JP5531250B1 - Binary power generation system - Google Patents

Abstract

The present invention provides a binary power generation system capable of improving the efficiency of heat energy utilization as a whole system and improving the power generation efficiency.
A binary power generation system 10 using steam of a low boiling point medium as a working fluid, the evaporator 3 for heating the low boiling point medium to obtain the steam of the low boiling point medium, and the steam for heating the steam of the low boiling point medium A superheater 5, a turbine T that converts the kinetic energy of the low-boiling-point medium steam that has passed through the steam superheater 5 into rotational energy of a rotating shaft, and a condenser 9 that condenses the low-boiling-point medium steam that has passed through the turbine T. And has a closed-loop circulation system 15 that circulates a low-boiling medium inside, passes through the evaporator 3 and passes through the turbine T and the low-boiling medium before flowing into the steam superheater 5. The binary power generation system 10 further includes a first heat exchanger 6 that performs heat exchange with the low-boiling point medium after being introduced and before flowing into the condenser 9.
[Selection] Figure 1

Description

  The present invention relates to a binary power generation system using a vapor of a low boiling point medium as a working fluid.

  2. Description of the Related Art Conventionally, a binary power generation system is known that generates power by heating a low-boiling medium having a boiling point lower than that of water such as ammonia and rotating a turbine impeller of a turbine generator using generated steam. A conventional binary power generation system using a turbine generator includes an evaporator that heats and vaporizes a liquid low-boiling-point medium, a turbine that converts the kinetic energy of steam of the low-boiling-point medium into rotational energy of a rotating shaft, and a low-boiling point The low boiling point medium is circulated in a closed loop including a condenser for condensing the vapor of the medium and a medium feed pump for sending the liquid low boiling point medium to the evaporator. Thus, in the conventional binary power generation system, the rotational energy obtained by the turbine is converted into electric energy by the generator of the turbine generator.

  Here, in such a binary power generation system, it is required to effectively use waste heat or the like as a heat source for heating and evaporating a low boiling point medium to improve power generation efficiency.

  Thus, for example, Patent Document 1 proposes a binary power generation system that uses high-temperature gas or high-temperature wastewater generated in an incinerator that incinerates sludge and garbage as a heat source. In the power generation system described in Patent Document 1, high-temperature air heated by exhaust gas from an incinerator included in the sewage treatment system and smoke-washed wastewater discharged from the sewage treatment system after washing the exhaust gas are used as heat sources. The low boiling point medium is heated. Specifically, in the power generation system of Patent Document 1, in the evaporator, the low boiling point medium is evaporated by exchanging heat between the smoke-washed wastewater having a temperature lower than that of the high-temperature air and the low boiling point medium. In the steam superheater provided in the rear stage, heat exchange is performed between the high-temperature air and the steam (working fluid) of the low-boiling point medium, so that the waste heat can be used effectively while the high-temperature working fluid is used. Power generation efficiency is improved.

Japanese Unexamined Patent Publication No. 2011-174652

  According to the power generation system (binary power generation system) according to Patent Document 1, the low boiling point medium is efficiently heated using two kinds of heat sources having different temperatures, and the impeller of the turbine generator is generated using a high temperature working fluid. Therefore, the power generation efficiency can be improved as compared with the case where the low boiling point medium is heated using only one kind of heat source.

  Here, in the binary power generation system, the working fluid (steam of the low boiling point medium) after rotating the impeller of the turbine generator is cooled and condensed in the condenser. However, in the conventional binary power generation system using two types of heat sources having different temperatures, the turbine generator impeller is rotated using a high-temperature working fluid, and the turbine generator impeller is rotated. The temperature of the working fluid is also relatively high.

  Therefore, in the conventional binary power generation system using two types of heat sources having different temperatures, the utilization efficiency of the two types of heat is good, but the heat of the working fluid after rotating the impeller of the turbine generator There was room for improvement in the utilization efficiency of thermal energy as a whole binary power generation system because energy was not effectively used.

