JP2013029288A - Cogeneration system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cogeneration system that reliably prevents the failure due to an increase in a flow rate of a heat recovery circuit such as the disorder of temperature stratification in a storage tank and, at the same time, can perform a freeze proofing operation.SOLUTION: The cogeneration system includes: a power generation part which incorporates fuel cell therein and generates electric energy and heat energy at the same time; a storage tank which stores hot water therein; and a heat recovery circuit which includes the storage tank and the power generation part and joins them circularly, wherein the hot water is heated by heat generated by the power generation part. The freeze proofing operation is performed by the cogeneration system. Therein, in accordance with the lowering of temperature on a prescribed position, flow rate increase propriety decision for deciding whether the flow rate of hot water in the heat recovery circuit can be increased is performed and, on the basis of the decision results of the flow rate increase propriety decision, the flow rate of hot water in the heat recovery circuit is increased.

Description

  The present invention relates to a cogeneration system using a fuel cell.

  2. Description of the Related Art Conventionally, a cogeneration system that generates electric power and can use exhaust heat generated at that time for hot water supply or heating is known. And as a power generation means employ | adopted as this kind of system, there exist a thing by a fuel cell and a thing by a gas engine. In recent years, solid oxide fuel cells (hereinafter also referred to as SOFC) have been put into practical use (for example, Patent Document 1). This SOFC does not emit carbon dioxide, unlike a gas engine, and does not emit carbon dioxide, and other known types of fuel cells (for example, molten carbonate fuel cells, phosphoric acid fuel cells, polymer electrolyte fuel cells) ) Has the advantage of having higher power generation efficiency.

Some of such cogeneration systems are used in general households. And the cogeneration system for homes generates electric power and heat at the same time. Here, regarding the power, the time to generate and the time to consume generally match. There is also a certain balance between power generation and consumption.
On the other hand, the time at which heat is generated and the time at which it is consumed are often significantly different. Also, the heat generation capacity per unit time and the required amount of heat per unit time during consumption are greatly different.
That is, the time at which heat is consumed is limited at home. Moreover, in the home, the heat demand is highest in the bath, and the bath consumes a large amount of heat in a short time.

Therefore, a cogeneration system for home use employs a configuration in which a storage tank is provided, hot water is produced by the generated heat, and this hot water is stored in the storage tank.
That is, in a home cogeneration system, a heat recovery circuit is provided that includes a power generation unit and a storage tank and connects the two in an annular shape. Then, the temperature of hot water flowing through the heat recovery circuit is raised by the heat generated in the power generation unit, and stored in a storage tank (hereinafter also referred to as heat storage operation).

  In addition, what forms temperature stratification in a storage tank is known as one form of a domestic cogeneration system provided with a storage tank.

  More specifically, in the cogeneration system in which temperature stratification is formed, hot water is taken out from the lower part of the storage tank during the heat storage operation, and the hot water is returned to the storage tank via the power generation unit. As a result, hot hot water is supplied from the upper part of the storage tank.

  Here, as is well known, since hot hot water has a density lower than that of low temperature hot water, when hot hot water is supplied to the storage tank, the hot hot water is accumulated upward and the low temperature hot water is accumulated on the bottom side.

  That is, when hot hot water is supplied from the upper side of the storage tank, it is clearly divided into a region where hot hot water is accumulated in the storage tank and a region where low temperature hot water is accumulated, and temperature stratification is formed inside the storage tank. Is done.

JP 11-159869 A

  Here, the above-mentioned SOFC has a feature that the heat generation temperature is high but the amount of exhaust heat is small. Therefore, when raising the temperature of the hot water in the heat storage operation, the flow rate of the hot water flowing through the heat recovery circuit must be extremely slowed down to reduce the circulating flow rate.

  However, when the flow rate of the hot water flowing through the heat recovery circuit is extremely slow, the hot water stays in the heat recovery circuit. In this case, if the cogeneration system is operated in a cold region where the temperature of the outside air is extremely low in winter, the hot water in the heat recovery circuit may be frozen by being cooled by the outside air.

  In view of this, it is conceivable to prevent the freezing by temporarily increasing the flow rate of the hot water flowing through the heat recovery circuit under the condition that the hot water in the heat recovery circuit may freeze.

  However, if the flow rate of hot water flowing through the heat recovery circuit is simply increased, low-temperature hot water that is not sufficiently heated flows from the upper part of the storage tank, and the temperature stratification formed inside the storage tank is disturbed. There is a problem that it ends up. That is, when low-temperature hot water flows in from the upper part of the storage tank, there is a problem that convection occurs in the storage tank and the temperature of the internal hot water becomes uniform.

  Then, this invention makes it a subject to provide the cogeneration system which can implement freezing prevention operation | movement, without disturbing the temperature stratification formed in the inside of a storage tank in view of the problem of the above-mentioned prior art.

  The invention according to claim 1 for solving the above-described problem has a power generation unit that has a built-in fuel cell and generates electric energy and thermal energy at the same time, and hot water is generated by the heat generated by the power generation unit. In a heating cogeneration system, a storage tank that stores hot water and a heat recovery circuit that includes the storage tank and the power generation unit and is connected in a ring shape, and is supplied to the hot water storage tank heated by the heat of the power generation unit And circulation of hot water between the power generation unit and the storage tank is performed through the heat recovery circuit, and the flow rate of hot water in the heat recovery circuit is increased on condition that the temperature is lowered at a predetermined position. The flow rate increase / decrease determination is performed to determine whether or not it is possible, and the freeze prevention operation is performed to increase the flow rate of hot water in the heat recovery circuit based on the determination result of the flow rate increase / decrease determination. A cogeneration system according to claim Rukoto.

  In the cogeneration system of the present invention, the flow rate increase / decrease determination is performed to determine whether or not the flow rate of the hot water in the heat recovery circuit can be increased on condition that the temperature at a predetermined position is lowered. And the antifreezing operation which increases the flow volume of the hot water of a heat recovery circuit based on the determination result of flow volume increase possibility determination is implemented. As a result, the antifreezing operation for increasing the flow rate of the hot water in the heat recovery circuit can be performed only when the normal operation of the cogeneration system is not adversely affected. Therefore, it is possible to perform the freeze prevention operation while preventing problems caused by increasing the flow rate of the heat recovery circuit, for example, problems such as disturbance of temperature stratification.

  The invention according to claim 2 is characterized in that the determination of whether the flow rate can be increased is a comparison between a predetermined temperature and a temperature of hot water flowing through the heat recovery circuit when the flow rate is increased by the heat recovery circuit. The cogeneration system according to claim 1.

  The cogeneration system of the present invention determines whether the flow rate can be increased based on the temperature of hot water when the flow rate is increased by the heat recovery circuit. That is, since the situation in which the flow rate is increased is simulated and the flow rate increase / decrease determination is performed based on the assumed temperature when the flow rate increases, it is possible to determine whether the flow rate can be increased with high accuracy.

  The invention according to claim 3 is characterized in that, when it is determined that the flow rate can be increased in the flow rate increase possibility determination, the target temperature of the hot water flowing through the heat recovery circuit is set as the predetermined temperature. It is a cogeneration system.

  According to such a configuration, even if the flow rate of the hot water flowing through the heat recovery circuit is increased, the temperature of the hot water flowing through the heat recovery circuit does not fall below a predetermined temperature. Therefore, hot water with low temperature does not flow into the storage tank from the heat recovery circuit, and it is possible to reliably prevent problems that may occur due to temperature drop of the hot water flowing through the heat recovery circuit, such as turbulence of temperature stratification in the storage tank. it can.

  According to a fourth aspect of the present invention, the heat recovery circuit includes an anti-freezing heater, and the anti-freezing heater is operated during the anti-freezing operation. Is a cogeneration system.

