JP5675385B2 - Fuel preheating system, gas turbine power generation system, and fuel preheating method - Google Patents

Description

  The present invention relates to a fuel preheating system, a gas turbine power generation system, and a fuel preheating method for preheating fuel supplied to a combustor for driving a gas turbine.

  The fuel supplied to the gas turbine is heated before being supplied to the gas turbine in order to increase combustion efficiency. Conventionally, there has been a technique for heating fuel in a fuel heater using one or more water streams from each section of an exhaust heat recovery boiler (HRSG).

  Patent Documents 1 and 2 disclose a technique in which a water heater assembly is separately provided and the fuel is heated before being supplied to the gas turbine. In this technique, water or steam is extracted from one or more sections of the exhaust heat recovery boiler and sent to a water heater assembly. Then, water for fuel heating is led from the water heater assembly to the fuel heater. As a result, the fuel supplied to the gas turbine receives heat from the water for fuel heating by the fuel heater, and the heated fuel is sent to the combustor. On the other hand, the cooled water for heating the fuel is sent to the condenser.

JP 2010-38162 A JP 2010-38163 A

  However, in the technique of heating the fuel in the fuel heater using one or more water streams from each section of a conventional exhaust heat recovery boiler (HRSG), the amount of heat applied to the fuel from the fuel heater is limited.

  In the techniques of Patent Documents 1 and 2, it is necessary to provide a water heater assembly in addition to the gas turbine and the exhaust heat recovery boiler. For this reason, there is a problem that the addition of equipment is expensive and the structure of the entire system becomes complicated.

  The present invention has been made in view of such circumstances, and a fuel preheating system and a fuel preheating method capable of efficiently heating fuel supplied to a combustor for driving a gas turbine with a simple structure. The purpose is to provide.

In order to solve the above problems, the fuel preheating system, gas turbine power generation system, and fuel preheating method of the present invention employ the following means.
That is, the fuel preheating system according to the present invention includes a first heat exchange unit provided in an exhaust heat recovery boiler that recovers heat of exhaust gas from a gas turbine driven by a high-temperature gas generated by combustion of fuel in a combustor. Unlike the second heat exchange section provided in the fuel supply path for supplying fuel to the combustor and the water supplied to the exhaust heat recovery boiler and exchanging heat with the heat of the exhaust gas, the first heat exchange section After being discharged, the heat medium supplied to the second heat exchange unit flows , and includes a first heat exchange unit and a medium flow path that is a closed loop in which the heat medium circulates through the second heat exchange unit , The medium is heated by the heat of the exhaust gas in the first heat exchange unit, and heats the fuel flowing through the fuel supply path in the second heat exchange unit.

The combustor generates hot gas by burning the supplied fuel, and supplies the hot gas to the gas turbine. The gas turbine is driven by hot gas supplied from a combustor. At this time, if the gas turbine is connected to the generator, the power generation by the power of the gas turbine can be performed. The exhaust heat recovery boiler recovers the heat of the exhaust gas discharged from the gas turbine. The exhaust heat recovery boiler is provided with a first heat exchange unit. The heat recovery steam generator may be provided with a heat transfer tube separately from the first heat exchange unit, change water into steam, and supply the steam to the steam turbine.
The fuel supply path is a flow path for supplying fuel to the combustor. A second heat exchange unit is provided in the fuel supply path.

  The medium flow path is formed such that the heat medium flows by being connected to the first heat exchange unit and the second heat exchange unit. Then, the heat medium is heated by the heat of the exhaust gas in the first heat exchange unit, and the high-temperature heat medium is discharged from the first heat exchange unit. Thereafter, the heat medium is supplied to the second heat exchange unit, and the heat of the high-temperature heat medium is used by the second heat exchange unit to heat the fuel flowing through the fuel supply path. As a result, the fuel is heated before being supplied to the combustor, and the combustion efficiency of the gas turbine can be improved.

In the above invention, the medium flow path includes the heat medium outlet in the first heat exchange unit, the heat medium inlet in the second heat exchange unit, the heat medium outlet in the second heat exchange unit, and the first heat exchange. The medium flow path may be provided so that the height decreases in the order of the inlet of the heat medium in the section.

