JP6266361B2 - Fuel supply device, combustor, gas turbine, and fuel supply method - Google Patents

Description

  The present invention relates to a fuel supply device, a combustor, a gas turbine, and a fuel supply method.

  The gas turbine is driven by a compressor that compresses combustion air, a combustor that injects and burns fuel into the compressed air supplied from the compressor, and a combustion gas that is generated from the combustor. And a fuel supply device that supplies fuel to the combustor.

  Natural gas is often used as a fuel in a gas turbine of a power plant. From the viewpoint of the supply situation and economic efficiency of natural gas, a mixed gas in which natural gas and other gas (for example, hydrogen gas, propane gas, butane gas, etc.) are mixed may be used as fuel. An example of a technology related to a gas turbine driven by a fuel blend in which two or more kinds of fuels are mixed is disclosed in Patent Document 1.

JP 2010-156324 A

  When the property of the fuel supplied from the fuel supply device to the combustor changes, for example, pressure fluctuation (combustion vibration) may occur inside the combustor. When combustion vibration occurs, combustion may become unstable, and the combustor and turbine components may deteriorate. As a result, the performance of the combustor and gas turbine may be degraded.

  An object of this invention is to provide the fuel supply apparatus and fuel supply method which can suppress the fall of the performance of a combustor and a gas turbine. Another object of the present invention is to provide a combustor and a gas turbine in which deterioration in performance is suppressed.

  A first aspect of the present invention is a fuel supply device that supplies a mixed fuel of a first fuel and a second fuel to a combustor of a gas turbine, wherein a mixing ratio of the first fuel and the second fuel is set. A mixing ratio setting section to be set, a mixing section in which the first fuel and the second fuel are mixed at the set mixing ratio, and a low heating value and specific gravity of the first fuel. Based on the characteristic information, the characteristic information of the second fuel including the lower calorific value and specific gravity of the second fuel, and the mixing ratio set by the mixing ratio setting unit, the mixing fuel of the mixing ratio is determined. A temperature setting unit that sets a target temperature of the mixed fuel supplied to the combustor so that a modified Wobbe index becomes a target value, and the combustor based on the target temperature set by the temperature setting unit The temperature of the mixed fuel supplied to the To provide a fuel supply device and a temperature adjustment device for integer.

  The second aspect of the present invention provides a combustor to which the mixed fuel is supplied from the fuel supply device of the first aspect.

  According to a third aspect of the present invention, there is provided a gas turbine comprising the fuel supply device of the first aspect and a combustor to which the mixed fuel is supplied from the fuel supply device.

  A fourth aspect of the present invention is a fuel supply method for supplying a mixed fuel of a first fuel and a second fuel to a combustor of a gas turbine, wherein a mixing ratio of the first fuel and the second fuel is set. Setting, mixing the first fuel and the second fuel at the set mixing ratio, characteristic information of the first fuel including a lower heating value and specific gravity of the first fuel, and Based on the characteristic information of the second fuel including the lower calorific value and specific gravity of the second fuel and the mixing ratio set by the mixing ratio setting unit, the modified wobbe index of the mixed fuel at the mixing ratio is the target The target temperature of the mixed fuel supplied to the combustor is set so as to be a value, and the temperature of the mixed fuel supplied to the combustor is adjusted based on the set target temperature And a fuel supply method including Subjected to.

  ADVANTAGE OF THE INVENTION According to this invention, the fall of the performance of a combustor and a gas turbine can be suppressed.

FIG. 1 is a diagram illustrating an example of a gas turbine according to the first embodiment. FIG. 2 is a schematic diagram illustrating an example of a fuel supply apparatus according to the first embodiment. FIG. 3 is a functional block diagram illustrating an example of the fuel supply apparatus according to the first embodiment. FIG. 4 is a flowchart illustrating an example of a fuel supply method according to the first embodiment. FIG. 5 is a diagram illustrating an example of the relationship between the fuel mixture ratio and time according to the first embodiment. FIG. 6 is a diagram illustrating an example of the relationship between the temperature and time of the fuel according to the first embodiment. FIG. 7 is a diagram illustrating an example of the relationship between the modified Wobbe index of fuel and time according to the first embodiment. FIG. 8 is a functional block diagram illustrating an example of a fuel supply device according to the second embodiment. FIG. 9 is a diagram illustrating an example of the relationship between fuel temperature and time. FIG. 10 is a diagram illustrating an example of the relationship between the fuel modified Wobbe index and time. FIG. 11 is a diagram illustrating an example of the relationship between the fuel mixture ratio and time according to the second embodiment. FIG. 12 is a diagram illustrating an example of the relationship between the modified Wobbe index of fuel and time according to the second embodiment. FIG. 13 is a diagram illustrating an example of the relationship between the fuel mixture ratio and the fuel temperature according to the third embodiment. FIG. 14 is a diagram illustrating an example of the relationship between the temperature of the fuel and time according to the fourth embodiment. FIG. 15 is a schematic diagram illustrating an example of a fuel supply apparatus according to the fourth embodiment.

  Hereinafter, embodiments according to the present invention will be described with reference to the drawings, but the present invention is not limited thereto. The components in the embodiments described below can be appropriately combined. Some components may not be used.

<First Embodiment>
A first embodiment will be described. FIG. 1 is a diagram illustrating an example of a gas turbine 1 according to the present embodiment. As shown in FIG. 1, a gas turbine 1 includes a compressor 2 that compresses combustion air, and a combustor 3 that generates combustion gas by injecting fuel into the compressed air supplied from the compressor 2 and burning the fuel. A turbine 4 driven by combustion gas supplied from the combustor 3 and a fuel supply device 10 for supplying fuel to the combustor 3 are provided.

  The turbine 4 includes a rotor 6 having moving blades 5 and a stator 8 having stationary blades 7 disposed around the rotor 6. The rotor 6 rotates about the rotation axis AX. The moving blade 5 is provided on the rotor shaft of the turbine 4. The moving blades 5 are arranged in a plurality of stages in the axial direction. The stationary blade 7 is provided in the casing of the stator 8. The stationary blades 7 are arranged in a plurality of stages in the axial direction. With respect to the axial direction, the moving blades 5 (moving blade rows) and the stationary blades 7 (static blade rows) are alternately arranged.

  Next, an example of the fuel supply apparatus 10 according to the present embodiment will be described. FIG. 2 is a schematic diagram illustrating an example of the fuel supply apparatus 10 according to the present embodiment. In the present embodiment, the fuel supply device 10 supplies the mixed fuel Gm of the first fuel G1 and the second fuel G2 to the combustor 3 of the gas turbine 1. The mixed fuel Gm is supplied from the fuel supply device 10 to the combustor 3. The combustor 3 generates combustion gas by injecting and burning the mixed fuel Gm into the compressed air supplied from the compressor 2.

  Each of the first fuel G1 and the second fuel G2 is a gas (gaseous fuel). The mixed fuel Gm is also a gas (gaseous fuel). In the present embodiment, the first fuel G1 is natural gas. The second fuel G2 is a gas having a different property from the first fuel G1. The second fuel G2 includes at least one of hydrogen gas, ethane gas, propane gas, and butane gas. Note that the second fuel G2 may include an inert gas such as nitrogen gas and carbon dioxide gas.

  As shown in FIG. 2, the fuel supply device 10 includes a first fuel supply device 11 that supplies the first fuel G1, a second fuel supply device 12 that supplies the second fuel G2, a first fuel G1, and a second fuel. The mixing unit 15 in which the fuel G2 is mixed, the temperature adjusting device 16 that adjusts the temperature of the mixed fuel Gm of the first fuel G1 and the second fuel G2 generated by the mixing unit 15, and the temperature adjusting device 16 A temperature sensor 17 for detecting the temperature of the adjusted mixed fuel Gm, a first supply amount adjusting device 13 for adjusting the supply amount of the first fuel G1 supplied from the first fuel supply device 11 to the mixing unit 15, and a first 2 a second supply amount adjusting device 14 for adjusting the supply amount of the second fuel G2 supplied from the fuel supply device 12 to the mixing unit 15, and a pressure adjusting valve for adjusting the pressure of the mixed fuel Gm supplied to the combustor 3. 18 and the mixed fuel Gm supplied to the combustor 3 The supply amount adjusting valve 19 for adjusting the supply amount, a control unit 20 for controlling the fuel supply device 10, and a.