  Therefore, the objective of this invention made | formed in view of this situation is to provide the binary power generation system which can improve the utilization efficiency of the thermal energy as the whole binary power generation system, and can improve power generation efficiency.

  The inventors of the present invention have intensively studied for the purpose of solving the above problems. And in the binary power generation system using two types of heat sources having different temperatures, the present inventors heat the working fluid using the thermal energy of the working fluid after rotating the impeller of the turbine generator. Inspired by. Furthermore, the present inventors have conducted intensive studies, and in a binary power generation system using two types of heat sources, the working fluid after rotating the impeller of the turbine generator is hot, and therefore before passing through the evaporator. When it was used for heating the working fluid, it was found that the working fluid (low boiling point medium) could not be efficiently heated in the evaporator using a low-temperature heat source, and the present invention was completed.

An object of the present invention is to advantageously solve the above-mentioned problems, and a binary power generation system according to the present invention is a binary power generation system that uses steam of a low boiling point medium as a working fluid, and heats the low boiling point medium. To obtain the vapor of the low boiling point medium, the steam superheater for heating the vapor of the low boiling point medium, and the kinetic energy of the vapor of the low boiling point medium passing through the steam superheater is converted into the rotational energy of the rotating shaft And a condenser that condenses the vapor of the low-boiling-point medium in which a part of the kinetic energy is converted into the rotational energy of the rotating shaft in the turbine, and in which the low-boiling-point medium is circulated inside The low-boiling-point medium after passing through the evaporator and before flowing into the steam superheater, and after passing through the turbine and before Wherein before entering the condenser and further have a first heat exchanger for exchanging heat between the low-boiling medium, before flowing into the condenser even after having passed through the first heat exchanger A second heat exchanger for exchanging heat between the low boiling point medium and the low boiling point medium after passing through the condenser and before flowing into the evaporator; A heater that heats the low boiling point medium after passing through and before flowing into the second heat exchanger, and after flowing through the first heat exchanger, flows into the second heat exchanger A first temperature sensor that measures the temperature of the previous low-boiling medium; and a second temperature that measures the temperature of the low-boiling medium after passing through the heater and before flowing into the second heat exchanger. The low boiling point medium that has passed through the sensor and the heater is allowed to flow into the evaporator without passing through the second heat exchanger. Switching means for switching between the bypass flow path and the flow path to the second heat exchanger, the first flow path and the flow path through which the low-boiling-point medium flows after passing through the heater; And a control device that controls the switching means based on a temperature measurement value of the second temperature sensor, wherein the control device has a temperature measurement value of the first temperature sensor that is higher than a temperature measurement value of the second temperature sensor. A control device that switches to the flow path to the second heat exchanger when the temperature is high, and switches to the bypass flow path when the temperature measurement value of the first temperature sensor is equal to or lower than the temperature measurement value of the second temperature sensor. When, characterized Rukoto equipped with.
Thus, by performing heat exchange between the low boiling point medium after passing through the evaporator and before flowing into the steam superheater, and the low boiling point medium after rotating the rotating shaft of the turbine, The heat energy of the low-boiling-point medium after rotating the rotating shaft of the turbine can be effectively used to improve the utilization efficiency of the heat energy as the entire binary power generation system. Also, if the object to be heat exchanged with the low boiling point medium after rotating the rotating shaft of the turbine is the low boiling point medium after passing through the evaporator, it can be used for heating the low boiling point medium in the evaporator. Even if the heat source to be used is a low-temperature heat source, the low-boiling point medium in the evaporator can be efficiently heated. Incidentally, the temperature of the low-boiling medium steam after passing through the steam superheater is higher than the temperature of the low-boiling medium after rotating the rotating shaft of the turbine, so the low temperature after rotating the rotating shaft of the turbine is low. The target for heat exchange with the boiling point medium is the low boiling point medium before flowing into the steam superheater.