  According to this invention, since the medium flow path is a closed loop and has a height difference, the heat medium is heated and raised in the first heat exchanging section provided in the exhaust heat recovery boiler, and enters the fuel supply path. It cools and falls in the 2nd heat exchange part provided. At this time, since the heat medium circulates due to the temperature difference, the external force of the pump or the like can be greatly reduced, and the fuel supply path can be circulated without naturally using the external force of the pump or the like under a predetermined condition. The fuel passing through can be heated.

  A gas turbine power generation system according to the present invention is driven by the fuel preheating system, a combustor to which fuel preheated by the fuel preheating system is supplied, and a high-temperature gas generated by combustion of fuel in the combustor. A gas turbine and a generator that generates electric power by the rotational output of the gas turbine are provided.

  According to this invention, the fuel preheating system preheats the fuel supplied to the combustor, the combustor burns the preheated fuel to generate hot gas, the gas turbine is driven by the hot gas, and the generator Power is generated by the rotational output of the gas turbine. Therefore, the preheated fuel is supplied to the combustor, and the combustion efficiency of the gas turbine can be improved.

Further, the fuel preheating method according to the present invention is a first heat exchange unit provided in an exhaust heat recovery boiler that recovers heat of exhaust gas from a gas turbine driven by high-temperature gas generated by combustion of fuel in a combustor. , A heat medium different from the water supplied to the exhaust heat recovery boiler and exchanging heat with the exhaust gas is heated by the heat of the exhaust gas, and the heat medium heated in the first heat exchange unit is transferred from the first heat exchange unit. The heat medium discharged and discharged from the first heat exchange unit is supplied to a second heat exchange unit provided in a fuel supply path for supplying fuel to the combustor, and the second heat exchange unit The fuel flowing through the fuel supply path is heated by the medium, and the heat medium circulates in a closed loop between the first heat exchange unit and the second heat exchange unit .

  According to this invention, the first heat exchange unit is provided in the exhaust heat recovery boiler, and the heat medium is heated by the heat of the exhaust gas in the first heat exchange unit. And the heated heat medium is discharged | emitted from a 1st heat exchange part, and is supplied to a 2nd heat exchange part. The second heat exchange unit is provided in a fuel supply path that supplies fuel to the combustor, and the fuel that flows through the fuel supply path is heated by the heat medium that flows through the second heat exchange unit. As a result, the fuel is heated before being supplied to the combustor, and the combustion efficiency of the gas turbine can be improved.

  According to the present invention, the fuel supplied to the combustor for driving the gas turbine can be efficiently heated with a simple structure.

It is the schematic which shows the gas turbine combined cycle (GTCC) power generation system of this invention. It is the schematic which shows the fuel preheating system of this invention. It is a graph which shows the relationship between fuel preheating rise temperature [degreeC] and the height difference [m] from the upper end of a medium flow path which is a closed circuit to a lower end.

Embodiments according to the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic diagram showing a gas turbine combined cycle (GTCC) power generation system 1 of the present invention.
The power generation system 1 of the present invention includes a gas turbine power generation system 10, a steam turbine power generation system 20, an exhaust heat recovery boiler 30, a fuel preheating system 2, and the like. The power generation system 1 generates power using the gas turbine 12 and then rotates the steam turbine 21 with steam generated by using the exhaust heat from the gas turbine 12 to generate power again. Further, the fuel supplied to the combustor 13 of the gas turbine power generation system 10 is preheated by the fuel preheating system 2. Here, the fuel is, for example, LNG vaporized gas.

  The gas turbine power generation system 10 includes a compressor 11, a gas turbine 12, a combustor 13, a generator 14, and the like. The gas turbine power generation system 10 generates power by driving the gas turbine 12.

  The compressor 11 is driven by the rotational driving force of the gas turbine 12 being transmitted. The compressor 11 sucks ambient air and continuously compresses the air, and sends the compressed air to the combustor 13.

  The gas turbine 12 is driven to rotate by being supplied with hot gas from the combustor 13 and expanding the hot gas. The gas turbine 12 exhausts exhaust gas, and the exhaust gas is supplied to the exhaust heat recovery boiler 30. The outlet temperature of the exhaust gas from the gas turbine 12 is, for example, 550 to 600 ° C. The gas turbine 12 is directly connected to the compressor 11 at one end side and directly connected to the generator 14 at the other end side.

  The combustor 13 is supplied with air from the compressor 11 and supplied with fuel from the fuel supply path 50 to burn the fuel and generate high-temperature gas. The combustor 13 supplies the generated high temperature gas to the gas turbine 12. The fuel supply path 50 is a pipe connecting the fuel supply source and the combustor 13, and the fuel flows from the fuel supply source to the combustor 13. A second heat exchange unit 6 is provided in the fuel supply path 50.