  The first fuel supply device 11 can deliver the first fuel G1. The first fuel supply device 11 and the mixing unit 15 are connected via a pipe 41. The first fuel G <b> 1 delivered from the first fuel supply device 11 is supplied to the mixing unit 15 via the pipe 41.

  The second fuel supply device 12 can deliver the second fuel G2. The second fuel supply device 12 and the mixing unit 15 are connected via a pipe 42. The second fuel G2 sent from the second fuel supply device 12 is supplied to the mixing unit 15 via the pipe 42.

  The first supply amount adjusting device 13 adjusts the supply amount of the first fuel G1 per unit time supplied from the first fuel supply device 11 to the mixing unit 15. The first supply amount adjusting device 13 is disposed in the pipe 41. The first supply amount adjusting device 13 includes a valve mechanism, and adjusts the supply amount of the first fuel G1 by adjusting the opening degree of the valve mechanism (or the opening ratio P of the flow path of the pipe 41). The first supply amount adjusting device 13 is controlled by the control device 20. The first fuel G1 sent from the first fuel supply device 11 is supplied to the mixing unit 15 via the first supply amount adjusting device 13.

  The second supply amount adjusting device 14 adjusts the supply amount of the second fuel G2 per unit time supplied from the second fuel supply device 12 to the mixing unit 15. The second supply amount adjusting device 14 is disposed in the pipe 42. The second supply amount adjusting device 14 includes a valve mechanism, and adjusts the supply amount of the second fuel G2 by adjusting the opening degree of the valve mechanism (or the opening ratio Q of the flow path of the pipe 42). The second supply amount adjusting device 14 is controlled by the control device 20. The second fuel G2 sent from the second fuel supply device 12 is supplied to the mixing unit 15 via the second supply amount adjusting device 14.

  The mixing unit 15 mixes the first fuel G1 and the second fuel G2. In the mixing unit 15, a mixed fuel Gm of the first fuel G1 and the second fuel G2 is generated. The mixed fuel Gm generated in the mixing unit 15 is supplied to the combustor 3 via the pipe 43.

  The temperature adjusting device 16 adjusts the temperature of the mixed fuel Gm generated in the mixing unit 15 and supplied to the combustor 3. The temperature adjustment device 16 is disposed in the pipe 43. The temperature adjustment device 16 includes a heating device and a cooling device. The temperature adjustment device 16 is controlled by the control device 20. The temperature adjusting device 16 adjusts the temperature of the mixed fuel Gm generated by the mixing unit 15 so that the temperature of the mixed fuel Gm becomes the target temperature.

  The temperature sensor 17 detects the temperature of the mixed fuel Gm whose temperature has been adjusted by the temperature adjusting device 16. The temperature sensor 17 detects the temperature of the mixed fuel Gm flowing through the pipe 43. A detection signal of the temperature sensor 17 is output to the control device 20. The control device 20 controls the temperature adjustment device 16 based on the detection value of the temperature sensor 17.

  The control device 20 executes various processes related to fuel supply. The control device 20 includes a CPU (Central Processing Unit), and executes various processes including arithmetic processing related to fuel supply and signal processing. The control device 20 includes a storage unit that stores various types of information related to fuel supply. The storage unit includes at least one of a random access memory (RAM), a read only memory (ROM), a flash memory, and a hard disk drive.

  FIG. 3 is a functional block diagram illustrating an example of the fuel supply apparatus 10 according to the present embodiment. As shown in FIG. 3, the control device 20 includes a mixing ratio setting unit 21 that sets a mixing ratio of the first fuel G1 and the second fuel G2, and a first fuel database (characteristic information of the first fuel G1). (First storage unit) 22, a second fuel database (second storage unit) 23 that stores characteristic information of the second fuel G2, a calculation unit 24 that calculates characteristic information of the mixed fuel Gm, and a combustor 3 And a temperature setting unit 25 for setting a target temperature Tr of the mixed fuel Gm to be provided.

  The mixing ratio setting unit 21 sets the mixing ratio of the first fuel G1 and the second fuel G2. In the present embodiment, the input device 50 is connected to the control device 20. The input device 50 includes at least one of a keyboard and a touch panel, for example, and is operated by an operator. Information regarding the mixture ratio is input to the control device 20 by the operator via the input device 50. An input signal generated by operating the input device 50 is input to the mixing ratio setting unit 21. The mixing ratio setting unit 21 sets the mixing ratio of the first fuel G1 and the second fuel G2 based on the input signal from the input device 50.

  Based on the mixing ratio set by the mixing ratio setting unit 21, the first supply amount adjusting device 13 and the second supply amount adjusting device 14 are controlled. The first supply amount adjusting device 13 adjusts the supply amount (supply amount per unit time) of the first fuel G <b> 1 supplied to the mixing unit 15 based on the mixing ratio set by the mixing ratio setting unit 21. The second supply amount adjusting device 14 adjusts the supply amount (supply amount per unit time) of the second fuel G2 supplied to the mixing unit 15 based on the mixing ratio set by the mixing ratio setting unit 21. The control device 20 adjusts the first supply amount so that the mixing ratio of the first fuel G1 and the second fuel G2 of the mixed fuel Gm generated in the mixing unit 15 becomes the mixing ratio set by the mixing ratio setting unit 21. The device 13 and the second supply amount adjusting device 14 are controlled. The first fuel G1 and the second fuel G2 are mixed in the mixing unit 15 at the mixing ratio set by the mixing ratio setting unit 21.

  The first fuel database 22 stores characteristic information of the first fuel G1. The characteristic information of the first fuel G1 includes the lower heating value LHV1 of the first fuel G1 and the specific gravity d1 of the first fuel G1. The second fuel database 23 stores characteristic information of the second fuel G2. The characteristic information of the second fuel G2 includes the lower heating value LHV2 of the second fuel G2 and the specific gravity d2 of the second fuel G2. The characteristic information of the first fuel G1 and the characteristic information of the second fuel G2 are known information measured in advance.

  The calculation unit 24 calculates characteristic information of the mixed fuel Gm. The characteristic information of the mixed fuel Gm includes the lower heating value LHVm of the mixed fuel Gm and the specific gravity dm of the mixed fuel Gm. The arithmetic unit 24 is set by the characteristic information of the first fuel G1 stored in the first fuel database 22, the characteristic information of the second fuel G2 stored in the second fuel database 23, and the mixing ratio setting unit 21. Based on the mixed ratio, the characteristic information of the mixed fuel Gm is calculated.

  For example, when the mixing ratio of the first fuel G1 and the second fuel G2 is k1: k2, the lower heating value LHVm of the mixed fuel Gm and the specific gravity dm of the mixed fuel Gm are expressed by the following equations (1) and (2 ) Is calculated based on the equation.

  The temperature setting unit 25 is a mixture set by the mixing ratio setting unit 21 based on the characteristic information of the first fuel G1, the characteristic information of the second fuel G2, and the mixing ratio set by the mixing ratio setting unit 21. The target temperature Tr of the mixed fuel Gm supplied to the combustor 3 is set so that the modified Wobbe index MWI of the mixed fuel Gm mixed at the ratio becomes the target value MWIr. In the present embodiment, the temperature setting unit 25 is a mixture calculated by the calculation unit 24 based on the characteristic information of the first fuel G1, the characteristic information of the second fuel G2, and the mixing ratio set by the mixing ratio setting unit 21. Based on the characteristic information of the fuel Gm, the target temperature Tr of the mixed fuel Gm is set so that the modified Wobbe index MWI of the mixed fuel Gm becomes the target value MWIr.

  For example, as described in Japanese Patent Application Laid-Open No. 2010-156324, the lower heating value of gas is LHV [kcal / kg], the specific gravity of gas (density ratio of gas to air) is d, and the temperature of gas is T [K. ], The modified Wobbe index MWI of gas is defined by the following equation (3).

  Therefore, when the target value of the modified Wobbe index MWI of the mixed fuel Gm is MWIr, the target value MWIr is defined by the following equation (4).