Furthermore, in addition to the first heat exchanger as described above, a second heat exchanger is further provided that heat-transfers the thermal energy of the low boiling point medium that has passed through the first heat exchanger to the low boiling point medium before flowing into the evaporator. Thereby, the thermal energy which the low boiling-point medium which passed through the 1st heat exchanger has can be used effectively, and the utilization efficiency of the thermal energy as the whole binary power generation system can be improved further.

Further, as described above, the temperature of the low boiling point medium that has passed through the heater with the first and second temperature sensors is compared with the temperature of the low boiling point medium that has passed through the first heat exchanger. Only when the temperature is higher, the heat transfer from the low boiling point medium passing through the first heat exchanger to the low boiling point medium passing through the heater (ie, using the second heat exchanger) makes it possible to Even when a temperature change occurs in the heat source used in the superheater, the utilization efficiency of the thermal energy as the entire binary power generation system can be further improved.

  According to the binary power generation system of the present invention, it is possible to improve the utilization efficiency of heat energy as the entire binary power generation system and improve the power generation efficiency.

It is explanatory drawing which shows schematic structure of the typical binary power generation system according to this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Here, in the binary power generation system of the present invention, power generation is performed using the vapor of the low boiling point medium as the working fluid. The binary power generation system of the present invention is not particularly limited, and may be a carina cycle type binary power generation system using a mixture of water and ammonia as a low boiling point medium. The binary power generation system of the present invention may be a Rankine cycle type binary power generation system that uses a simple substance such as ammonia, butane, or pentane as a low boiling point medium.

<Binary power generation system>
FIG. 1 shows a schematic configuration of an example of a binary power generation system according to the present invention. The binary power generation system 10 is a carina cycle type binary power generation system.

  The binary power generation system 10 includes a turbine generator including a turbine T and a generator 11. In the binary power generation system 10, the low boiling point medium tank 1, the medium feed pump P1, the heater 2 functioning as a regenerative heat exchanger, the evaporator 3, the separator 4, the steam superheater 5, Electric power is generated using a turbine generator by circulating a low boiling point medium in a closed loop circulation system 15 including a turbine T, a first heat exchanger 6, an absorber 8, and a condenser 9. The binary power generation system 10 preferably further includes a second heat exchanger 7, a first temperature sensor 12, a second temperature sensor 13, a switching unit 14, and a bypass channel 17. Further, the binary power generation system 10 may include a third heat exchanger 20.

  Here, the low boiling point medium tank 1 is a tank for storing a liquid low boiling point medium. Then, the low boiling point medium in the low boiling point medium tank 1 (in the binary power generation system 10 of this example, a mixture of water and ammonia) is sent to the evaporator 3 via the heater 2 by the medium feed pump P1. It is done.

  The heater 2 performs heat exchange between the low-temperature low-boiling medium and the high-temperature evaporation residual liquid separated in the separator 4 described in detail later, before the low-boiling medium flows into the evaporator 3. It is an apparatus for preheating a low boiling point medium. In the heater 2, the thermal energy of the evaporation residual liquid is effectively used for preheating the low boiling point medium.

  Then, the low boiling point medium preheated by the heater 2 is further heated in the evaporator 3, and at least a part thereof becomes steam. Specifically, in the evaporator 3, the low boiling point medium is heated, and a mixed fluid of the low boiling point medium vapor mainly composed of ammonia vapor and the evaporation residual liquid mostly composed of water is generated. Here, in the evaporator 3, for example, the low-boiling point medium is heated using a fluid having a first temperature (for example, warm water) as a heat source. The first temperature can be, for example, 50 ° C to 100 ° C. As a heat source for heating the low-boiling point medium in the evaporator 3, a heat source usually used in binary power generation such as hot waste water from an incinerator, exhaust gas from a heating furnace, hot spring water, steam, or the like may be used. it can.