  The cogeneration system of the present invention includes an anti-freezing heater, and can operate the anti-freezing heater during the anti-freezing operation. Therefore, even if it is not possible to prevent the freezing of hot water simply by increasing the flow rate of the hot water in the heat recovery circuit, the temperature of the hot water is reliably increased by heating the hot water with the antifreeze heater. A decrease can be prevented. Further, even when the flow rate of the hot water in the heat recovery circuit cannot be increased, similarly, the freezing of the hot water can be surely prevented by the temperature rise of the hot water by the antifreezing heater.

  The invention according to claim 5 includes a power generation unit and a waste heat storage unit having at least the storage tank, and a power generation unit controller that controls the power generation unit, and a waste heat that controls the waste heat storage unit. A hot water storage unit control unit, and the power generation unit control unit transmits the information based on the determination result of the flow rate increase possibility determination to the exhaust heat hot water storage unit control unit as well as performing the flow rate increase possibility determination. The cogeneration system according to claim 4, wherein the hot water storage unit control unit operates the freeze prevention heater based on information transmitted from the power generation unit control unit.

The cogeneration system of the present invention may be configured such that separate control units control the power generation unit and the exhaust heat hot water storage unit. That is, the power generation unit control unit and the exhaust heat hot water storage unit control unit may control the power generation unit and the exhaust heat hot water storage unit, respectively. The power generation unit control unit and the exhaust heat hot water storage unit control unit may operate the freeze prevention heater based on the determination result of the flow rate increase / decrease determination by transmitting and receiving signals to and from each other. That is, the structure which performs another freeze prevention operation | movement by another control part which each controls a power generation unit and an exhaust heat hot water storage unit mutually transmitting / receiving a signal may be sufficient.
Thus, according to the configuration in which the two units are controlled by different control units, there is an advantage that the degree of freedom of the installation position of each unit is higher than the configuration in which the two control units are controlled by one control unit. . More specifically, for example, when the power generation unit and the waste heat storage unit are arranged at positions separated from each other, the wiring is extended from the control unit to each unit when one control unit controls two units. It is necessary to do. This restricts the installation positions of the two units. On the other hand, according to a configuration in which two units are controlled by different control units and information is transmitted and received with each other, such a restriction does not occur, and thus the degree of freedom of the installation position of each unit is high.

  According to the sixth aspect of the present invention, the hot water discharged from the lower part of the storage tank is heated by the heat generated by the power generation unit, and the heated hot water is returned to the storage tank from the upper side, whereby the temperature of the storage tank is increased. The cogeneration system according to any one of claims 1 to 5, wherein a stratification is formed.

  In the cogeneration system of the present invention, the hot water discharged from the lower part of the storage tank is heated by the heat generated in the power generation unit, and the heated hot water is returned to the storage tank from the upper side, whereby temperature stratification is performed on the storage tank. May be formed.

  The invention according to claim 7 is characterized in that, in the freeze prevention operation, when the flow rate of the hot water in the heat recovery circuit is increased, the rotational speed of the motor of the circulation pump is controlled so as to become a predetermined target temperature. A cogeneration system according to any one of claims 1 to 6.

  According to this configuration, the rotational speed of the circulation pump is controlled so that the hot water flowing into the hot water storage tank reaches a predetermined target temperature. Therefore, low-temperature hot water does not flow into the hot water storage tank, and temperature stratification in the hot water storage tank is not disturbed.

  The invention according to claim 8 is characterized in that, in the freeze prevention operation, when the flow rate of hot water in the heat recovery circuit is increased, the rotational speed of the motor of the circulation pump is controlled so as to have a predetermined flow rate. Item 7. The cogeneration system according to any one of Items 1 to 6.

  According to such a configuration, the rotational speed of the motor of the circulation pump is controlled so that the flow rate of the hot water flowing through the heat recovery circuit becomes a predetermined flow rate. In other words, hot water can be allowed to flow through the heat recovery circuit at a speed that can surely prevent freezing.

  According to the present invention, there is provided a cogeneration system capable of performing an anti-freezing operation while reliably preventing problems caused by increasing the flow rate of the heat recovery circuit, such as disturbance of temperature stratification in the storage tank. it can.

It is an operation principle figure showing a cogeneration system concerning an embodiment of the present invention. FIG. 2 is an operation principle diagram of the cogeneration system of FIG. 1, and shows a heat recovery circuit in black. FIG. 2 is an operation principle diagram of the cogeneration system of FIG. 1, and shows a hot water supply path in black. FIG. 2 is an operation principle diagram of the cogeneration system of FIG. 1, and shows a heat supply path in black. FIG. 2 is an operation principle diagram of the cogeneration system in FIG. 1, and shows a hot water flow in a normal heat storage operation mode in black. FIG. 2 is an operation principle diagram of the cogeneration system of FIG. 1, and shows a black and white flow of hot water in a heat storage operation mode when the fuel cell is at a low temperature. FIG. 2 is an operation principle diagram of the cogeneration system of FIG. 1, and is a diagram illustrating the flow of hot water when performing hot water supply operation using hot water in a storage tank in black. In addition, the flow of the hot water in the heat storage operation is represented by hatching to distinguish. FIG. 2 is an operation principle diagram of the cogeneration system of FIG. 1, and shows a black and white flow of hot water when hot water is supplied to a reheating heat exchanger using hot water in a storage tank. In addition, the flow of the hot water in the heat storage operation is represented by hatching to distinguish. It is an operation | movement principle figure of the cogeneration system of FIG. 1, and is the figure which showed the flow of the hot water at the time of supplying hot water to the heat exchanger for heat appliances using the hot water in a storage tank in black. In addition, the flow of the hot water in the heat storage operation is represented by hatching to distinguish. It is a flowchart which shows the operation | movement procedure which a power generation unit control part implements in the freeze prevention operation | movement of the cogeneration system of FIG. It is a flowchart which shows the operation | movement procedure which an exhaust heat hot water storage unit control part implements in the freezing prevention driving | operation of the cogeneration system of FIG.

  Below, the cogeneration system 1 which concerns on 1st Embodiment of this invention is demonstrated.

As shown in FIG. 1, the cogeneration system 1 of the present embodiment is a combination of a power generation unit 2 and a heat recovery device 3 (exhaust heat storage unit), which are connected by a reciprocating pipe 5. Is formed.
The cogeneration system 1 includes a heat recovery circuit 12, a hot water supply path 21, and a heat supply path 22 as main flow paths connecting the power generation unit 2 and the devices in the heat recovery apparatus 3. Further, a plurality of short-circuit paths are provided to communicate these flow paths with each other.

  The power generation unit 2 includes a fuel cell 6 that is a main component and a cooling means 7 that cools the fuel cell 6.

  The fuel cell 6 uses a fuel cell that operates at a high temperature. In this embodiment, a solid oxide fuel cell (so-called SOFC) is employed.

  The cooling means 7 includes a power generation side flow path 8 through which hot water flows and a power generation side heat exchanger 10 and a power generation side circulation pump 11 disposed in the power generation side flow path 8.

  The power generation side circulation pump 11 (circulation pump) is a device for circulating hot water through a heat recovery circuit 12 (FIG. 2) having a reciprocating pipe 5 as a component. The power generation side circulation pump 11 is a spiral pump and includes a motor (not shown). And the flow volume of the hot water which flows through the circuit 12 for heat recovery can be increased / decreased by changing the rotation speed of a motor.

  That is, the power generation unit 2 passes through the power generation side heat exchanger 10 by a function as a power generation device for supplying power to an external power load and heat generated by the power supply. It is the structure also provided with the function as a thermal energy generation device which heats the hot and cold water.

  The heat recovery apparatus 3 includes, as main components, a storage tank 15, an auxiliary heat source unit 16, and two heat supply heat exchangers 17 and 18 capable of supplying heat to the outside. The two heat supply heat exchangers are specifically a heat exchanger heat exchanger 17 and a bath reheating heat exchanger 18.