  The characteristics of the mixed fuel Gm including the lower heating value LHVm and the specific gravity dm depend on the properties (components) of the mixed fuel Gm. The temperature T of the mixed fuel Gm can be adjusted by the temperature adjustment device 16. In the present embodiment, the temperature setting unit 25 sets the target temperature Tr of the mixed fuel Gm so that the modified Wobbe index MWI of the mixed fuel Gm becomes the target value MWIr. The target temperature Tr is set based on the following equation (5).

  The temperature adjustment device 16 adjusts the temperature of the mixed fuel Gm supplied to the combustor 3 based on the target temperature Tr set by the temperature setting unit 25. The temperature adjusting device 16 adjusts the temperature of the mixed fuel Gm generated by the mixing unit 15 so that the temperature of the mixed fuel Gm supplied to the combustor 3 becomes the target temperature Tr. Thereby, the mixed fuel Gm in which the modified Wobbe index MWI is adjusted to the target value MWIr is supplied to the combustor 3.

  Next, an example of the fuel supply method according to this embodiment will be described. In the present embodiment, the mixing ratio of the first fuel G1 and the second fuel G2 is changed at an arbitrary timing. Even if the mixing ratio is changed, the temperature setting unit 25 sets the target temperature Tr of the mixed fuel Gm so that the modified Wobbe index MWI of the mixed fuel Gm becomes the target value MWIr. The temperature adjustment device 16 is based on the target temperature Tr set by the temperature setting unit 25 so that the modified Wobbe index MWI of the mixed fuel Gm becomes the target value MWIr before and after the mixture ratio is changed. Then, the temperature of the mixed fuel Gm is adjusted.

  The target value MWIr may be an intended numerical value, or an intended numerical value and a numerical value within an allowable range based on the numerical value. In the present embodiment, the target temperature Tr is set so that the modified Wobbe index MWI of the mixed fuel Gm becomes a value within an allowable range before and after the change of the mixture ratio.

  FIG. 4 is a flowchart illustrating an example of a fuel supply method according to the present embodiment. As shown in FIG. 4, in the present embodiment, the first fuel G1 and the second fuel G2 are mixed at the first mixing ratio (k1a: k2a) to generate the mixed fuel Gm having the first mixing ratio. (Step SA1), setting the target temperature Tr so that the modified Wobbe index MWI of the mixed fuel Gm having the first mixture ratio becomes the target value MWIr (step SA2), and the target temperature set in step SA2 A command for adjusting the temperature of the mixed fuel Gm having the first mixing ratio generated by the mixing unit 15 so as to be Tr (step SA3) and for changing from the first mixing ratio to the second mixing ratio. Outputting a signal (step SA4) and mixing the first fuel G1 and the second fuel G2 at the second mixing ratio (k1b: k2b) to generate the mixed fuel Gm having the second mixing ratio. ( Step SA5), setting the target temperature Tr so that the modified Wobbe index MWI of the mixed fuel Gm of the second mixture ratio becomes the target value MWIr (Step SA6), and the target temperature Tr set in Step SA6 Thus, the temperature of the mixed fuel Gm having the second mixing ratio generated by the mixing unit 15 is adjusted (step SA7).

  The first mixing ratio is a mixing ratio before the change. The first mixing ratio of the first fuel G1 and the second fuel G2 is k1a: k2a. The second mixing ratio is the changed mixing ratio. The second mixing ratio of the first fuel G1 and the second fuel G2 is k1b: k2b.

  The control device 20 controls the first supply amount adjusting device 13 and the second supply amount adjusting device 14 so that the mixed fuel Gm having the first mixing ratio is supplied to the combustor 3. In the present embodiment, the first mixing ratio k1a: k2a = 1: 0. That is, the mixing ratio k1a of the first fuel G1 is 100%, and the mixing ratio k2a of the second fuel G2 is 0%. In other words, the mixed fuel Gm having the first mixing ratio includes only the first fuel G1 and does not include the second fuel G2. The control device 20 adjusts the first supply amount so that the first fuel G1 is supplied from the first fuel supply device 11 to the mixing unit 15 and the second fuel G2 is not supplied from the second fuel supply device 12 to the mixing unit 15. The device 13 and the second supply amount adjusting device 14 are controlled. The first supply amount adjusting device 13 opens the flow path of the pipe 41 so that the opening ratio of the flow path of the pipe 41 becomes Pa% (100%). The second supply amount adjusting device 14 closes the flow path of the pipe 42 so that the opening ratio of the flow path of the pipe 42 is Qa% (0%). Thereby, the mixed fuel Gm having the first mixing ratio is generated (step SA1).

  The control device 20 sets the target temperature Tr so that the modified Wobbe index MWI of the mixed fuel Gm having the first mixing ratio becomes the target value MWIr according to the above-described equations (1) to (5) (step SA2). . The control device 20 controls the temperature adjusting device 16 to adjust the temperature of the mixed fuel Gm having the first mixing ratio so as to be the target temperature Tr set in step SA2 (step SA3). The temperature adjustment device 16 starts temperature adjustment of the mixed fuel Gm based on the target temperature Tr corresponding to the first mixing ratio (k1a: k2a). The temperature of the mixed fuel Gm is detected by the temperature sensor 17. A detection signal of the temperature sensor 17 is output to the control device 20. The control device 20 adjusts the temperature of the mixed fuel Gm using the temperature adjustment device 16 so as to reach the target temperature Tr based on the detection value of the temperature sensor 17.

  As a result, the mixed fuel Gm having the first mixing ratio in which the modified Wobbe index MWI is adjusted to the target value MWIr is supplied to the combustor 3.

  In the present embodiment, the combustion adjustment operation of the combustor 3 is performed in a state where the mixed fuel Gm having the first mixing ratio is supplied to the combustor 3. Combustion adjustment work adjusts the distribution of fuel supply to the plurality of combustors 3 of the gas turbine 1 in order to prevent pressure fluctuations (combustion vibration) inside the combustor 3 during combustion and to reduce NOx. The work to do.

  The gas turbine 1 includes a plurality of combustors (combustion systems) such as a pilot combustor such as a diffusion combustor and a main combustor such as a premix combustor. The fuel supply device 10 supplies fuel to the plurality of combustion systems (diffusion combustion system and premixed combustion system). If the fuel supply amount is not properly distributed to the plurality of combustion systems, combustion vibration may occur or the amount of NOx may increase, and the performance of the combustor 3 may be degraded. In the present embodiment, the distribution of the fuel supply amount to the plurality of combustors 3 is adjusted by the combustion adjustment work in order to prevent combustion vibration and reduce NOx.

  After the combustion adjustment work is completed, the mixture ratio of the mixed fuel Gm is changed (step SA4). In order to change the mixing ratio of the first fuel G1 and the second fuel G2, the input device 50 is operated at an arbitrary timing by the operator. Based on the input signal of the input device 50, the mixing ratio setting unit 21 outputs a command signal for changing the mixing ratio to each of the first supply amount adjusting device 13 and the second supply amount adjusting device 14. Each of the first supply amount adjusting device 13 and the second supply amount adjusting device 14 starts an operation for changing the mixing ratio based on a command signal for changing the mixing ratio output from the mixing ratio setting unit 21. .

  The operation for changing the mixing ratio is performed by changing the supply amount of the first fuel G1 supplied from the first fuel supply device 11 to the mixing unit 15 and from the second fuel supply device 12 to the mixing unit 15. The operation | movement which changes the supply amount of the 2nd fuel G2 supplied with respect to it is included. The control device 20 controls the first supply amount adjusting device 13 so that the supply amount of the first fuel G1 is changed. In addition, the control device control device 20 controls the second supply amount adjusting device 14 so that the supply amount of the second fuel G2 is changed.

  As described above, in the present embodiment, the first supply amount adjusting device 13 includes the valve mechanism, and adjusts the opening degree of the valve mechanism (or the opening ratio P of the flow path of the pipe 41) to thereby adjust the first fuel. The supply amount of G1 is adjusted. The second supply amount adjusting device 14 includes a valve mechanism, and adjusts the supply amount of the second fuel G2 by adjusting the opening degree of the valve mechanism (or the opening ratio Q of the flow path of the pipe 42). In the present embodiment, the operation of changing the supply amount of the first fuel G <b> 1 includes the operation of changing the opening ratio P of the flow path of the pipe 41. The operation of changing the supply amount of the second fuel G2 includes an operation of changing the opening ratio Q of the flow path of the pipe 42.

