when the hot water storage tank 4 is fully stored without complicating the system.

<Another embodiment>
<1>
Although the said embodiment demonstrated the example which discharge | releases the hot water stored in the hot water storage tank 4 in the bathtub 3 in the heat discharge | release operation, you may discharge | release hot water to places other than the bathtub 3. FIG. For example, hot water may be discharged into sewage.
Moreover, in this embodiment, although the example using hot water as a thermal storage medium was demonstrated, if a thermal storage medium is discharge | released to places other than the bathtub 3 in heat release operation, the liquid different from hot water will be used as a thermal storage medium. Also good.

<2>
In the above-described embodiment, the example in which the heat release operation is not performed while the cogeneration apparatus 1 is automatically operated is described. However, the heat release operation is also performed while the cogeneration apparatus 1 is automatically operated. Also good. That is, as in the case of the manual operation described in the above embodiment, is the above-described “release permitted state” set even when the combined heat and power supply device 1 is automatically operated and the full storage state is reached? Whether to perform the heat release operation while continuing the execution of the thermoelectric generation operation of the combined heat and power supply device 1 according to whether or not to stop the thermoelectric generation operation of the combined heat and power supply device 1 without executing the heat release operation. , May be switched.

<3>
In the above embodiment, an example has been described in which the user can set the accumulated hot water amount (100 L, 200 L) and hot water temperature (40 ° C., 42 ° C.) to be released when performing the heat release operation. You may enable it to set. For example, in the above-described embodiment, the example in which the operation control unit C notifies the user of the execution of the heat release operation when performing the heat release operation has been described. However, the user determines whether to perform such notification. May be configured to be settable.

<4>
In the said embodiment, although the specific value about the temperature of hot water, the amount of hot water discharged | emitted in one heat | fever discharge | release operation (20L), the upper limit (100L, 200L) of integrated hot water amount, etc. were mentioned, those numerical values are mentioned. They are listed for illustrative purposes only, and the present invention is not limited to these values. For example, in the above-described embodiment, an example in which the amount of hot water discharged in one heat release operation is 20 L has been described, but this value may be changed to a value such as 10 L or 30 L.
Alternatively, the amount of hot water discharged in one heat release operation may be a variable value instead of the fixed value as described above. For example, as the heat release operation, the hot water storage tank 4 may be changed to release a certain amount of hot water, or the hot water storage tank 4 may be changed to release hot water until the heat storage amount in the hot water storage tank 4 is less than the upper limit heat storage amount. May be. In these cases, the amount of hot water to be released in the heat release operation becomes a variable value according to the temperature of the hot water to be released.

<5>
In the said embodiment, the cogeneration system may be equipped with heat release means other than discharging hot water (heat storage medium). For example, heat discharge means such as an air-cooled radiator may be provided in the exhaust heat circulation path L8 while heading from the hot water storage tank 4 to the combined heat and power supply device 1. The operation control means C cools the hot water by releasing a small amount of heat using an air-cooled radiator at a stage before the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount, for example, during execution of the thermoelectric generation operation. Also good. And, for example, there is an increase in the outside air temperature or an increase in the amount of exhaust heat from the combined heat and power supply device 1, so that the heat and power generation operation of the combined heat and power supply device 1 is being performed even though heat release by the air-cooled radiator is continued. When the heat storage amount in the hot water storage tank 4 reaches the upper limit heat storage amount, the operation control means C is configured to perform the heat release operation in the form of hot water (heat storage medium) discharge described in the above embodiment. May be. In this case, when the temperature of the hot water after being cooled by the air-cooled radiator reaches a predetermined upper limit temperature, it is determined that the heat storage amount in the hot water storage tank 4 has reached the upper limit heat storage amount.

  INDUSTRIAL APPLICABILITY The present invention can be used for a cogeneration system that can perform control when the heat storage device is fully stored without complicating the system.

1 Combined heat and power supply device 3 Bathtub 4 Hot water storage tank (heat storage device)
C operation control means r1 display part r2 information input part (operation command receiving means)
r3 audio output unit (notification means)

Claims (5)

A combined heat and power device that generates heat and electricity, a heat storage device that can store heat generated in the combined heat and power device up to an upper limit heat storage amount using a heat storage medium, and a heat storage device that operates the combined heat and power device A cogeneration system comprising a thermoelectric generation operation for generating electricity together with an operation control means for controlling a heat release operation for releasing heat stored in the heat storage device in the form of discharge of the heat storage medium. There,
From the user , when the heat storage amount in the heat storage device reaches the upper limit heat storage amount during the execution of the thermoelectric generation operation of the cogeneration device, a response to stop the thermoelectric generation operation of the cogeneration device, or An operation command receiving means for receiving a command to take any of the measures to continue execution of the thermoelectric generation operation of the cogeneration device while performing the heat release operation ,
The operation control means includes
The combined heat and power supply while performing the heat release operation when the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation of the heat and power supply device by the operation command receiving means. When the amount of heat stored in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation when the command to take a response to continue execution of the thermoelectric generation operation of the device is received, the thermoelectric generation Performing the heat release operation while continuing the operation,
When the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation of the cogeneration device from the user by the operation command receiving means, the thermoelectric generation operation of the cogeneration device is performed. When in the state of receiving a command to take a response to stop, if the heat storage amount in the heat storage device reaches the upper limit heat storage amount during execution of the thermoelectric generation operation, the thermoelectric generation is performed without executing the heat release operation. A cogeneration system that is configured to stop operation. The heat storage device is configured to store heat using hot water as the heat storage medium,
The operation control means is configured to adjust and discharge hot water to a set temperature when performing the heat release operation,
The cogeneration system according to claim 1, wherein the operation command receiving unit is configured to receive the set temperature from a user. The heat storage device is configured to store heat using hot water as the heat storage medium,
The operation control means is configured to release hot water by a set discharge amount when executing the heat release operation,
The cogeneration system according to claim 1 or 2, wherein the operation command receiving means is configured to receive the set release amount from a user.   The cogeneration system according to claim 2 or 3, wherein the operation control means is configured to discharge hot water into the bathtub in the heat release operation.   The cogeneration system as described in any one of Claims 1-4 provided with the alerting | reporting means which alert | reports execution of the said heat release driving | operation to a user.

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