  The separator 4 is a device that gas-liquid separates the mixed fluid of the low-boiling-point medium vapor and the evaporation residual liquid flowing out of the evaporator 3 into the low-boiling-point medium vapor and the evaporation residual liquid. Then, the low boiling point medium vapor separated by the separator 4 is sent to the steam superheater 5. Further, the evaporation residual liquid passes through the evaporation residual liquid flow path 16 and is sent to the absorber 8 through the heater 2. As the separator 4, a known gas-liquid separator such as a mist separator or a cyclone can be used.

  The steam superheater 5 is a device for further heating the low boiling point medium vapor separated by the separator 4 and improving the power generation efficiency of the binary power generation system 10. In the steam superheater 5, the low boiling point separated by the separator 4 using a fluid (for example, warm air) having a second temperature higher than the first temperature that is the temperature of the heat source (fluid) used in the evaporator 3. Heat the medium vapor. The second temperature can be, for example, 100 ° C to 400 ° C. In addition, as a heat source at the time of heating low boiling-point medium vapor | steam in the steam superheater 5, exhaust gas, such as an incinerator, warm air heated by it, a vapor | steam, hot spring vapor | steam, or a solar heat can be used.

  The turbine T is a device that converts the kinetic energy of the low-boiling-point medium vapor that has flowed out of the steam superheater 5 into the rotational energy of the rotating shaft. The rotating shaft of the turbine T is connected to the generator 11, and the rotational energy obtained by the turbine T is converted into electric energy in the generator 11. The temperature of the low boiling point medium vapor after passing through the turbine T can be, for example, 100 ° C to 300 ° C.

  The first heat exchanger 6 condenses after passing through the evaporator 3 and before flowing into the steam superheater 5 and after passing through the turbine T and after passing through the turbine T. Heat exchange is performed with the low boiling point medium (including low boiling point medium vapor) before flowing into the vessel 9. Most of the low boiling point medium after passing through the turbine T and before flowing into the condenser 9 (before flowing into the absorber 8 in the binary power generation system 10 in this example) is in a vapor state. Compared with the low-boiling-point medium steam that has flowed out of the superheater 5, a part of the kinetic energy of the low-boiling-point medium steam is converted into rotational energy of the rotating shaft in the turbine T, so that part of the thermal energy is lost. However, it is still hot. Therefore, the first heat exchanger 6 heat-transfers the thermal energy of the low boiling point medium to the low boiling point medium after passing through the evaporator 3 and before flowing into the steam superheater 5. Accordingly, the thermal energy of the low boiling point medium after passing through the turbine T and before flowing into the condenser 9 can be effectively used to improve the utilization efficiency of the thermal energy of the binary power generation system 10 as a whole. it can.

Here, the temperature of the first temperature fluid used as the heat source in the evaporator 3 is the temperature of the low boiling point medium (third temperature) after passing through the turbine T and before flowing into the first heat exchanger 6. Usually lower than. Therefore, if heat exchange is performed between the low boiling point medium before flowing into the evaporator 3 and the low boiling point medium having the third temperature, the temperature of the low boiling point medium before flowing into the evaporator 3 becomes the first temperature. May be higher than 1 temperature. In that case, the evaporator 3 cannot heat the low-boiling point medium using the fluid at the first temperature as a heat source (that is, it cannot effectively use the heat energy of the fluid at the first temperature). Therefore, the first heat exchanger 6 passes through the evaporator 3 and the low boiling point medium before flowing into the steam superheater 5 and the low boiling point after passing through the turbine T and before flowing into the condenser 9. It is necessary to be able to exchange heat with the medium.
The first heat exchanger 6 includes a low boiling point medium before passing through the evaporator 3 and flowing into the separator 4, and a low boiling point medium after passing through the turbine T and before flowing into the condenser 9. It is preferable to install at a position where heat can be exchanged between the two. Heat exchange between the low boiling point medium after passing through the separator 4 and before flowing into the steam superheater 5 and the low boiling point medium after passing through the turbine T and before flowing into the condenser 9 This is because the amount of low-boiling-point medium vapor separated in the separator 4 can be increased as compared with the case where the first heat exchanger 6 is installed at the position where the heat treatment is performed. As a result, the power generation amount in the generator 11 can be increased, and stable power generation can be achieved even when the temperature of the heat source used in the evaporator 3 changes over time, for example. .
The third temperature is likely to become higher than the first temperature as the difference between the first temperature and the second temperature is larger, particularly when the difference between the first temperature and the second temperature is 100 ° C. or more. The improvement in the utilization efficiency of heat energy by performing the heat exchange described above is remarkable.