  In the following description, a time point at which an operation for changing the mixing ratio is referred to as a time point ta. In the present embodiment, at the time point ta, the operation of changing the supply amount of the first fuel G1 supplied from the first fuel supply device 11 to the mixing unit 15 and the second fuel supply device 12 to the mixing unit 15 are performed. On the other hand, an operation of changing the supply amount of the second fuel G2 supplied is started. That is, at the time point ta, an operation for changing the opening ratio P of the flow path of the pipe 41 and an operation for changing the opening ratio Q of the flow path of the pipe 42 are started.

  The control device 20 controls the first supply amount adjusting device 13 and the second supply amount adjusting device 14 so that the mixed fuel Gm having the second mixing ratio is supplied to the combustor 3. In the present embodiment, in the second mixing ratio (k1b: k2b), each of the mixing ratio k1b of the first fuel G1 and the mixing ratio k2b of the second fuel G2 is not 0%. For example, in the second mixing ratio, the mixing ratio k1b of the first fuel G1 is less than 100% and 90% or more, and the mixing ratio k2b of the second fuel G2 is the remainder. In the control device 20, the first fuel G1 is supplied from the first fuel supply device 11 to the mixing unit 15 at the mixing ratio k1b, and the second fuel G2 is supplied from the second fuel supply device 12 to the mixing unit 15 at the mixing ratio k2b. Thus, the first supply amount adjusting device 13 and the second supply amount adjusting device 14 are controlled. The 1st supply amount adjustment apparatus 13 opens the flow path of the piping 41 so that the opening ratio of the flow path of the piping 41 may be Pb% (for example, 95%). The second supply amount adjusting device 14 opens the flow path of the pipe 42 so that the opening ratio of the flow path of the pipe 42 is Qb% (for example, 5%). Thereby, the mixed fuel Gm having the second mixing ratio is generated (step SA5).

  That is, in the present embodiment, in order to generate the mixed fuel Gm having the first mixing ratio (k1a: k2a), the opening ratio of the flow path of the pipe 41 is adjusted to be Pa%, and the flow of the pipe 42 is increased. The road opening ratio is adjusted to be Qa%. In order to change the first mixing ratio (k1a: k2a) to the second mixing ratio (k1b: k2b), the opening ratio of the flow path of the pipe 41 is changed from Pa% to Pb% at the time ta, and the pipe 42 The opening ratio of the channel is changed from Qa% to Qb%. In order to generate the mixed fuel Gm having the second mixing ratio (k1b: k2b), the opening ratio of the flow path of the pipe 41 is adjusted to be Pb%, and the opening ratio of the flow path of the pipe 42 is set to Qb%. It is adjusted to become.

  The control device 20 sets the target temperature Tr so that the modified Wobbe index MWI of the mixed fuel mixed fuel Gm having the second mixing ratio becomes the target value MWIr according to the above-described equations (1) to (5) (step) SA6). The control device 20 controls the temperature adjusting device 16 to adjust the temperature of the mixed fuel Gm having the second mixing ratio so as to become the target temperature Tr set in step SA5 (step SA7). The temperature adjustment device 16 starts temperature adjustment of the mixed fuel Gm based on the target temperature Tr corresponding to the second mixing ratio (k1b: k2b). The temperature of the mixed fuel Gm is detected by the temperature sensor 17. A detection signal of the temperature sensor 17 is output to the control device 20. The control device 20 adjusts the temperature of the mixed fuel Gm based on the detected value of the temperature sensor 17 so that the target temperature Tr is reached.

  As a result, the mixed fuel Gm having the second mixing ratio in which the modified Wobbe index MWI is adjusted to the target value MWIr is supplied to the combustor 3. In the present embodiment, in a state where the mixed fuel Gm having the second mixing ratio is supplied to the combustor 3, the combustor 3 injects the mixed fuel Gm into the compressed air to generate combustion gas. Thereby, the gas turbine 1 operates.

  FIG. 5 is a timing chart showing an example of changes in the mixing ratio k1 of the first fuel G1 and the mixing ratio k2 of the second fuel G2. In FIG. 5, the horizontal axis represents time, and the vertical axis represents the mixing ratio. As shown in FIG. 5, at the time point ta, an operation for changing the mixing ratio is started. In the period before time ta, the mixing ratio is k1a: k2a. In the period after the time point ta, the mixing ratio is k1b: k2b.

  FIG. 6 is a timing chart showing an example of a change in temperature of the mixed fuel Gm. In FIG. 6, the horizontal axis represents time, and the vertical axis represents the temperature (gas temperature) of the mixed fuel Gm. As shown in FIG. 6, the target temperature Tr is changed at the same time ta when the operation for changing the mixture ratio is started. At the same time as time ta, temperature adjustment by the temperature adjustment device 16 based on the changed target temperature Tr is started. In FIG. 6, the target temperature Tr1 is a temperature for setting the modified Wobbe index MWI of the mixed fuel Gm having the first mixing ratio to the target value MWIr. The target temperature Tr2 is a temperature for setting the modified Wobbe index MWI of the mixed fuel Gm having the second mixing ratio to the target value MWIr.

  FIG. 7 is a timing chart showing an example of a change in the modified Wobbe index MWI of the mixed fuel Gm. In FIG. 7, the horizontal axis represents time, and the vertical axis represents the modified Wobbe index MWI of the mixed fuel Gm. As shown in FIG. 7, at the same time ta when the operation for changing the mixture ratio is started, the temperature of the mixed fuel Gm is changed to change the mixture ratio before and after the change of the mixture ratio. The modified Wobbe index MWI is maintained at a constant value (target value) MWIr. That is, the temperature of the mixed fuel Gm having the first mixing ratio is adjusted to the target temperature Tr1, and the temperature of the mixed fuel Gm having the second mixing ratio is adjusted to the target temperature Tr2, thereby mixing the first mixing ratio. The modified Wobbe index MWI of the fuel Gm is equal to the modified Wobbe index MWI of the mixed fuel Gm having the second mixture ratio.

  In this embodiment, the target value of the modified Wobbe index MWI of the mixed fuel Gm after changing from the first mixing ratio to the second mixing ratio is the modified Wobbe index MWIr of the mixed fuel Gm of the first mixing ratio. It is determined to be a reference allowable range (range between MWIr-ΔM and MWIr-ΔM). ΔM is 5% of the modified Wobbe index MWI of the mixed fuel Gm having the first mixing ratio.

  FIG. 7 shows a line MLJ as an example of the modified Wobbe index MWI when the temperature of the mixed fuel Gm is not changed even when the mixture ratio (k1: k2) is changed. As shown in FIG. 7, if the temperature of the mixed fuel Gm is not changed even if the mixture ratio is changed, the modified Wobbe index MWI may change greatly due to the change of the mixture ratio and deviate from the allowable range. In the present embodiment, the temperature (target temperature) of the mixed fuel Gm is changed before and after the change of the mixture ratio based on the characteristic information and the mixture ratio of the mixed fuel Gm. It is suppressed that the modified Wobbe index MWI greatly changes before and after the change.

  As described above, according to the present embodiment, the mixed fuel Gm is based on the characteristic information of the first fuel G1, the characteristic information of the second fuel G2, and the mixing ratio set by the mixing ratio setting unit 21. Since the target temperature Tr of the mixed fuel Gm is set so that the modified Wobbe index MWI becomes the target value MWIr, the mixing ratio is adjusted by adjusting the temperature of the mixed fuel Gm based on the target temperature Tr. Even if it is changed, the modified Wobbe index MWI of the mixed fuel Gm supplied to the combustor 3 can be made constant.

  As a result, the modified Wobbe index MWI of the mixed fuel Gm supplied from the fuel supply device 10 to the combustor 3 is suppressed from changing before and after the change of the mixing ratio. Therefore, the occurrence of combustion vibration in the combustor 3 due to the change in the modified Wobbe index MWI of the mixed fuel Gm is suppressed.