  The storage tank 15 is a sealed tank for storing hot water, and can form a temperature stratification of the hot water therein. The storage tank 15 has a heat recovery circuit 12, a hot water supply path 21, and a heat supply path 22 for the top connection parts 25 and 26 provided at the top and the bottom connection parts 27 and 28 provided at the bottom. The pipes to be configured are connected. In addition, although it is recommended that the top connection portions 25 and 26 and the bottom connection portions 27 and 28 are provided in two openings as in the present embodiment, one connection may be provided for each.

  Furthermore, the storage tank 15 has a configuration in which a plurality (four in this embodiment) of tank temperature sensors 30a to 30d are arranged in the direction of rising (height direction) of hot water stored therein. The tank temperature sensors 30a to 30d function as temperature detection means for detecting the temperature of hot water in the storage tank 15 and detect the remaining amount of hot water in the storage tank 15 at a predetermined temperature or a predetermined temperature range. It also serves as a remaining amount detection means.

Here, in general, when hot water is stored in a storage tank, the hot water is divided into layers for each temperature if the temperature difference between the hot water and the hot water is a predetermined threshold value (about 10 degrees Celsius). Therefore, the hot water passing through the heat recovery circuit 12 is heated to a temperature higher than the threshold temperature with respect to the temperature of the hot water in the storage tank 15 and slowly returned to the extent that the hot water in the storage tank 15 is not disturbed. Then, the hot water stored in the storage tank 15 is divided into layers for each temperature (temperature stratification). That is, a high temperature layer accumulated in the upper part of the storage tank 15 and a low temperature layer accumulated in the lower part are formed.
Therefore, it is possible to detect how much hot water heated to a desired temperature range is stored in the storage tank 15 by examining the detection temperatures of the tank temperature sensors 30a to 30d installed in the storage tank 15. .

  As will be described in detail later, in the cogeneration system 1 of this embodiment, the low-temperature hot water taken out from the bottom of the storage tank 15 is discharged to the heat recovery circuit 12 and passes through the power generation side heat exchanger 10 of the power generation unit 2. By doing so, the heat exchange / heating is performed, and the storage tank 15 is slowly returned to the top side.

  The auxiliary heat source unit 16 is the same as a conventionally known water heater. The auxiliary heat source unit 16 includes a burner 31 for burning fuel such as gas and kerosene and an auxiliary heat source side heat exchanger 32, and heats hot water using heat energy generated by the combustion of the fuel. Is.

  Next, main flow paths in the cogeneration system 1 of the present embodiment will be described.

  As described above, the cogeneration system 1 of the present embodiment mainly includes the heat recovery circuit 12, the hot water supply path 21, and the heat supply path 22. Hereinafter, each flow path will be described.

First, the heat recovery circuit 12 will be described.
As shown in black in FIG. 2, the heat recovery circuit 12 has an annular shape including a power generation side circulation pump 11 and a power generation side heat exchanger 10 in the power generation unit 2 and a storage tank 15 in the heat recovery device 3. This is a connected flow path, and is a flow path capable of circulating hot water between the power generation side heat exchanger 10 and the storage tank 15. Specifically, the heat recovery circuit 12 includes a heat recovery forward passage 37 through which hot water flows from the storage tank 15 toward the power generation side heat exchanger 10, and hot water from the power generation side heat exchanger 10 toward the storage tank 15. And a heat recovery bypass passage 40 that bypasses the storage tank 15.
That is, the upstream side of the heat recovery forward flow path 37 is connected to the bottom connection portion 27 of the storage tank 15, and the downstream side of the heat recovery return flow path 38 is connected to the top connection portion 25 of the storage tank 15. Further, a heat recovery bypass flow path 40 is connected so as to short-circuit the intermediate portion between them, thereby forming a heat recovery circuit 12.

  The heat recovery forward flow path 37 includes a three-way valve 41 that is a flow path switching means that enables the flow path to be switched midway, a radiator temperature sensor 47 that detects the temperature of hot water, an antifreezing heater 44, A radiator 42 serving as a heat dissipating means is provided. Further, the heat recovery forward flow path 37 includes a heat recovery side forward flow path temperature sensor 43 and a power generation side forward flow at a portion located inside the power generation unit 2 and a portion located inside the heat recovery apparatus 3, respectively. A path temperature sensor 49 is provided.

  The three-way valve 41 has three ports 41a to 41c and can switch the flow path to two paths. That is, in the three-way valve 41, when the port 41a and the port 41c are communicated with each other, the other port 41b is closed, and the heat recovery forward flow path 37 can be made to flow. Further, in the three-way valve 41, when the port 41b and the port 41c communicate with each other, the other port 41a is closed, and the heat recovery bypass flow path 40 can be in a flowable state.

  The antifreeze heater 44 is a so-called ceramic heater in which a heating element is built in alumina or ceramics formed into a flat plate shape as a heater. This anti-freezing heater can heat a pipe or the like forming the heat recovery flow path 37 by heat generated by energization. More specifically, the hot water flowing through the heat recovery forward flow path 37 can be heated by heating the piping or the like forming the heat recovery forward flow path 37.

  The radiator 42 includes a fan 45 and employs a radiator that lowers the temperature of hot water passing therethrough due to an air cooling effect. The fan 45 of the radiator 42 can control power based on the temperature detected by the radiator temperature sensor 47.

  The heat recovery side forward flow path temperature sensor 43 detects the temperature of hot water flowing through the heat recovery forward flow path 37. More specifically, when hot water is introduced from the heat recovery device 3 side to the power generation unit 2 side, the temperature of the hot water immediately before being sent out to the outside in the heat recovery device 3 is detected.

  The power generation side forward flow path temperature sensor 49 detects the temperature of hot water flowing through the heat recovery forward flow path 37, and more specifically, detects the temperature of hot water immediately after being introduced into the power generation unit 2. It is.

  The heat recovery return flow path 38 is provided with a power generation side return flow path temperature sensor 48 and a heat recovery side return flow path temperature sensor 46 in the middle. These are all arranged on the upstream side (the power generation side heat exchanger 10 side) of the connection part of the heat recovery bypass flow path 40 connected to the heat recovery return flow path 38, and the power generation side return flow path from the upstream side. The temperature sensor 48 and the heat recovery side return flow path temperature sensor 46 are arranged in this order. Further, at this time, the power generation side return flow path temperature sensor 48 is arranged in a portion located inside the power generation unit 2, and the heat recovery side return flow path temperature sensor 46 is arranged in a portion located inside the heat recovery apparatus 3. Has been.

  The power generation side return flow path temperature sensor 48 detects the temperature of the hot water flowing through the heat recovery return flow path 38, and more specifically, detects the temperature of the hot water immediately after being heated by the power generation unit 2. Can do. In other words, when returning hot water from the power generation unit 2 side to the heat recovery device 3 side, the temperature of the hot water immediately before being sent out to the outside in the power generation unit 2 is detected.

  The heat recovery side return flow path temperature sensor 46 detects the temperature of the hot water flowing through the heat recovery return flow path 38, and more specifically, detects the temperature of the hot water immediately after being returned to the heat recovery device 3. To do.

Next, the hot water supply path 21 will be described.
The hot water supply path 21 is a flow path for discharging hot water having a desired temperature to the outside. That is, the hot water supply path 21 has a water supply channel 50 located upstream from the storage tank 15 and a hot water supply located downstream from the storage tank 15 with reference to the water supply source, as shown in black in FIG. A flow path 51 is used.

  The water supply channel 50 is connected to the bottom connection portion 28 of the storage tank 15. Thereby, the cogeneration system 1 is configured such that low-temperature hot water supplied from the outside can be introduced from the bottom side of the storage tank 15.

  A water supply temperature sensor 52 that detects the temperature of hot water supplied from the outside, a check valve 53, and a three-way valve 55 that serves as a flow path switching unit are provided in the middle of the water supply flow path 50. Yes.