  The generator 14 receives the rotational driving force of the gas turbine 12 and outputs electric power by the driving force. The electric power obtained by the generator 14 is supplied to the power system via a power line (not shown).

  The exhaust heat recovery boiler 30 is supplied with exhaust gas from the gas turbine 12 and exhausts the exhaust gas to an exhaust cylinder (not shown). The exhaust heat recovery boiler 30 recovers the heat of the exhaust gas discharged from the gas turbine 12. For example, the exhaust heat recovery boiler 30 is provided with the first heat exchange unit 4 that constitutes a part of the medium flow path. The exhaust gas passing through the exhaust heat recovery boiler 30 exchanges heat with the heat medium flowing through the medium flow path in the first heat exchange unit 4. The exhaust heat recovery boiler 30 is provided with a heat transfer tube 25 that constitutes a part of the flow path of the steam turbine power generation system 20. The exhaust gas passing through the exhaust heat recovery boiler 30 exchanges heat with water or steam flowing through the circulation flow path of the steam turbine power generation system 20 in the heat transfer pipe 25.

  The steam turbine power generation system 20 includes a steam turbine 21, a power generator 22, a condenser 23, a feed water pump 24, an exhaust heat recovery boiler 30, and the like. The steam turbine power generation system 20 generates power by driving the steam turbine 21. The steam turbine power generation system 20 has a closed circuit circulation channel, and steam or water is circulated in the circulation channel by a feed water pump 24.

  The steam turbine 21 is rotationally driven by a heat drop (enthalpy drop) of steam generated in a heat transfer tube 25 provided in the exhaust heat recovery boiler 30. A generator 22 is connected to the steam turbine 21. The rotational driving force of the steam turbine 21 is transmitted to the generator 22, and electric power is obtained by the generator 22. The electric power obtained by the generator 22 is supplied to the power system via a power line (not shown).

  The condenser 23 cools the steam with cooling water and condensates it. The water generated by condensing and liquefying is sent to the exhaust heat recovery boiler 30 by the water supply pump 24.

Next, the fuel preheating system 2 of the present invention will be described with reference to FIG. FIG. 2 is a schematic view showing the fuel preheating system 2 of the present invention.
The fuel preheating system 2 has a closed circuit medium flow path through which a heat medium flows, and is provided with a first heat exchange unit 4 and a second heat exchange unit 6. The 1st heat exchange part 4 and the 2nd heat exchange part 6 are comprised by the heat exchanger tube group which consists of a some heat exchanger tube, respectively.

  The first heat exchange unit 4 is provided in the exhaust heat recovery boiler 30. The heat medium flowing in the heat transfer tube of the first heat exchange unit 4 exchanges heat with the exhaust gas flowing in the exhaust heat recovery boiler 30, and the heat medium is heated. The second heat exchange unit 6 is provided in the fuel supply path 50 through which the fuel flows. The heat medium flowing in the heat transfer tube of the second heat exchange unit 6 exchanges heat with the fuel flowing in the fuel supply path 50, and the heat medium is cooled.

  The pipe 3 is a flow that connects an opening (heat medium outlet) below the heat transfer tube of the second heat exchange unit 6 and an opening (heat medium inlet) below the heat transfer tube of the first heat exchange unit 4. The heat medium flows from the second heat exchange unit 6 to the first heat exchange unit 4. The pipe 5 is a flow connecting an opening (heat medium outlet) above the heat transfer tube of the first heat exchange unit 4 and an opening (heat medium inlet) above the heat transfer tube of the second heat exchange unit 6. The heat medium flows from the first heat exchange unit 4 to the second heat exchange unit 6.

The medium flow path is configured by the first heat exchange unit 4, the second heat exchange unit 6, and the pipes 3 and 5, and the heat medium circulates in the medium flow path. The heat medium is, for example, gas (air, carbon dioxide, etc.), oil or organic solvent (silicon oil, Dowsum A, ethylene glycol, etc.), molten salt (NaNO ₂ , LiNO ₃ , NaNO ₃ , KNO ₃ , NaOH, KOH , LiCl, NaCl, KCl, Li 2 CO 3, Na 2 CO 3, K 2 CO 3, NaNO 3 -KNO 3, HTS: NaNO 3 -KNO 3 -NaNO 2, LiF-BeF 2, LiF-NaF-KF, LiF-BeF ₂ -ThF ₄ -UF ₄ etc.) can be used. As the heat medium, oil-based ones are suitable when used in a low temperature range (for example, normal temperature to 350 ° C.), and molten salts are suitable when used at a high temperature (for example, 450 ° C. or higher). This is because the heat transfer medium has a large heat transfer coefficient and heat capacity in these temperature ranges.