  The combustion vibration is a pressure fluctuation generated inside the combustor 3, and the excessive combustion vibration causes deterioration (damage) of the combustor 3 and the turbine components. The main component of natural gas, which is the first fuel G1, is methane. Methane has a lower combustion rate and lower combustibility than other hydrocarbon components such as ethane and propane. Therefore, when the first fuel G1 (natural gas) and the second fuel G2 (other gas) are mixed and the methane concentration in the mixed fuel Gm changes, the combustibility changes, and as a result, combustion oscillation occurs. there's a possibility that.

  In the present embodiment, the combustion oscillation is suppressed by maintaining the modified Wobbe index MWI constant. By suppressing the combustion vibration, the combustion in the combustor 3 becomes unstable and the combustor 3 and the turbine components are prevented from deteriorating. Therefore, a decrease in the performance of the combustor 3 and the gas turbine 1 is suppressed.

  In addition, by adjusting the temperature of the mixed fuel Gm so that the modified Wobbe index MWI remains constant even when the mixing ratio is changed, it is possible to avoid re-execution of the combustion adjustment work, and to reduce the work burden. it can.

  In the present embodiment, after the mixture ratio is set, the temperature of the mixed fuel Gm is adjusted based on the set mixture ratio. In order to make the modified Wobbe index MWI constant, the process for making the modified Wobbe index MWI constant is performed more smoothly than the method in which the mixing ratio is adjusted while the temperature is kept constant.

  In the present embodiment, a command signal for changing the mixing ratio is output from the mixing ratio setting unit 21 in changing the mixing ratio. Each of the first supply amount adjustment device 13 and the second supply amount adjustment device 14 starts an operation for changing the change ratio based on a command signal for changing the mixture ratio output from the mixture ratio setting unit 21. . In the present embodiment, processing for changing the target temperature Tr is performed at a time point ta at which the operation for changing the mixing ratio is started. In the present embodiment, the temperature adjustment device 16 starts temperature adjustment of the mixed fuel mixed fuel Gm based on the target temperature Tr corresponding to the changed mixture ratio. That is, based on the time point ta, the start point of temperature adjustment of the mixed fuel Gm based on the changed target temperature Tr is defined. Therefore, after changing the mixing ratio, temperature adjustment by the temperature adjusting device 16 based on the target temperature Tr corresponding to the changed mixing ratio is started at an appropriate time.

  In the present embodiment, the characteristic information of the first fuel G1 and the characteristic information of the second fuel G2 are measured in advance, the characteristic information of the first fuel G1 is stored in the first fuel database 22, and the second fuel The G2 characteristic information is stored in the second fuel database 23. The temperature setting unit 25 sets the target temperature Tr of the mixed fuel Gm based on the storage information of the first fuel database 22, the storage information of the second fuel database 23, and the mixing ratio set by the mixing ratio setting unit 21. Set. Thereby, the temperature setting unit 25 can quickly set the target temperature Tr.

Second Embodiment
A second embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof is simplified or omitted.

  FIG. 8 is a functional block diagram illustrating an example of the fuel supply apparatus 10 according to the present embodiment. In the present embodiment, the fuel supply device 10 determines the change rate of the mixing ratio k1 of the first fuel G1 and the change rate of the second fuel G2 based on the change rate of the actual temperature Tg of the mixed fuel Gm adjusted by the temperature adjusting device 16. A mixing ratio change rate adjusting unit 26 that adjusts the change rate of the mixing ratio k2 is provided.

  In the present embodiment, the mixture ratio change rate adjusting unit 26 is based on the change rate of the actual temperature Tg of the mixed fuel Gm whose temperature is adjusted by the temperature adjusting device 16, and the first fuel first of the first supply amount adjusting device 13. The change rate of the supply amount of the fuel G1 and the change rate of the supply amount of the second fuel G2 of the second supply amount adjusting device 14 are adjusted.

  In the present embodiment, the change rate of the mixing ratio is a change amount (change speed) of the mixing ratio per unit time. The rate of change in temperature is the amount of change in temperature (change rate) per unit time. The change rate of the supply amount is a change amount (change rate) of the supply amount per unit time.

  If the target temperature Tr of the mixed fuel Gm is changed from the target temperature Tr1 to the target temperature Tr2 at the time ta, even if the temperature adjustment device 16 starts adjusting the temperature of the mixed fuel Gm based on the target temperature Tr2 at the time ta. For example, a control delay (temperature adjustment delay) may occur in the actual temperature Tg of the mixed fuel Gm due to, for example, a heat transfer delay of the temperature adjusting device 16 and a heat capacity of the mixed fuel Gm.

  FIG. 9 is a diagram for explaining an example of the control delay. In FIG. 9, the horizontal axis represents time, and the vertical axis represents the temperature (gas temperature) of the mixed fuel Gm. At the time point ta, the mixing ratio of the first fuel G1 and the second fuel G2 is changed from the first mixing ratio to the second mixing ratio. At time ta, the temperature adjustment device 16 starts adjusting the temperature of the mixed fuel Gm based on the target temperature Tr2. Due to the control delay, at the time point ta, the actual temperature Tg of the mixed fuel Gm does not immediately change from the target temperature Tr1 to the target temperature Tr2. The actual temperature Tg of the mixed fuel Gm gradually changes from the target temperature Tr1 to the target temperature Tr2, and reaches the target temperature Tr2 at a time tb after a predetermined time (delay time) Hb has elapsed from the time ta.

  FIG. 10 is a schematic diagram illustrating an example of a change in the modified Wobbe index MWI of the mixed fuel Gm. FIG. 10 shows an example in which the first supply amount adjusting device 13 and the second supply amount adjusting device 14 are operated without considering the control delay in spite of the control delay occurring in the actual temperature Tg. . FIG. 10 shows an example in which the opening ratio P of the pipe 41 is instantaneously changed from the opening ratio Pa to the opening ratio Pb and the opening ratio Q of the pipe 42 is instantaneously changed from the opening ratio Qa to the opening ratio Qb at the time point ta. Show. That is, the supply amount of the first fuel G1 is instantaneously changed from the supply amount corresponding to the first mixing ratio to the supply amount corresponding to the second mixing ratio, and the supply amount of the second fuel G2 is changed to the first amount. An example in which the supply amount corresponding to the second mixing ratio is instantaneously changed from the supply amount corresponding to the mixing ratio will be described.

  Although the actual temperature Tg has not changed to the target temperature Tr2 at the time point ta, the opening ratio P is changed to the opening ratio Pb corresponding to the target temperature Tr2, and the opening ratio Q is an opening corresponding to the target temperature Tr2. The rate is changed to Qb. As a result, the modified Wobbe index MWI greatly fluctuates and may deviate from the allowable range as shown in FIG.

  In the present embodiment, the mixture ratio change rate adjusting unit 26 considers the control delay of the actual temperature Tg, and changes the change rate of the mixture ratio k1 of the first fuel G1 and the change rate of the mixture ratio k2 of the second fuel G2. Adjust each one.

  The adjustment of the mixing ratio k1 of the first fuel G1 includes the adjustment of the supply amount of the first fuel G1 of the first supply amount adjustment device 13. The adjustment of the mixing ratio k2 of the second fuel G2 includes the adjustment of the supply amount of the second fuel G2 of the second supply amount adjustment device 14.

  Therefore, the mixing ratio change rate adjustment unit 26 takes into account the control delay of the actual temperature Tg, and the change rate of the supply amount of the first fuel G1 of the first supply amount adjustment device 13 and the second supply amount adjustment device 14. Each change rate of the supply amount of the second fuel G2 is adjusted.

  That is, the mixing ratio change rate adjusting unit 26 changes the supply amount of the first fuel G1 of the first supply amount adjusting device 13 based on the change rate of the actual temperature Tg of the mixed fuel Gm adjusted by the temperature adjusting device 16. The rate and the change rate of the supply amount of the second fuel G2 of the second supply amount adjusting device 14 are adjusted.

  In the present embodiment, the adjustment of the supply amount of the first fuel G <b> 1 includes the adjustment of the opening ratio P of the flow path of the pipe 41. The adjustment of the supply amount of the second fuel G2 includes the adjustment of the opening ratio Q of the flow path of the pipe 42.