  The three-way valve 55 is substantially the same as the structure of the three-way valve 41 in the heat recovery circuit 12 (see FIG. 2), and has three ports 55a to 55c. That is, in the three-way valve 55, when the port 55a and the port 55b communicate with each other, the other port 55c is closed, and the upstream water supply channel 50a located on the upstream side (water supply source side) of the water supply channel 50 and the water supply channel It is possible to circulate with the downstream side water supply flow path 50b located on the downstream side of the 50 (the storage tank 15 side). Further, when the port 55a and the port 55c communicate with each other, the other port 55b is closed, and the upstream side water supply flow path 50a and the tank bypass flow path 56 can be circulated.

  The hot water flow path 51 is a flow path that is connected to the top connection portion 26 of the storage tank 15 and leads to the hot water tap or the recirculation circulation path 35. That is, a bath-side branch 57 that communicates with the recirculation circulation channel 35 is connected in the middle of the hot water flow channel 51.

  Further, in the middle of the hot water flow passage 51, a high temperature side temperature sensor 58, a hot water mixing valve 60 having three ports, a flow rate sensor 61, a proportional valve 62, and a hot water temperature sensor 63 are sequentially arranged from the upstream side. Is provided. The hot water / water mixing valve 60 is connected to a water supply branch 65 that branches from the water supply passage 50. The water supply branch 65 is a flow path for joining the hot water supplied from the outside with the hot water flowing through the hot water flow path 51.

  A check valve 66 is provided in the midstream of the water supply branch 65 to prevent the hot water from flowing backward from the hot water flow channel 51 side toward the water supply source side. Downstream of this, it is connected to the hot and cold mixing valve 60.

  That is, the hot water passing through the hot water flow path 51 is adjusted to a desired temperature by mixing hot and cold hot water with the hot water mixing valve 60, and is controlled to a desired flow rate with the proportional valve 62.

Next, the heat supply path 22 will be described.
As shown in black in FIG. 4, the heat supply path 22 includes a heat appliance flow path 67 provided with a heat exchanger heat exchanger 17 and a bath reheating flow provided with a bath reheating heat exchanger 18. The circulation channel is formed to include the channel 68.

  Specifically, the heat supply path 22 is a flow path branched from the aforementioned hot water flow path 51 (see FIG. 3), and is divided into the hot water branch flow path 70, the heat exchange flow path 71, and the heat exchange flow path 71. The flow path is formed by a heat appliance flow path 67 and a bath reheating flow path 68 branched from the heat flow return path 72. For easier understanding, if attention is paid to hot water flowing through the heat supply path 22, the hot water discharged from the top connection portion 26 of the storage tank 15 is discharged from the hot water flow channel 51 through the branch portion 54 to the hot water branch flow channel. 70, passes through the junction 92, and is introduced into the heat exchange channel 71. And it branches from the heat transfer flow path 71 by the branch part 82, and passes the flow path 67 for heat appliances, and the flow path 68 for reheating a bath. After that, they merge at the junction 83 and are introduced again into the storage tank 15 via the heat exchange return channel 72.

  In the hot water branch passage 70, a three-way valve 73 serving as a passage switching means, a circulation pump 76, an auxiliary heat source incoming water temperature sensor 77, and an auxiliary heat source flow rate sensor 78 are sequentially inserted in the middle from the upstream side (storage tank 15 side). And an auxiliary heat source three-way valve 80 and an auxiliary heat source hot water temperature sensor 81 are provided.

  The circulation pump 76 is activated when hot water is circulated through the heat supply path 22, and the auxiliary heat source incoming water temperature sensor 77 and the auxiliary heat source flow rate sensor 78 determine the temperature and flow rate of hot water entering the auxiliary heat source machine 16. The auxiliary heat source hot water temperature sensor 81 detects the temperature of the hot water discharged from the auxiliary heat source machine 16. That is, the combustion amount of the auxiliary heat source unit 16 is determined based on the information detected by each of these sensors.

  The three-way valve 73 has three ports 73a to 73c, and opens a flow path for flowing hot water from the storage tank 15 to the hot water branch flow path 70 side, or supplies hot water from the tank bypass flow path 56 to the hot water branch flow path 70. The flow path flowing through the can be opened. Similarly, the auxiliary heat source three-way valve 80 also has three ports 80a to 80c, and opens a flow path for flowing hot water in the tapping branch flow path 70 to the auxiliary heat source apparatus 16 or bypasses the auxiliary heat source apparatus 16. The flow path to be opened can be opened.

  The heat exchange channel 71 is a channel from the junction 92 connected to the downstream end of the hot water branch channel 70 to the branch 82 to the heating device channel 67 and the bath reheating channel 68. is there.

  The heat appliance flow path 67 is a flow path from the branch portion 82 through the heat appliance heat exchanger 17 to the junction 83 to the heat exchange return flow path 72. The heat appliance flow path 67 is provided with an electromagnetic valve 85 on the downstream side of the heat appliance heat exchanger 17.

  The bath reheating flow path 68 is a flow path from the branch portion 82 through the bath reheating heat exchanger 18 to the junction 83 to the heat exchange return flow path 72. The bath reheating flow path 68 is provided with an electromagnetic valve 86 on the downstream side of the bath reheating heat exchanger 18.

  The heat exchange return channel 72 is a channel from the junction 83 to the storage tank 15.

  The heat exchange return channel 72 is provided with a temperature sensor 93, a flow rate sensor 95, and the above-described three-way valve 55 in the middle.

  Opening and closing of the three-way valves 73 and 80 of the outgoing hot water branching channel 70, the electromagnetic valve 85 of the heating device channel 67, the electromagnetic valve 86 of the bath reheating channel 68, and the three-way valve 55 in the heat exchange return channel 72, respectively. The state is controlled and the operation of the circulation pump 76 is controlled, whereby the water flow in the heat supply path 22 is controlled.

  Further, the cogeneration system 1 of the present embodiment includes a tank bypass flow path 56 that bypasses the storage tank 15 and a branch path 87 branched from the heat supply path 22 as shown in FIG.

  The tank bypass flow channel 56 is a flow channel branched from the water supply flow channel 50, and the hot water passing through the port 55 c of the three-way valve 55 leads to the port 73 c of the three-way valve 73 provided in the hot water branch flow channel 70. is there. That is, the hot water that has passed through the tank bypass flow path 56 can flow into the hot water branch flow path 70 without being introduced into the storage tank 15.

  A temperature sensor 101 is provided in the middle of the tank bypass flow path 56.

  The branch path 87 is connected to the downstream side of the auxiliary heat source hot water temperature sensor 81, and specifically, is connected to a junction 92 that is a connection portion of the hot water branch flow path 70 and the heat transfer flow path 71. . Further, in the middle of the branch path 87, a temperature sensor 102 and a proportional valve 91 are provided in order from the merging portion 92 side.

  Further, the operation of the cogeneration system 1 of the present embodiment is controlled by a control unit (not shown). The components provided in this control means are the same as those provided in a conventionally known cogeneration system. For example, the control means may be configured to include a CPU, a memory incorporating a predetermined control program, and the like. Based on the detection signals of the sensors provided in each part, the data stored in the memory, etc., the control means includes a valve, a power generation unit 2, an auxiliary heat source unit 16 and the like provided in each part of the cogeneration system 1. The operation is controlled to optimize the total energy efficiency of the cogeneration system 1.

  The control means of the cogeneration system 1 includes a power generation unit control unit that mainly controls the power generation unit 2 and an exhaust heat hot water storage unit control unit that mainly controls the heat recovery device 3.