  The second heat exchanger 7 flows into the evaporator 3 after passing through the first heat exchanger 6 and before flowing into the condenser 9 and after passing through the condenser 9. Heat exchange is performed with the previous low boiling point medium. In the binary power generation system 10 shown in FIG. 1, the second heat exchanger 7 has passed through the heater 2 and the low boiling point medium after passing through the first heat exchanger 6 and before flowing into the absorber 8. After that, heat exchange was performed with the low boiling point medium before flowing into the evaporator 3. Thus, by providing the 2nd heat exchanger 7, the thermal energy which the low boiling-point medium which passed through the 1st heat exchanger 6 is used effectively, and the utilization efficiency of the heat energy as the binary power generation system 10 whole is further increased. Can be improved.

  The absorber 8 rotates the rotating shaft of the turbine T, and mixes the low boiling point vapor after passing through the first heat exchanger 6 and the second heat exchanger 7 and the evaporation residual liquid separated by the separator 4. In this apparatus, a part of the low-boiling-point medium vapor is absorbed by the evaporation residual liquid. As the absorber 8, a known gas-liquid mixing device such as a line mixer or a spray tower can be used.

  The third heat exchanger 20 flows into the heater 2 after passing through the absorber 8 and before flowing into the condenser 9 and after being sent from the medium feed pump P1. Heat exchange with the previous low boiling point medium. In the binary power generation system 10, it is not essential to provide the third heat exchanger. Further, the temperature of the low boiling point medium after passing through the absorber 8 and before flowing into the condenser 9 is basically increased although there is a slight temperature increase due to the compression action by the medium liquid feeding pump P1. It is higher than the temperature of the low boiling point medium after being sent out from the liquid pump P1 and before flowing into the heater 2. For this reason, it is not indispensable to provide a valve or the like in the third heat exchanger flow path 19 and perform control similar to flow path change control related to the second heat exchanger described later. The binary power generation system 10 can be configured so that the low boiling point medium sent from P1 always passes through the third heat exchanger 20.

  The condenser 9 is a device that cools the mixed fluid of the low boiling point medium vapor and the evaporation residual liquid that has flowed out of the absorber 8 and condenses the low boiling point medium vapor. Then, after the low-boiling-point medium liquid obtained by condensing the low-boiling-point medium vapor in the condenser 9 (the mixture of the low-boiling-point medium vapor condensate and the evaporation residual liquid) is stored in the low-boiling point medium tank 1, The liquid is again sent to the evaporator 3 by the medium feed pump P1.

Here, the temperature of the low boiling point medium (fourth temperature) after passing through the first heat exchanger 6 and before flowing into the condenser 9 passed through the heater 2 in the second heat exchanger 7. The temperature of the low boiling point medium before flowing into the evaporator 3 can be raised when the temperature is higher than the temperature (fifth temperature) of the low boiling point medium after flowing into the evaporator 3 later. However, when the temperature of the heat source used in the evaporator 3 (first temperature) or the temperature of the heat source used in the steam superheater 5 (second temperature) changes over time, the fourth temperature is the fifth temperature. It can be lower than the temperature. And when 4th temperature becomes lower than 5th temperature, if the 2nd heat exchanger 7 is used, the low boiling point medium before flowing into the evaporator 3 will be cooled, and a binary electric power generation system The utilization efficiency of the heat energy as the whole 10 will fall.
Therefore, when the fourth temperature can be lower than the fifth temperature, the binary power generation system 10 includes a first temperature sensor 12, a second temperature sensor 13, a switching unit 14, and a bypass channel described below. 17 is preferably provided.