  Therefore, the mixture ratio change rate adjusting unit 26 adjusts the change rate of the opening rate P and the change rate of the opening rate Q based on the change rate of the actual temperature Tg of the mixed fuel Gm adjusted by the temperature adjusting device 16. The change rate of the aperture ratio is a change amount (change speed) of the aperture ratio per unit time.

  FIG. 11 shows the mixing ratio k1 'of the first fuel G1 and the mixing ratio k2' of the second fuel G2 whose rate of change is adjusted in consideration of the control delay of the actual temperature Tg. As shown in FIG. 11, in consideration of the control delay of the actual temperature Tg, each of the mixing ratio k1 'of the first fuel G1 and the mixing ratio k2' of the second fuel G2 changes slowly from the time point ta.

  When the time constant of the actual temperature Tg is t1, the mixing ratio k1 'and the mixing ratio k2' are defined by the following expressions (6) and (7). The time constant t1 is determined in consideration of the control delay of the actual temperature Tg.

  FIG. 12 shows the mixed fuel when the change rate of the mixing ratio k1 ′ of the first fuel G1 and the change rate of the mixing ratio k2 ′ of the second fuel G2 are adjusted in consideration of the control delay of the actual temperature Tg. It is a schematic diagram which shows an example of the change of the modified Wobbe index | exponent MWI of Gm. When a control delay occurs in the actual temperature Tg, the change rate of the mixing ratio (the change rate of the supply amount and the change rate of the opening ratio) is adjusted in consideration of the control delay of the actual temperature Tg, so that FIG. As shown, the modified Wobbe index MWI falls within an acceptable range.

  As described above, when a control delay occurs in the actual temperature Tg, the modified Wobbe index MWI before and after the change of the mixture ratio based on the change rate of the actual temperature Tg of the mixed fuel Gm adjusted by the temperature adjustment device 16. Even when the mixture ratio is changed by adjusting the change rate of the mixture ratio k1 ′ of the first fuel G1 and the change rate of the mixture ratio k2 ′ of the second fuel G2 so that the fuel ratio does not deviate from the allowable range, The modified Wobbe index MWI of the mixed fuel Gm can be within an allowable range. Therefore, generation | occurrence | production of combustion vibration is suppressed and the fall of the performance of the combustor 3 and the gas turbine 1 is suppressed.

<Third Embodiment>
A third embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof is simplified or omitted.

  In the present embodiment, the mixture ratio change rate adjustment unit 26 estimates the actual temperature Test value of the mixed fuel Gm estimated in consideration of the detection result (detection value Tm) of the temperature sensor 17 and the detection delay of the temperature sensor 17. Based on the above, an example of adjusting the change rate of the mixing ratio will be described.

  At the time point ta, the mixing ratio of the first fuel G1 and the second fuel G2 is changed from the first mixing ratio to the second mixing ratio. At the time point ta, the target temperature Tr of the mixed fuel Gm is changed from the target temperature Tr1 to the target temperature Tr2. At time ta, the temperature adjustment device 16 starts adjusting the temperature of the mixed fuel Gm based on the detection value Tm of the temperature sensor 17 so that the temperature of the mixed fuel Gm becomes the target temperature Tr2. When a detection delay occurs in the temperature sensor 17, even if the temperature adjustment device 16 starts adjusting the temperature of the mixed fuel Gm so that the target temperature Tr2 is reached at the time ta, due to the detection delay of the temperature sensor 17, There is a possibility that the temperature of the mixed fuel Gm is not accurately adjusted.

  That is, when a detection delay occurs in the temperature sensor 17, the change rate of the mixing ratio k1 and the change rate of the mixing ratio k2 of the second fuel G2 are adjusted based on the detection value Tm of the temperature sensor 17 different from the actual temperature Tg. Will be. When the detection delay of the temperature sensor 17 is not taken into account, the control device 20 adjusts the change rate of the mixing ratio in a state of being trapped by the temperature sensor 17. As a result, the modified Wobbe index MWI may deviate from the allowable range.

  When a detection delay of the temperature sensor 17 occurs, for example, the supply amount (opening ratio P) of the first fuel G1 based on the detection value Tm and the actual temperature Tg changes to the target temperature Tr2 at the time point ta. When the supply amount (opening ratio Q) of the second fuel G2 is adjusted, the supply amount (opening ratio P) of the first fuel G1 and the supply amount (opening ratio Q) of the second fuel G2 correspond to the target temperature Tr2. The value may not be changed. As a result, the modified Wobbe index MWI may vary greatly and deviate from the allowable range.

  In the present embodiment, the actual temperature estimated value Test is derived in consideration of the detection value Tm of the temperature sensor 17 and the detection delay of the temperature sensor 17. Based on the actual temperature estimated value Test, the change rate of the mixing ratio is adjusted.

  When the time constant of the temperature sensor 17 is t2 and the detection value of the temperature sensor 17 is Tm, the actual temperature estimated value Test is defined by the following equation (8). The time constant t2 is determined in consideration of the control delay of the temperature sensor 17.

  The control device 20 sets the actual temperature estimated value Test of the mixed fuel Gm estimated in consideration of the detection value Tm of the temperature sensor 17 and the detection delay of the temperature sensor 17 so that the modified Wobbe index MWI does not deviate from the allowable range. Based on this, the rate of change of the mixing ratio is adjusted. When not only the detection delay of the temperature sensor 17 but also the control delay of the actual temperature Tg by the temperature adjusting device 16 occurs, the control device 20 considers both the control delay of the actual temperature Tg and the detection delay of the temperature sensor 17. Each of the mixing ratio k1 and the mixing ratio k2 is changed slowly. This suppresses the modified Wobbe index MWI from deviating from the allowable range.

  Further, in the present embodiment, the mixture ratio change rate adjusting unit 26 is based on the actual temperature estimated value Test of the mixed fuel Gm estimated in consideration of the detection value Tm of the temperature sensor 17 and the detection delay of the temperature sensor 17. The limiting value (upper limit value and lower limit value) of the mixing ratio k1 of the first fuel G1 and the limiting value (upper limit value and lower limit value) of the mixing ratio k2 of the second fuel G2 are defined. The mixture ratio change rate adjusting unit 26 adjusts the change rate of the mixture ratio based on the specified limit value of the mixture ratio so that the modified Wobbe index MWI does not deviate from the allowable range.

  As in the above-described embodiment, the operation for changing the mixing ratio is performed by the operation for changing the opening ratio P of the flow path of the pipe 41 by the first supply amount adjusting device 13 and the operation for changing the mixing ratio by the second supply amount adjusting device 14. The operation includes changing the opening ratio Q of the flow path of the pipe 42.

  FIG. 13 is a diagram illustrating an example of an upper limit value and a lower limit value of the mixing ratio k1 of the first fuel G1. In FIG. 13, the horizontal axis indicates the actual temperature estimated value Test of the mixed fuel Gm estimated in consideration of the detected value of the temperature sensor 17 and the detection delay of the temperature sensor 17. The vertical axis represents the mixing ratio k1 of the first fuel G1. The relationship between the actual temperature estimated value Test shown in FIG. 13 and k1 of the first fuel G1 is obtained by a prior experiment (preliminary experiment). The limit values (upper limit value and lower limit value) of the mixing ratio k2 of the second fuel G2 are obtained by k2 = 1−k1. The relationship between the actual temperature estimated value Test and the limit value of the mixing ratio k1 of the first fuel G1, and the relationship between the actual temperature estimated value Test and the limit value of the mixing ratio k2 of the second fuel G2 are stored in the storage unit of the control device 20. Is remembered.

  The limit value of the mixing ratio is a value that allows the modified Wobbe index MWI to fall within an allowable range without departing from the limit value in the estimated actual temperature Test. As described above, the limit value of the mixing ratio may be obtained by a preliminary experiment. The limit value of the mixing ratio may be obtained by simulation. When changing the mixing ratio based on the actual temperature estimated value Test, the control device 20 slowly changes the mixing ratio so that the mixing ratio does not deviate from the limit value. As a result, the modified Wobbe index MWI falls within the allowable range.