  The power generation unit controller can acquire values detected by the sensors provided in the power generation unit 2 such as the power generation side forward flow path temperature sensor 49 and the power generation side return flow path temperature sensor 48. Further, the power generation unit control unit controls the operation of various devices provided in the power generation unit 2 such as the power generation side circulation pump 11 based on the values acquired from the sensors and the signals received from the exhaust heat storage unit control unit. be able to.

  The waste heat storage unit control unit can acquire values detected by sensors provided in the heat recovery device 3 such as the heat recovery side forward flow path temperature sensor 43 and the heat recovery side return flow path temperature sensor 46. . Further, the exhaust heat hot water storage unit control unit controls the operation of various devices provided in the power generation unit 2 such as the anti-freezing heater 44 based on the value acquired from each sensor and the signal received from the power generation unit control unit. Can do.

  That is, the power generation unit control unit and the exhaust heat hot water storage unit control unit can transmit and receive signals to and from each other. Specifically, a signal for operating a device provided in the power generation unit 2 or the heat recovery device 3 can be transmitted and received based on the detection signals of the sensors acquired by each.

  Subsequently, the operation in the normal operation mode of the cogeneration system 1 of the present embodiment will be described. In addition, since the normal driving | operation operation | movement of the cogeneration system 1 of this embodiment is as substantially the same as a well-known technique, it demonstrates easily.

The cogeneration system 1 of this embodiment is an operation operation for heat consumption selected from an operation mode group including a heat storage operation mode in which the heat storage operation is performed independently, a hot water supply operation mode, a reheating operation mode, and a heating operation mode. The operation can be performed by selecting the mode.
Each operation mode will be described below.

(Heat storage operation mode)
In the heat storage operation mode, by operating the power generation side circulation pump 11, a water flow is generated in the heat recovery circuit 12, the exhaust heat generated by the operation of the power generation unit 2 is recovered, and hot water is heated. This is an operation mode in which a heat storage operation for storing hot water in the storage tank 15 is performed. That is, this is an operation mode in which the heat storage operation is performed independently when there is no request for operation operation. In other words, it can be said to be a standby mode.

That is, when the cogeneration system 1 operates in the heat storage operation mode, the three-way valve 41 is closed with respect to the heat recovery bypass passage 40 (closes the port 41b) based on a control signal transmitted from a control means (not shown), The heat recovery forward flow path 37 and the heat recovery return flow path 38 are controlled to be open. Therefore, in the heat recovery circuit 12, as shown in black in FIG. 5, the bottom connection portion 27 of the storage tank 15 starts from the bottom connection portion 27 toward the top connection portion 25 of the storage tank 15 via the power generation unit 2. Circulating hot water is generated. On the other hand, in the power generation unit 2, since the fuel cell 6 generates power and generates heat, the power generation side heat exchanger 10 is heated. That is, the hot water introduced into the power generation unit 2 is heated by the exhaust heat of the fuel cell 6, and the heated hot water passes through the heat recovery return flow path 38, and reaches the upper side of the storage tank 15 (top connection portion 25. ). And by performing such operation | movement continuously, the hot water heated by the storage tank 15 is stored gradually.
At this time, although not particularly limited, the flow rate of the hot water flowing through the heat recovery circuit 12 is 100 cc / min or more and 300 cc / min or less, or an amount slightly less than 100 cc / min to 300 cc / min. It has become.

  Here, in the heat storage operation mode of this embodiment, when the temperature of the hot water flowing through the heat recovery return flow path 38 is low, an operation of circulating hot water in the heat recovery return flow path 38 is performed. That is, when the temperature of the hot water flowing through the heat recovery return flow path 38 is low, the temperature stratification in the storage tank 15 is disturbed if the hot water is returned to the storage tank 15. Therefore, when the temperature of the hot water flowing through the heat recovery return flow path 38 is low, the open port of the three-way valve 41 is switched so that the hot water flows from the heat recovery return flow path 38 to the heat recovery bypass flow path 40 side. . More specifically, as shown in black in FIG. 6, the water flow upstream of the three-way valve 41 in the heat recovery forward flow path 37 is stopped, and the flow path of the heat recovery circuit 12 is the storage tank 15. Hot water is caused to flow through the flow path that bypasses the flow, and the hot water is heated by the power generation unit 2. Such an operation is continued until the return-side temperature sensor 46 detects a predetermined temperature or higher.

  That is, in the operation of recovering the exhaust heat generated by the operation of the power generation unit 2 to heat the hot water and storing the hot water in the storage tank 15, the temperature of the hot water flowing through the heat recovery return passage 38 is equal to or higher than a predetermined temperature. It implements on condition that it is. On the other hand, when the temperature of the hot water flowing through the heat recovery return flow path 38 is low, the operation of circulating the hot water in the heat recovery return flow path 38 is performed by switching the port that the three-way valve 41 opens. Control is performed so that hot water does not flow from the return flow path 38 to the storage tank 15.

(Hot water operation mode)
During the hot water supply operation mode, the heat storage operation is always performed as indicated by hatching in FIG. That is, when the cogeneration system 1 using SOFC operates in the hot water supply operation mode, both the heat storage operation and the hot water supply operation are performed.

  At this time, when a hot water tap or the like is operated, a part of the low-temperature hot water supplied from an external water supply source flows into the storage tank 15 from the bottom connection portion 28. Thereby, hot hot water staying at the top of the storage tank 15 is discharged to the hot water flow path 51.

  Further, the low-temperature hot water supplied from an external water supply source also flows into the water supply branch 65. Thus, the hot water mixing valve 60 is introduced into the hot water flow path 51.

  That is, in the hot water supply operation mode, as indicated by black coating in FIG. 7, in addition to the heat storage operation, the hot hot water stored in the storage tank 15 and the low temperature hot water that has passed through the water supply branch 65 are merged. In this way, a water flow is formed, adjusted to a predetermined temperature, and hot water is supplied from a hot water tap (including dropping into the bathtub).

(Fast driving mode)
Even during the chasing operation mode, the heat storage operation is always performed as indicated by hatching in FIG. That is, when the cogeneration system 1 using the SOFC operates in the reheating operation mode, the heat storage operation and the reheating operation for supplying high-temperature hot water to the reheating heat exchanger 18 are performed.

  At this time, hot water is supplied to the reheating heat exchanger 18 and hot water in the bathtub is circulated in the recirculation circulation channel 35 (see black in FIG. 8). As a result, the hot hot water circulating in the heat supply path 22 (bath reheating channel 68) and the hot water in the bathtub circulating in the recirculation circulation path 35 exchange heat. As a result, the hot water in the bathtub is heated to a desired temperature.

(Heating operation mode)
Even during the heating operation mode, the heat storage operation is always performed as indicated by hatching in FIG. 9. That is, when the cogeneration system 1 using SOFC operates in the heating operation mode, both the heat storage operation and the heating operation for supplying high-temperature hot water to the heat exchanger 17 for a heating appliance are performed.

  At this time, hot hot water is supplied to the heat exchanger 17 for the heat appliance, and a circulating flow of hot water (a heat medium for supplying heat to a heating device (not shown)) is generated in the heating circulation passage 36. (See black in FIG. 9). As a result, the hot water that circulates through the heat supply path 22 (heat appliance flow path 67) and the hot water that serves as a heat medium that circulates through the heating circulation path 36 exchange heat. As a result, heat is supplied to a heating device (not shown).

  The above is the description of the operation in the operation mode for normal heat consumption.

  Here, as described above, the SOFC has a high heat generation temperature but a small amount of exhaust heat. Therefore, in the present embodiment, the flow rate of hot water flowing through the heat recovery circuit 12 is reduced when the heat storage operation mode is performed. And the hot water is circulated slowly by that, and the hot water is fully heated. Further, as described above, when returning hot water to the storage tank 15 in the heat storage operation mode, it is necessary to slowly return the hot water in the storage tank 15 to such an extent that the hot water in the storage tank 15 is not disturbed in order to maintain temperature stratification in the storage tank 15. . From this point of view, when hot water is supplied to the heat recovery circuit 12 in the heat storage operation mode, it is necessary to reduce the flow rate and to supply hot water slowly.