  Further, the closed circuit of the medium flow path is arranged with a height difference as shown in FIG. 2, so that the internal heat medium is heated and raised in the first heat exchanging unit 4 on the exhaust heat recovery boiler 30 side. Then, the second heat exchange section 6 on the fuel supply path 50 side is cooled and descends. Here, the first heat exchange unit 4 and the second heat exchange unit 6 are provided meandering along the height direction. The pipes 3 and 5 are provided horizontally. The pipes 3 and 5 may be provided to be inclined with respect to the horizontal direction, but the outlet of the heat medium in the first heat exchange unit 4, the inlet of the heat medium in the second heat exchange unit 6, the second The medium flow path is provided so that the height decreases in the order of the outlet of the heat medium in the heat exchanger 6 and the inlet of the heat medium in the first heat exchanger 4.

  At this time, since the heat medium circulates due to the temperature difference, the external force of the pump or the like can be greatly reduced. Under the predetermined conditions, the heat medium is naturally circulated without using the external force of the pump or the like, and the second The fuel passing through the fuel supply path 50 can be heated by the heat exchange unit 6.

Next, the operation of the fuel preheating system 2 of the present invention will be described.
First, when the exhaust gas from the gas turbine 12 is supplied to the exhaust heat recovery boiler 30, the exhaust gas exchanges heat with the heat medium flowing through the first heat exchange unit 4 in the medium flow path. As a result, in the exhaust heat recovery boiler 30, the exhaust gas is cooled and the heat medium is heated. And since the specific gravity of a heat medium becomes small, the inside of the heat exchanger tube of the 1st heat exchange part 4 raises.

  On the other hand, in the fuel supply path 50 through which the fuel supplied to the combustor 13 flows, the fuel exchanges heat with the heat medium flowing through the second heat exchange unit 6 of the medium flow path. As a result, the fuel is heated by the second heat exchange unit 6. Therefore, since the temperature of the fuel rises before being supplied to the combustor 13, the combustion efficiency of the gas turbine power generation system 10 can be improved. Moreover, in the 2nd heat exchange part 6, since a heat medium is cooled and specific gravity becomes large, it falls in the inside of a heat exchanger tube.

  From the above, due to the density difference of the heat medium, the heat medium flows in the pipe 3 from the lower opening of the second heat exchange unit 6 to the lower opening of the first heat exchange unit 4 and flows into the pipe 5. Then, it flows from the upper opening of the first heat exchange unit 4 to the upper opening of the second heat exchange unit 6. As a result, the heat medium circulates in the medium flow path in the order of the pipe 3, the first heat exchange unit 4, the pipe 5, and the second heat exchange unit 6. Under a predetermined condition, the fuel passing through the fuel supply path 50 can be heated by the second heat exchange unit 6 while naturally circulating the heat medium without using an external force such as a pump.

  Next, as an example of the fuel preheating system 2 of the present invention, the examination result of the fuel preheating rising temperature when the heat medium circulating in the medium flow path is dowsum A will be described using FIG. FIG. 3 is a graph showing the relationship between the fuel preheating rising temperature [° C.] and the height difference [m] from the upper end to the lower end of the medium flow path which is a closed circuit.

  The graph of FIG. 3 is a result of calculating how much the temperature increase of the fuel preheating becomes the parameter using the height difference of the medium flow path as a parameter. The driving force for circulating the heat medium through the medium flow path is calculated based on the density difference caused by the temperature difference of the heat medium and the height difference of the medium flow path. Further, the temperature difference (density difference) of the heat medium between the high temperature side and the low temperature side of the medium flow path is constant.

  As a calculation method, first, a closed-circuit medium flow path having the shape shown in FIG. 2, the first heat exchange unit 4, and the second heat exchange unit 6 are assumed, and the inside of the medium flow path by the driving force described above is assumed. The circulation flow rate of the heat medium is calculated. Next, the heat exchange amount is calculated based on the calculated circulation flow rate and the set temperature difference. Finally, the fuel temperature rise corresponding to the heat exchange amount is calculated based on the predetermined fuel gas flow rate.