  As described above, when a detection delay occurs in the temperature sensor 17, based on the actual temperature estimated value Test, the change rate of the mixing ratio k1 of the first fuel G1 and the change rate of the mixing ratio k2 of the second fuel G2 are calculated. By adjusting within the limit value range, the modified Wobbe index MWI of the mixed fuel Gm can be kept within the allowable range even when the mixing ratio is changed. Therefore, generation | occurrence | production of combustion vibration is suppressed and the fall of the performance of the combustor 3 and the gas turbine 1 is suppressed.

<Fourth embodiment>
A fourth embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof is simplified or omitted.

  In the present embodiment, the changed mixing ratio is supported based on the time from the start of the operation for changing the mixing ratio until the mixed fuel Gm having the changed mixing ratio reaches the temperature adjusting device 16. An example in which the start point of temperature adjustment by the temperature adjustment device 16 based on the target temperature Tr2 to be performed is defined will be described.

  An operation for changing the mixing ratio (an operation for changing the supply amount of the first fuel G1 and an operation for changing the supply amount of the second fuel G2) is performed, and the mixed fuel Gm having the changed mixing ratio is mixed by the mixing unit 15. Even if it is generated at, the temperature adjusting device 16 has the mixed fuel Gm before the change of the mixture ratio at the time when the operation for changing the mixture ratio is started and immediately after. In this state, if the temperature adjusting device 16 starts adjusting the temperature of the mixed fuel Gm based on the changed mixing ratio, the mixed fuel Gm having the changed mixing ratio corresponds to the changed mixing ratio. The temperature is adjusted based on the target temperature Tr2 to be performed. As a result, the modified Wobbe index MWI may deviate from the allowable range.

  Therefore, in the present embodiment, the mixture after the change is based on the time Hc from the start of the operation for changing the mixture ratio until the mixed fuel Gm having the changed mixture ratio reaches the temperature adjusting device 16. A temperature adjustment start time tc by the temperature adjustment device 16 based on the target temperature Tr2 corresponding to the ratio is defined.

  FIG. 14 is a timing chart showing an example of a temperature change of the mixed fuel Gm according to the present embodiment. In FIG. 14, the horizontal axis represents time, and the vertical axis represents the temperature (gas temperature) of the mixed fuel Gm. As shown in FIG. 14, at the time point ta, an operation for changing the mixing ratio is started. As described in the above embodiment, the operation for changing the mixing ratio is the operation of changing the opening ratio P of the flow path of the pipe 41 by the first supply amount adjusting device 13 and the second supply amount adjusting device 14. The operation | movement which changes the opening ratio Q of the flow path of the piping 42 by is included. At the time point ta, the first supply amount adjusting device 13 changes the opening ratio Pa of the flow path of the pipe 41 to the opening ratio Pb. At the time point ta, the second supply amount adjusting device 14 changes the opening ratio Qa of the flow path of the pipe 42 to the opening ratio Qb.

  The temperature adjustment by the temperature adjustment device 16 based on the target temperature Tr2 corresponding to the changed mixing ratio is started at a time point tc after the elapse of time Hc from the time point ta. Until the time point tc, the temperature adjustment device 16 performs temperature adjustment of the mixed fuel Gm based on the target temperature Tr1 corresponding to the mixture ratio before the change.

  The time Hc is the time required for the first fuel G1 to move (flow) from the first supply amount adjusting device 13 to the temperature adjusting device 16 via the mixing unit 15. The time Hc is the time required for the second fuel G2 to move (flow) from the second supply amount adjusting device 14 to the temperature adjusting device 16 via the mixing unit 15. The time Hc is obtained based on the flow rate of the first fuel G1 and the distance from the first supply amount adjusting device 13 to the temperature adjusting device 16. The time Hc is obtained based on the flow rate of the second fuel G2 and the distance from the second supply amount adjusting device 14 to the temperature adjusting device 16. The time Hc may be obtained by a prior experiment (preliminary experiment) or may be obtained by simulation.

  As described above, when there is a fuel flow delay from the first supply amount adjusting device 13 or the second supply amount adjusting device 14 to the temperature adjusting device 16, the change is made after the operation for changing the mixing ratio is started. Until the time Hc until the mixed fuel Gm of the later mixing ratio reaches the temperature adjusting device 16 has elapsed, the mixed fuel mixed fuel Gm by the temperature adjusting device 16 is based on the target temperature Tr1 corresponding to the mixing ratio before the change. The temperature adjustment of the mixed fuel Gm by the temperature adjustment device 16 is started based on the target temperature Tr2 corresponding to the changed mixture ratio at the time tc when the time Hc elapses. Thus, the temperature of the mixed fuel Gm can be adjusted based on an appropriate target temperature corresponding to the mixing ratio. Therefore, the modified Wobbe index MWI is suppressed from deviating from the allowable range.

<Fifth Embodiment>
A fifth embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof is simplified or omitted.

  FIG. 15 is a schematic diagram illustrating an example of the fuel supply apparatus 10 according to the present embodiment. In the present embodiment, the fuel supply device 10 includes a first detection device 31 that detects characteristic information of the first fuel G1 and a second detection device 32 that detects characteristic information of the second fuel G2. The first detection device 31 is disposed in a pipe 41 between the first fuel supply device 11 and the mixing unit 15. The first detection device 31 detects the characteristic of the first fuel G1 that is sent from the first fuel supply device 11 and before being supplied to the mixing unit 15. The second detection device 32 is disposed in a pipe 42 between the second fuel supply device 12 and the mixing unit 15. The second detection device 32 detects the characteristic of the second fuel G2 that is sent from the second fuel supply device 12 and before being supplied to the mixing unit 15.

  The first detection device 31 includes a calorimeter that can detect the lower heating value LHV1 of the first fuel G1 and a density meter that can detect the specific gravity d1 of the first fuel G1. The second detection device 32 includes a calorimeter that can detect the lower heating value LHV2 of the second fuel G2, and a density meter that can detect the specific gravity d2 of the second fuel G2. The detection signal of the first detection device 31 and the detection signal of the second detection device 32 are output to the control device 20.

  In the present embodiment, the stored information in the first fuel database 22 is updated based on the detection result of the first detection device 31. Based on the detection result of the second detection device 32, the storage information of the second fuel database 23 is updated.

  There may be a difference between the stored information in the first fuel database 22 and the characteristics of the first fuel G1 supplied from the first fuel supply device 11. In the present embodiment, the first detection device 31 detects the characteristics of the first fuel G1 supplied from the first fuel supply device 11, and based on the detection results, periodically stores the information stored in the first fuel database 22. Update to Thereby, generation | occurrence | production of the shift | offset | difference with the memory | storage information of the 1st fuel database 22 and the characteristic (actual characteristic) of the 1st fuel G1 supplied from the 1st fuel supply apparatus 11 can be suppressed. Similarly, the storage information in the second fuel database 23 is periodically updated based on the detection result of the second detection device 32, so that the storage information in the second fuel database 23 and the second fuel supply device 12 Generation | occurrence | production of the shift | offset | difference with the characteristic (actual characteristic) of the 2nd fuel G2 supplied can be suppressed. Therefore, the target temperature Tr of the mixed fuel Gm can be set with high accuracy.

  In each of the above-described embodiments, the mixing ratio k2a of the second fuel G2 is 0% in the first mixing ratio (k1a: k2a). That is, the second fuel G2 is not included in the mixed fuel Gm having the first mixing ratio. Both the first fuel G1 and the second fuel G2 may be included in the mixed fuel Gm having the first mixing ratio.

  In each of the above-described embodiments, the combustion adjustment operation is performed using the mixed fuel Gm having the first mixing ratio, and the gas turbine 1 is actually operated using the mixed fuel Gm having the second mixing ratio. It was. The gas turbine 1 may be actually operated using each of the mixed fuel Gm having the first mixing ratio and the mixed fuel Gm having the second mixing ratio.

  In the above-described embodiments, the mixed fuel Gm is generated by mixing the first fuel G1 and the second fuel G2. The mixed fuel Gm may be generated by mixing a plurality of three or more different types of fuel.

  In each of the above embodiments, the temperature of the mixed fuel Gm is adjusted so that the variation of the modified Wobbe index MWI is suppressed when the mixing ratio is changed. The temperature of the mixed fuel Gm may be adjusted so that the variation of the modified Wobbe index MWI is suppressed when the type (property, component) of the fuel supplied to the combustor 3 is switched. For example, the temperature of the mixed fuel Gm may be adjusted so that the fluctuation of the modified Wobbe index MWI is suppressed when the fuel supplied to the combustor 3 is switched from natural gas to another gas.