  However, when the cogeneration system 1 is used in a cold region, there is a concern that hot water flowing in the heat recovery circuit 12 may freeze due to a decrease in the temperature of the outside air if hot water is slowly flowed in the heat recovery circuit 12. The That is, when the flow rate of the hot water flowing through the heat recovery circuit 12 is extremely low, the hot water stays in the heat recovery circuit 12. At this time, if the outside air temperature decreases, the hot water in the heat recovery circuit 12 may be frozen.

  Therefore, in the cogeneration system 1 of the present embodiment, an anti-freezing operation is performed in order to prevent freezing of hot water flowing through the heat recovery circuit 12 due to a temperature drop of the outside air. The freeze prevention operation which is a characteristic operation of the present embodiment will be described in detail below.

  The freeze prevention operation of the present embodiment is started on the condition that the temperature drop of the hot water flowing through the heat recovery circuit 12 is detected in the power generation unit 2 or the heat recovery device 3. Then, any one of the first freeze prevention operation, the second freeze prevention operation, and the third freeze prevention operation is performed.

  The first antifreezing operation is an operation of flowing hot water through the heat recovery circuit 12 in a state where the antifreezing heater 44 is operated. More specifically, the first freeze prevention operation is an operation performed when the fuel cell is not generating power, and includes a heat recovery forward flow path 37, a heat recovery return flow path 38, and a heat recovery bypass flow path. Hot water is allowed to flow through the circulation circuit formed by 40 (see black in FIG. 6). At this time, the flow rate of hot water flowing through the circulation circuit is larger than the average value of the flow rate of hot water in the heat storage operation mode (for example, a flow rate of less than 200 cc / min, hereinafter also referred to as a normal flow rate), The flow rate is sufficient to prevent freezing of hot water in the recovery circuit 12 (for example, 1 L / min).

  The second freeze prevention operation is an operation in which the flow rate of hot water flowing through the heat recovery circuit 12 is increased from a normal flow rate (for example, a flow rate of less than 200 cc / min) with the freeze prevention heater 44 stopped. is there. More specifically, this operation is performed when the fuel cell is generating power and the flow rate of hot water flowing through the heat recovery circuit 12 is relatively high. That is, it is performed when the flow rate of hot water is relatively high and the hot water flowing into the storage tank 15 does not become low temperature even if the flow rate of hot water is increased from a normal flow rate (for example, a flow rate of less than 200 cc / min). In the present embodiment, the flow rate of hot water when the second antifreezing operation is performed is preferably 200 cc / min or more and 1 L / min or less. In other words, the flow rate is lower than the flow rate of the first freeze prevention operation and higher than the normal flow rate, and the flow rate can sufficiently prevent freezing of hot water.

  The third freeze prevention operation is an operation in which the flow rate of hot water flowing through the heat recovery circuit 12 is set to a normal flow rate (for example, a flow rate of less than 200 cc / min) in a state where the freeze prevention heater 44 is operated. . More specifically, this operation is performed when the fuel cell is generating power and the flow rate of hot water flowing through the heat recovery circuit 12 is relatively low. That is, when the flow rate of hot water is relatively low and the flow rate of hot water is increased from the normal flow rate (for example, less than 200 cc / min), the hot water flowing into the storage tank 15 becomes low temperature. Is done.

  More specifically, if the fuel cell 6 is not generating power when the freeze prevention operation is started, the first freeze prevention operation is performed.

  On the other hand, if the fuel cell 6 is generating power when the freeze prevention operation is started, it is determined whether or not the flow rate of the hot water flowing through the heat recovery circuit 12 can be increased. That is, if the flow rate is increased, it is determined whether or not the temperature of the hot water flowing into the storage tank 15 is equal to or higher than a predetermined temperature Ta (for example, 40 degrees Celsius).

  As a result of the determination, if it is confirmed that the temperature of the hot water flowing into the storage tank 15 is equal to or higher than the predetermined temperature Ta even if the flow rate is increased, the second antifreezing operation is performed. Further, if the flow rate of hot water is increased and the temperature of the hot water flowing into the storage tank 15 becomes lower than the predetermined temperature Ta, the third freeze prevention operation is performed.

  The anti-freezing operation of the present embodiment will be described in more detail below with reference to FIGS.

  First, the operation | movement at the time of the freeze prevention driving | operation by the electric power generation unit 2 side controlled by the electric power generation unit control part is demonstrated.

  When it is detected by the power generation side forward flow path temperature sensor 49 that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or lower than a predetermined temperature Tb (for example, 3 ° C.), or by the power generation side return flow path temperature sensor 48 Either when it is detected that the temperature of the hot water flowing through the recovery circuit 12 is equal to or lower than the predetermined temperature Tb, or when a freeze response instruction signal transmitted from the exhaust heat hot water storage unit control unit is detected The process proceeds to step 102 (in the case of Yes in step 101), and the freeze prevention operation is started.

  Here, as will be described in detail later, on the heat recovery device 3 side, when it is detected that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or lower than the predetermined temperature Tb, the exhaust heat hot water storage unit control unit is on the power generation unit 2 side. A freeze response instruction signal is transmitted to the power generation unit controller. That is, when it is detected by the power generation unit 2 or the heat recovery device 3 that the temperature of the hot water flowing through the heat recovery circuit 12 is low (below the predetermined temperature Tb), the freeze prevention operation is started.

  When the freeze prevention operation is started, the power generation unit control unit determines whether or not the fuel cell 6 is generating power (step 102).

If the fuel cell 6 is not generating power (No in step 102), the first freeze prevention operation is performed (step 110). That is, the power generation-side circulation pump 11 is started, and hot water is supplied to the heat recovery circuit 12 at a specified flow rate Q1 (for example, 1 L / min). Further, the power generation unit controller transmits a signal instructing the operation of the freeze prevention heater 44 to the exhaust heat hot water storage unit controller. At this time, as will be described in detail later, the antifreeze heater 44 is activated in the heat recovery device 3.
The cogeneration system 1 of the present embodiment is one in which the fuel cell 6 continues to generate power when operation is started after introduction. However, when power generation is stopped for some reason, the first freeze prevention operation ( Step 110) is performed.

On the other hand, when the fuel cell 6 is generating power (Yes in step 102), the flow rate of hot water flowing through the heat recovery circuit 12 is detected (step 103). When it is confirmed that the flow rate of hot water flowing through the heat recovery circuit 12 is sufficient to prevent the hot water from freezing in the heat recovery circuit 12 (Yes in step 103), the process returns to step 101. , The processing after step 101 is performed.
On the other hand, when the flow rate of the hot water flowing through the heat recovery circuit 12 is relatively small, that is, when the hot water may freeze in the heat recovery circuit 12, the cogeneration system 1 determines whether the flow rate can be increased. A determination is made (step 104). More specifically, the flow rate of hot water flowing through the heat recovery circuit 12 is changed from the flow rate at that time (the flow rate before the freeze prevention operation is performed and the normal flow rate, for example, 200 cc / min) to the specified flow rate Q2 (for example, When it is assumed that the temperature has increased to a predetermined flow rate of 200 cc / min or higher), it is determined whether or not the temperature of the hot water flowing into the hot water storage tank 15 is equal to or higher than a predetermined temperature Ta (for example, 40 degrees Celsius). If the temperature of the hot water flowing into the hot water storage tank 15 is predicted to be equal to or higher than the predetermined temperature Ta even if the flow rate of hot water is increased, it is determined that the flow rate can be increased (Yes in step 105). On the other hand, if the flow rate of hot water is increased, if the temperature of the hot water flowing into the hot water storage tank 15 is predicted to be lower than the predetermined temperature Ta, it is determined that the flow rate cannot be increased (No in step 105).