  As shown in FIG. 3, it can be seen that the higher the difference in the height of the medium flow path, the larger the temperature rise in fuel preheating. Further, in the case of FIG. 3, it is possible to preheat the fuel by 50 ° C. or more by securing a height difference of 3 m in the medium flow path.

As mentioned above, according to this invention, since the fuel supplied to a combustor can be heated previously, the combustion efficiency of a gas turbine power generation system can be improved. Further, by appropriately arranging the medium flow path, the heat medium flowing through the closed medium flow path circulates due to a temperature difference (density difference). The external force of the pump or the like can be greatly reduced, and the fuel passing through the fuel supply path can be heated while naturally circulating the heat medium without using the external force of the pump or the like under a predetermined condition.
It is possible to optimize the fuel preheating system by selecting a heat medium suitable for the performance and operating conditions of the gas turbine combined cycle (GTCC) power generation system.

  In the above description, the case where the fuel of the gas turbine is natural gas (LNG) has been described, but the present invention is not limited to this example. The gas turbine fuel may be oil such as light oil. In the above description, the case where the present invention is applied to a gas turbine combined cycle (GTCC) power generation system has been described. However, the present invention does not include a steam turbine power generation system, and includes a gas turbine power generation system and an exhaust heat recovery boiler. It can also be applied to the system. Furthermore, in the above description, the GTCC power generation system in which the generator is directly connected to each of the gas turbine and the steam turbine has been described. However, the present invention is not limited to this example, and the generator is shared, and the gas turbine, the steam turbine, The present invention can also be applied to a GTCC power generation system in which the machines are directly connected.

1 Gas turbine combined cycle power generation system 2 Fuel preheating system 3, 5 Piping (medium flow path)
4 1st heat exchange part 6 2nd heat exchange part 10 Gas turbine power generation system 11 Compressor 12 Gas turbine 13 Combustor 14,22 Generator 20 Steam turbine power generation system 21 Steam turbine 23 Condenser 24 Feed water pump 25 Transmission Heat pipe 30 Waste heat recovery boiler 50 Fuel supply path

Claims (4)

A first heat exchange unit provided in an exhaust heat recovery boiler that recovers heat of exhaust gas from a gas turbine driven by high-temperature gas generated by combustion of fuel in a combustor;
A second heat exchange section provided in a fuel supply path for supplying the fuel to the combustor;
Unlike water that is supplied to the exhaust heat recovery boiler and exchanges heat with the heat of the exhaust gas, after being discharged from the first heat exchange unit, a heat medium supplied to the second heat exchange unit flows , A medium flow path that is a closed loop in which the heat medium circulates through the first heat exchange section and the second heat exchange section ;
With
The fuel preheating system, wherein the heat medium is heated by the heat of the exhaust gas in the first heat exchange unit, and the fuel flowing in the fuel supply path is heated in the second heat exchange unit. The medium flow path, prior Symbol outlet of the heat medium in the first heat exchanger, the inlet of the heat medium in the second heat exchange portion, an outlet of the heat medium in the second heat exchange section, the 2. The fuel preheating system according to claim 1, wherein the medium flow path is provided in such a manner that a height thereof decreases in order of an inlet of the heat medium in the first heat exchange unit. A fuel preheating system according to claim 1 or 2,
A combustor supplied with fuel preheated by the fuel preheating system;
A gas turbine driven by hot gas generated by combustion of the fuel in the combustor;
A generator for generating electricity by the rotational output of the gas turbine;
A gas turbine power generation system comprising: In a first heat exchange section provided in an exhaust heat recovery boiler that recovers heat of exhaust gas from a gas turbine driven by high-temperature gas generated by combustion of fuel in a combustor, the exhaust heat recovery boiler is supplied with the Heating the heat medium different from the water that exchanges heat with the heat of the exhaust gas by the heat of the exhaust gas ,
Discharging the heat medium heated in the first heat exchange section from the first heat exchange section;
Supplying the heat medium discharged from the first heat exchange unit to a second heat exchange unit provided in a fuel supply path for supplying the fuel to the combustor;
In the second heat exchange unit, the fuel flowing through the fuel supply path is heated by the heat medium ,
The fuel preheating method , wherein the heat medium circulates in a closed loop between the first heat exchange unit and the second heat exchange unit .

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