  The first temperature sensor 12 is configured to measure the temperature of the low boiling point medium after passing through the first heat exchanger 6 and before flowing into the second heat exchanger 7. The second temperature sensor 13 is configured to measure the temperature of the low boiling point medium after passing through the heater 2 and before flowing into the second heat exchanger 7.

  The switching unit 14 includes a first switching valve 14A and a second switching valve 14B. 14 A of 1st switching valves are arrange | positioned on the bypass channel 17 into which the low boiling-point medium which passed through the heater 2 flows in into the said evaporator 3 without passing through the 2nd heat exchanger 7. FIG. Specifically, the first switching valve 14 </ b> A is on the circulation system 15 at the rear stage of the heater 2, and is a second heat exchange for supplying a low boiling point medium flowing through the circulation system 15 to the second heat exchanger 7. The second heat exchanger flow path 18 is provided upstream of the position where the heat exchanger flow path 18 joins the circulation system 15. The second switching valve 14 </ b> B is provided on the second heat exchanger flow path 18 subsequent to the position where the second heat exchanger flow path 18 branches from the circulation system 15. That is, the first switching valve 14 </ b> A is arranged so that, when opened, the low boiling point medium that has passed through the heater 2 can flow into the evaporator 3 through the circulation system 15 without passing through the second heat exchanger 7. The second switching valve 14B is arranged so that the low boiling point medium that has passed through the heater 2 can flow into the second heat exchanger 7 when opened.

  Here, the binary power generation system 10 preferably further includes a control device (not shown) that controls the operation of the binary power generation system 10 using the first temperature sensor 12, the second temperature sensor 13, and the switching unit 14. Here, the operation of the binary power generation system 10 mainly refers to a change in the flow path of the low boiling point medium in the binary power generation system 10. Hereinafter, control by the control device will be described.

<Operation of binary power generation system>
A control device (not shown) controls the switching unit 14 based on the temperature measurement values of the first temperature sensor 12 and the second temperature sensor 13. Specifically, the control device, when the temperature measurement value (fourth temperature) of the first temperature sensor 12 is higher than the temperature measurement value (fifth temperature) of the second temperature sensor 13, the flow path of the low boiling point medium. Is switched to the second heat exchanger flow path 18 to the second heat exchanger 7, and the temperature measurement value (fourth temperature) of the first temperature sensor 12 is equal to or lower than the temperature measurement value (fifth temperature) of the second temperature sensor 13. In this case, the flow path of the low boiling point medium is switched to the bypass flow path 17. This is a case where a temperature change occurs in the heat source (that is, hot water or hot air) used in the evaporator 3 or the steam superheater 5 by changing the flow path of the low boiling point medium in the binary power generation system 10. However, the binary power generation system can be driven stably, and the utilization efficiency of thermal energy as the entire binary power generation system can be further improved.