  At this time, the flow rate increase / decrease determination may be performed as appropriate, but as an example, there is a method of calculating a temperature Tx when the flow rate is increased and determining whether or not the temperature is equal to or higher than a predetermined temperature Ta (for example, 40 degrees Celsius). is there. Specifically, first, the fuel cell is calculated from the flow rates of hot water flowing through the heat recovery circuit 12 during the freeze prevention operation and the temperatures acquired by the power generation side forward flow path temperature sensor 49 and the power generation side return flow path temperature sensor 48. 6 calculates the amount of heat discharged. Next, the temperature Tx when the flow rate is increased is calculated from the calculated amount of heat and the temporary flow rate when increased. And it is the method of comparing whether the calculated temperature Tx is more than the predetermined temperature Ta. If the calculated temperature Tx is equal to or higher than the predetermined temperature Ta, it is determined that the flow rate can be increased. If the calculated temperature Tx is lower than the predetermined temperature Ta, it is determined that the flow rate cannot be increased.

  When it is determined that the flow rate can be increased in the flow rate increase / decrease determination (Yes in step 105), the second freeze prevention operation is performed (step 106). In the second freeze prevention operation, the flow rate of hot water flowing through the heat recovery circuit 12 is increased from a normal flow rate (a flow rate at the start of the freeze prevention operation, for example, 200 cc / min) to a specified flow rate Q2.

  Here, the specified flow rate Q2 is a normal flow rate (also a flow rate at the start of the freeze prevention operation, for example, 200 cc / min) or more, and is an appropriate flow rate.

  In the second freeze prevention operation, a signal for stopping the freeze prevention heater 44 is transmitted to the exhaust heat hot water storage unit controller. At this time, as will be described in detail later, if the anti-freezing heater 44 is stopped in the heat recovery apparatus 3, the stopped state is maintained in the anti-freezing heater 44 as it is. Moreover, if the freeze prevention heater 44 is operating in the heat recovery apparatus 3, it is stopped.

  By the way, when the second freeze prevention operation is performed, even if the flow rate of the hot water flowing through the heat recovery circuit 12 has already been changed by the freeze prevention operation, the flow rate of the hot water flowing through the heat recovery circuit 12 is determined as described above. Let the flow rate be Q2. That is, in this case as well, the flow rate of hot water flowing through the heat recovery circuit 12 is changed to a specified flow rate Q2, and a signal for stopping the freeze prevention heater 44 is transmitted to the exhaust heat storage unit control unit.

  If it is determined that the flow rate cannot be increased (No in step 105), the third anti-freezing operation is performed (step 109). That is, while maintaining the flow rate of the hot water flowing through the heat recovery circuit 12 at a normal flow rate (which is also the flow rate before the start of the freeze prevention operation, for example, 200 cc / min), the freeze prevention heater is controlled against the exhaust heat storage unit control unit. A signal to activate 44 is transmitted. At this time, as will be described in detail later, if the freeze prevention heater 44 is stopped in the heat recovery apparatus 3, the freeze prevention heater 44 is operated. Moreover, if the antifreezing heater 44 is operating in the heat recovery apparatus 3, the operating state is maintained.

  By the way, when the third freeze prevention operation is performed, the flow rate of the hot water flowing through the heat recovery circuit 12 is changed even if the flow rate of the hot water flowing through the heat recovery circuit 12 has already been changed by the freeze prevention operation. The flow rate is returned to the normal flow rate (which is also the flow rate before starting the freeze prevention operation, for example, 200 cc / min), and a signal for operating the freeze prevention heater 44 is transmitted to the exhaust heat storage unit control unit.

  Then, until it is detected that the temperature of the hot water flowing through the heat recovery circuit 12 in the power generation unit 2 and the heat recovery device 3 is equal to or higher than a predetermined temperature Tc (for example, 7 degrees Celsius) (while No in Step 107). The processing after step 102 is performed.

  On the other hand, when it is detected by the power generation side forward flow path temperature sensor 49 that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or higher than a predetermined temperature Tc, and the power recovery side flow path temperature sensor 48 detects the heat recovery circuit. 12 when the temperature of the hot water flowing through 12 is detected to be equal to or higher than the predetermined temperature Tc, and when the signal indicating the stop of the freeze prevention operation transmitted from the exhaust heat hot water storage unit control unit is detected (Yes in step 107). ), The process proceeds to step 108 and the freeze prevention operation is stopped.

  Here, there is a difference between a predetermined temperature Tc (for example, 7 degrees Celsius) that is a stop condition for the freeze prevention operation and a predetermined temperature Tb (for example, 3 degrees Celsius) that is the start condition for the freeze prevention operation. More specifically, the predetermined temperature Tc, which is the stop condition for the freeze prevention operation, is higher than the predetermined temperature Tb, which is the start condition for the freeze prevention operation.

  As will be described in detail later, on the heat recovery device 3 side, when it is detected that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or higher than the predetermined temperature Tc, the waste heat hot water storage unit controller is on the power generation unit 2 side. A signal instructing the power generation unit controller to stop the freeze prevention operation is transmitted. That is, when it is detected by the power generation unit 2 and the heat recovery device 3 that the temperature of the hot water flowing through the heat recovery circuit 12 is high (above the predetermined temperature Tc), the freeze prevention operation is stopped.

  Specifically, a signal for stopping the freeze prevention heater 44 is transmitted to the exhaust heat hot water storage unit controller, and the flow rate of hot water flowing through the heat recovery circuit 12 is set to the normal flow rate (flow rate before the start of the freeze prevention operation). However, for example, it is returned to 200 cc / min (step 108). And it waits until it detects that the temperature of the hot water which flows through the circuit 12 for heat recovery is low temperature (below predetermined temperature Tb) in the electric power generation unit 2 or the heat recovery device 3 (until it becomes Yes in step 101).

  This is the end of the description of the operation during the freeze prevention operation on the power generation unit 2 side.

  Next, the operation during the freeze prevention operation on the heat recovery device 3 side controlled by the exhaust heat hot water storage unit control unit will be described.

  In the heat recovery apparatus 3, when it is detected by the heat recovery side forward flow path temperature sensor 43 that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or lower than a predetermined temperature Tb (for example, 3 ° C.), or on the heat recovery side When the return channel temperature sensor 46 detects that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or lower than the predetermined temperature Tb, or the radiator temperature sensor 47 sets the temperature of the hot water flowing through the heat recovery circuit 12 to a predetermined temperature. When it is detected that the temperature is equal to or lower than the temperature Tb (Yes in Step 201), the exhaust heat hot water storage unit control unit transmits a signal for freezing instruction to the power generation unit control unit on the power generation unit 2 side. That is, when it is detected that the temperature of the hot water flowing through the heat recovery circuit 12 is low (predetermined temperature Tb or less), the exhaust heat hot water storage unit control unit sends a freeze response instruction signal to the power generation unit control unit on the power generation unit 2 side. To send.

  Further, when the heat recovery apparatus 3 receives a signal for operating the antifreeze heater 44 transmitted by the power generation unit control unit during the antifreeze operation (Yes in step 203), the antifreeze heater 44 is turned on. Activate (step 204). Specifically, the anti-freezing heater 44 is energized, and the anti-freezing heater 44 heats the piping and the like forming the heat recovery forward flow path 37. Then, the temperature of hot water flowing through the heat recovery flow path 37 is raised.

  On the other hand, when the signal for stopping the freeze prevention heater 44 transmitted by the power generation unit control unit is received while the freeze prevention operation is being performed (No in Step 203), the freeze prevention heater 44 is stopped (Step 207). ).

  When the signal for operating the freeze prevention heater 44 transmitted from the power generation unit control unit is received, the freeze prevention heater 44 is activated if it is stopped, and if the freeze prevention heater 44 is activated, the activated state is maintained. Let Similarly, when the signal for stopping the freeze prevention heater 44 transmitted by the power generation unit control unit is received, the freeze prevention heater 44 is stopped if it is in operation, and if it is stopped, the stopped state is set. Let it be maintained.