DESCRIPTION OF SYMBOLS 1 Gas turbine 2 Compressor 3 Combustor 4 Turbine 5 Rotor blade 6 Rotor 7 Stator blade 8 Stator 10 Fuel supply device 11 First fuel supply device 12 Second fuel supply device 13 First supply amount adjustment device 14 Second supply amount adjustment Device 15 Mixing unit 16 Temperature adjusting device 17 Temperature sensor 18 Pressure adjusting valve 19 Supply amount adjusting valve 20 Control device 21 Mixing ratio setting unit 22 First fuel database (first storage unit)
23 Second fuel database (second storage unit)
24 calculation unit 25 temperature setting unit 26 mixing ratio change rate adjustment unit 31 first detection device 32 second detection device 41 piping 42 piping 43 piping 50 input device d1 specific gravity d2 specific gravity dm specific gravity G1 first fuel G2 second fuel Gm mixed fuel LHV1 Lower heating value LHV2 Lower heating value LHVm Lower heating value MWI Modified Wobbe index MWIr Target value Tr Target temperature

Claims (12)

A fuel supply device for supplying a mixed fuel of a first fuel and a second fuel to a combustor of a gas turbine,
A mixing ratio setting unit that sets a mixing ratio of the first fuel and the second fuel;
A mixing unit in which the first fuel and the second fuel are mixed at the set mixing ratio;
The first fuel characteristic information including the lower heating value and specific gravity of the first fuel, the second fuel characteristic information including the lower heating value and specific gravity of the second fuel, and the mixing ratio setting unit are set. A temperature setting unit that sets a target temperature of the mixed fuel supplied to the combustor so that a modified Wobbe index of the mixed fuel of the mixing ratio becomes a target value based on the mixing ratio;
A temperature adjusting device that adjusts the temperature of the mixed fuel supplied to the combustor based on the target temperature set by the temperature setting unit;
A mixing ratio change rate adjusting unit that adjusts the change rate of the mixing ratio based on the change rate of the actual temperature of the mixed fuel adjusted by the temperature adjusting device;
A fuel supply device comprising: A first supply amount adjusting device that adjusts a supply amount of the first fuel supplied to the mixing unit based on the mixing ratio set by the mixing ratio setting unit;
A second supply amount adjusting device for adjusting a supply amount of the second fuel supplied to the mixing unit based on the mixing ratio set by the mixing ratio setting unit;
A fuel supply device according to claim 1. Based on a command signal for changing the mixing ratio output from the mixing ratio setting unit, an operation for changing the mixing ratio is started,
The fuel supply device according to claim 1 or 2, wherein the temperature adjustment device starts temperature adjustment of the mixed fuel based on a target temperature corresponding to the changed mixing ratio. A temperature sensor for detecting the temperature of the mixed fuel whose temperature is adjusted by the temperature adjusting device;
The mixing ratio change rate adjustment unit defines a limit value of the mixing ratio based on an estimated actual temperature value of the mixed fuel estimated in consideration of a detection result of the temperature sensor and a detection delay of the temperature sensor. The fuel supply device according to any one of claims 1 to 3, wherein a change rate of the mixing ratio is adjusted. The temperature setting unit sets a target temperature corresponding to the changed mixing ratio based on the command signal,
Based on the time from the start of the operation for changing the mixing ratio until the mixed fuel having the changed mixing ratio reaches the temperature adjusting device, the target temperature corresponding to the changed mixing ratio is reached. The fuel supply device according to claim 3, wherein a starting point of temperature adjustment by the temperature adjusting device is defined. A fuel supply device for supplying a mixed fuel of a first fuel and a second fuel to a combustor of a gas turbine,
A mixing ratio setting unit that sets a mixing ratio of the first fuel and the second fuel;
A mixing unit in which the first fuel and the second fuel are mixed at the set mixing ratio;
The first fuel characteristic information including the lower heating value and specific gravity of the first fuel, the second fuel characteristic information including the lower heating value and specific gravity of the second fuel, and the mixing ratio setting unit are set. A temperature setting unit that sets a target temperature of the mixed fuel supplied to the combustor so that a modified Wobbe index of the mixed fuel of the mixing ratio becomes a target value based on the mixing ratio;
A temperature adjusting device that adjusts the temperature of the mixed fuel supplied to the combustor based on the target temperature set by the temperature setting unit;
With
Based on a command signal for changing the mixing ratio output from the mixing ratio setting unit, an operation for changing the mixing ratio is started,
The temperature adjusting device starts temperature adjustment of the mixed fuel based on a target temperature corresponding to the changed mixing ratio,
The temperature setting unit sets a target temperature corresponding to the changed mixing ratio based on the command signal,
Based on the time from the start of the operation for changing the mixing ratio until the mixed fuel having the changed mixing ratio reaches the temperature adjusting device, the target temperature corresponding to the changed mixing ratio is reached. It said temperature adjusting device fuel supply system start of the temperature adjustment Ru is defined by based. A fuel supply device for supplying a mixed fuel of a first fuel and a second fuel to a combustor of a gas turbine,
A mixing ratio setting unit that sets a mixing ratio of the first fuel and the second fuel;
A mixing unit in which the first fuel and the second fuel are mixed at the set mixing ratio;
The first fuel characteristic information including the lower heating value and specific gravity of the first fuel, the second fuel characteristic information including the lower heating value and specific gravity of the second fuel, and the mixing ratio setting unit are set. A temperature setting unit that sets a target temperature of the mixed fuel supplied to the combustor so that a modified Wobbe index of the mixed fuel of the mixing ratio becomes a target value based on the mixing ratio;
A temperature adjusting device that adjusts the temperature of the mixed fuel supplied to the combustor based on the target temperature set by the temperature setting unit;
A first storage unit for storing the characteristic information of the first fuel;
A second storage unit that stores the characteristic information of the second fuel,
The temperature setting unit, and the information stored in the first storage unit, and the information stored in the second storage unit, based on said mixing ratio set by the mixing ratio setting section, the target temperature of the mixed fuel setting the fuel supply system you. A first detection device for detecting characteristic information of the first fuel;
A second detection device for detecting characteristic information of the second fuel,
Based on the detection result of the first detection device, the storage information of the first storage unit is updated,
The fuel supply device according to claim 7, wherein stored information in the second storage unit is updated based on a detection result of the second detection device.   A combustor to which the mixed fuel is supplied from the fuel supply device according to any one of claims 1 to 8. The fuel supply device according to any one of claims 1 to 8,
A combustor to which the mixed fuel is supplied from the fuel supply device;
A gas turbine comprising: A fuel supply method for supplying a mixed fuel of a first fuel and a second fuel to a combustor of a gas turbine,
Setting a mixing ratio of the first fuel and the second fuel;
Mixing the first fuel and the second fuel at the set mixing ratio;
The first fuel characteristic information including the lower heating value and specific gravity of the first fuel, the second fuel characteristic information including the lower heating value and specific gravity of the second fuel, and the mixing ratio setting unit are set. Setting a target temperature of the mixed fuel to be supplied to the combustor based on the mixing ratio so that a modified Wobbe index of the mixed fuel of the mixing ratio becomes a target value;
Adjusting the temperature of the mixed fuel supplied to the combustor based on the set target temperature;
Adjusting the rate of change of the mixing ratio based on the rate of change of the actual temperature of the mixed fuel whose temperature is adjusted;
A fuel supply method including: Setting a first mixing ratio to produce a mixed fuel of the first mixing ratio;
Setting the target temperature such that the modified Wobbe index of the mixed fuel of the first mixing ratio becomes a target value, and adjusting the temperature of the mixed fuel of the first mixing ratio;
Changing a first mixing ratio to a second mixing ratio to produce a fuel mixture of the second mixing ratio;
Setting the target temperature so that the modified Wobbe index of the mixed fuel of the second mixing ratio becomes a target value, and adjusting the temperature of the mixed fuel of the second mixing ratio;
The fuel supply method according to claim 11, comprising:

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