  Specifically, when the temperature of the hot water used as the heat source in the evaporator 3 (first temperature) is constant and the temperature of the hot air used as the heat source in the steam superheater 5 (second temperature) decreases. In some cases, the measured temperature value of the first temperature sensor 12 may decrease and become lower than the measured temperature value of the second temperature sensor 13. In such a case, if the low boiling point medium that has passed through the heater 2 flows into the second heat exchanger 7, the low boiling point medium that has passed through the turbine T passes through the low boiling point medium supplied to the evaporator 3. In addition to not being able to achieve the original purpose of heat transfer of the heat energy it has, heat transfer in the opposite direction occurs. Then, thermal energy is lost from the low boiling point medium heated by the heater 2, and energy loss occurs in the binary power generation system 10. Therefore, when the temperature measurement value of the first temperature sensor 12 is lower than the temperature measurement value of the second temperature sensor 13, the control device opens the first switching valve 14A, closes the second switching valve 14B, 2 Control is performed so that the low boiling point medium flows into the evaporator 3 without passing through the heat exchanger 7. Conversely, when the measured temperature value of the first temperature sensor 12 is higher than the measured temperature value of the second temperature sensor 13, the control device closes the first switching valve 14 </ b> A and opens the second switching valve 14 </ b> B. 2 Control is performed so that the low boiling point medium flows into the heat exchanger 7.

  The binary power generation system of the present invention has been described above using an example. However, the binary power generation system of the present invention is not limited to the above example, and the binary power generation system of the present invention may be appropriately modified. it can.

  ADVANTAGE OF THE INVENTION According to this invention, the utilization efficiency of the thermal energy as the whole system can be improved, and the binary electric power generation system which can improve electric power generation efficiency can be provided.

DESCRIPTION OF SYMBOLS 1 Low boiling-point medium tank 2 Heater 3 Evaporator 4 Separator 5 Steam superheater 6 1st heat exchanger 7 2nd heat exchanger 8 Absorber 9 Condenser 10 Binary power generation system 11 Generator 12 1st temperature sensor 13 1st 2 temperature sensor 14 switching means 15 circulation system 16 evaporation residual liquid flow path 17 detour flow path 18 second heat exchanger flow path 19 third heat exchanger flow path 20 third heat exchanger P1 medium feed pump T turbine

Claims (2)

A binary power generation system that uses steam of a low boiling point medium as a working fluid,
An evaporator that heats a low boiling point medium to obtain a vapor of the low boiling point medium, a steam superheater that heats the steam of the low boiling point medium, and a kinetic energy of the steam of the low boiling point medium that has passed through the steam superheater And a condenser that condenses the vapor of the low-boiling-point medium in which a part of the kinetic energy is converted into the rotational energy of the rotating shaft in the turbine, and inside the low-boiling-point medium Has a closed loop circulation system that circulates
Between the low boiling point medium after passing through the evaporator and before flowing into the steam superheater, and the low boiling point medium after passing through the turbine and before flowing into the condenser further have a first heat exchanger for heat exchange,
The low boiling point medium after passing through the first heat exchanger and before flowing into the condenser; and the low boiling point medium after passing through the condenser and before flowing into the evaporator; A second heat exchanger for exchanging heat between the two,
A heater for heating the low boiling point medium after passing through the condenser and before flowing into the second heat exchanger;
A first temperature sensor for measuring the temperature of the low boiling point medium after passing through the first heat exchanger and before flowing into the second heat exchanger;
A second temperature sensor for measuring the temperature of the low boiling point medium after passing through the heater and before flowing into the second heat exchanger;
A bypass flow path for allowing the low boiling point medium that has passed through the heater to flow into the evaporator without passing through the second heat exchanger;
Switching means for switching the flow path through which the low-boiling-point medium after passing through the heater flows between the bypass flow path and the flow path to the second heat exchanger;
A control device that controls the switching unit based on temperature measurement values of the first and second temperature sensors, the temperature measurement value of the first temperature sensor being a temperature measurement value of the second temperature sensor. When higher than the value, switch to the flow path to the second heat exchanger, and switch to the bypass flow path when the temperature measurement value of the first temperature sensor is equal to or lower than the temperature measurement value of the second temperature sensor A control device;
A binary power generation system comprising: The first heat exchanger passes through the evaporator and after passing through the turbine, the low-boiling-point medium before flowing into the separator disposed between the evaporator and the steam superheater. 2. The binary power generation system according to claim 1 , wherein the binary power generation system is installed at a position where heat exchange with the low boiling point medium before flowing into the condenser is possible.

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