  Then, in the heat recovery apparatus 3, until it is detected that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or higher than a predetermined temperature Tc (for example, 7 degrees Celsius) (while No in Step 205), Step 202 and subsequent steps. Perform the process.

  On the other hand, when it is detected by the heat recovery side forward flow path temperature sensor 43 that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or higher than the predetermined temperature Tc, the heat recovery side return flow path temperature sensor 46 recovers the heat. When it is detected that the temperature of the hot water flowing through the circuit 12 is equal to or higher than the predetermined temperature Tc, and the temperature sensor 47 for the radiator detects that the temperature of the hot water flowing through the heat recovery circuit 12 is equal to or higher than the predetermined temperature Tc. If this occurs (Yes in step 205), the freeze prevention heater 44 is stopped, and a signal instructing the power generation unit controller to stop the freeze prevention operation is transmitted. And it waits until it detects that the temperature of the hot water which flows through the circuit 12 for heat recovery is below the predetermined temperature Tb in the heat recovery apparatus 3 (until it becomes Yes at step 201).

  This is the end of the description of the operation during the freeze prevention operation on the heat recovery device 3 side.

As described above, the flow rate of the hot water flowing through the heat recovery circuit 12 in this embodiment is a normal flow rate (which is also a flow rate before starting the freeze prevention operation, for example, 200 cc / min) and the third freeze prevention operation. Are the same (substantially the same). The flow rate Q2 during the second anti-freezing operation is equal to or higher than the flow rate during the third anti-freezing operation. Furthermore, the flow rate (1 L / min) during the first anti-freezing operation is larger than the flow rate Q2 during the second anti-freezing operation.
That is, the flow rate of the hot water flowing through the heat recovery circuit 12 increases in the order of normal time, the third anti-freezing operation, the second anti-freezing operation, and the first anti-freezing operation.
Therefore, the predetermined flow rate Q1 targeted for the flow rate of the hot water flowing through the heat recovery circuit 12 in the first freeze prevention operation is equal to the flow rate of the hot water flowing through the heat recovery circuit 12 in the second freeze prevention operation. It is larger than the target predetermined flow rate Q2. Furthermore, the predetermined flow rate Q2 is larger than the normal flow rate.

  Further, as described above, in the present embodiment, the freeze prevention operation is performed by transmitting and receiving various signals between the power generation unit control unit and the exhaust heat hot water storage unit control unit. Specifically, when either the power generation unit 2 or the heat recovery device 3 confirms a decrease in the temperature of the hot water flowing through the heat recovery circuit 12, the freeze prevention operation is started. Then, any one of the first anti-freezing operation, the second anti-freezing operation, and the third anti-freezing operation is performed, and the anti-freezing heater 44 is operated and stopped as necessary in these operations. And when the temperature rise of the hot water flowing through the heat recovery circuit 12 is confirmed, the freeze prevention operation is stopped.

In the above-described embodiment, the flow rate of hot water flowing through the heat recovery circuit 12 in the heat storage operation mode is changed from less than 100 cc / min to 300 cc / min, and the operation in the heat storage operation mode and the freeze prevention operation are controlled based on the flow rate of hot water. In this example, the flow rate is prioritized and the temperature is controlled according to the course, but the cogeneration system of the present invention is not limited to this.
For example, the operation in the heat storage operation mode or the freeze prevention operation may be controlled based on the temperature of hot water. In other words, control that prioritizes the temperature and sets the flow rate as a result may be performed. Specifically, when the heat storage operation mode is performed, a predetermined target temperature is set, and the rotation of the motor of the power generation side circulation pump 11 is controlled so as to be the set target temperature, thereby changing the flow rate of hot water. May be. In addition, when performing the freeze prevention operation, different target temperatures are set for the first freeze prevention operation, the second freeze prevention operation, and the third freeze prevention operation, and the power generation side circulation pump is set so as to be the target temperature. You may control rotation of 11 motors.

  Furthermore, the operation in the heat storage operation mode or the freeze prevention operation may be controlled based on the flow rate of hot water. For example, the antifreezing operation is performed so that the hot water flowing through the heat recovery circuit 12 has a predetermined flow rate based on the diameter of the pipe constituting the heat recovery circuit 12 and the flow rate of the hot water flowing through the heat recovery circuit 12. Also good. At this time, the first anti-freezing operation, the second anti-freezing operation, and the third anti-freezing operation may be operated in order of increasing the flow velocity.

  In the above-described embodiment, an example in which a ceramic heater is employed as the antifreeze heater has been described. However, the antifreeze heater employed in the cogeneration system of the present invention is not limited thereto. For example, the antifreeze heater may be a heating element such as a strip-shaped resistor, and may be configured such that such an antifreeze heater is wound around a pipe (a pipe forming the heat recovery forward flow path 37). . Further, it may be a heater formed of a flexible plate and a heating element such as a heating wire. That is, it is only necessary that the hot water flowing through the heat recovery forward flow path 37 can be heated.

1 Cogeneration system 2 Power generation unit (power generation unit)
3 Heat recovery device (exhaust heat storage unit)
12 Heat recovery circuit 15 Storage tank 44 Antifreeze heater

Claims (8)

In a cogeneration system that includes a fuel cell and has a power generation unit that simultaneously generates electric energy and thermal energy, and heats hot water with the heat generated by the power generation unit,
A storage tank for storing hot water, and a heat recovery circuit that includes the storage tank and the power generation unit and is connected in an annular shape,
Supply of hot water heated by the heat of the power generation unit to the storage tank and circulation of hot water between the power generation unit and the storage tank are performed via a heat recovery circuit,
The flow rate increase / decrease determination is performed to determine whether or not the flow rate of the hot water in the heat recovery circuit can be increased on the condition that the temperature of the predetermined position is lowered, and based on the determination result of the flow rate increase / decrease determination A cogeneration system that performs anti-freezing operation to increase the flow rate of hot water in the heat recovery circuit.   The cogeneration according to claim 1, wherein the determination of whether or not the flow rate can be increased is a comparison between a predetermined temperature and a temperature of hot water flowing through the heat recovery circuit when the flow rate is increased by the heat recovery circuit. system.   The cogeneration system according to claim 2, wherein when it is determined that the flow rate can be increased in the flow rate increase possibility determination, the target temperature of the hot water flowing through the heat recovery circuit is set as the predetermined temperature. The heat recovery circuit includes an anti-freezing heater,
The cogeneration system according to any one of claims 1 to 3, wherein the antifreeze heater is operated during the antifreeze operation. A power generation unit, and an exhaust heat storage unit having at least the storage tank,
A power generation unit control unit for controlling the power generation unit; and a waste heat storage unit control unit for controlling the exhaust heat storage unit;
The power generation unit control unit performs the flow rate increase possibility determination and transmits information based on the determination result of the flow rate increase possibility determination to the exhaust heat hot water storage unit control unit. The cogeneration system according to claim 4, wherein the anti-freezing heater is operated based on information transmitted from the control unit.   The hot water discharged from the lower part of the storage tank is heated by the heat generated in the power generation unit, and the heated hot water is returned to the storage tank from the upper side, thereby forming temperature stratification in the storage tank. The cogeneration system according to any one of claims 1 to 5, wherein the cogeneration system is characterized.   7. The rotation speed of the motor of the circulation pump is controlled so as to reach a predetermined target temperature when the flow rate of hot water in the heat recovery circuit is increased in the freeze prevention operation. The described cogeneration system.   7. The rotation speed of the motor of the circulation pump is controlled so that a predetermined flow rate is obtained when the flow rate of hot water in the heat recovery circuit is increased in the freeze prevention operation. Cogeneration system.

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