JP2017089570A - Combined cycle plant, its control device and operational method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a chimney outlet temperature of discharged gas discharged out of a discharged heat recovery boiler while restricting a reduction of a power generating efficiency to be kept more than a specified temperature at a combined cycle plant, a control device of the combined cycle plant and an operation method for the combined cycle plant.SOLUTION: This invention comprises: a gas turbine 11 having a compressor 21, a combustor 22 and a turbine 23; a discharged heat recovery boiler 12 for generating steam by the discharged heat of the discharging gas obtained from the gas turbine 11; a steam turbine 13 driven by steam generated by the discharged heat recovery boiler 12; a condensed water bypass line 54 bypassing a fuel economizer 34 at the discharged heat recovery boiler 12 to flow the condensed water to a downstream side; a flow rate adjustment valve 55 arranged at the condensed water bypass line 54; and a control device 60 for releasing the flow rate adjustment valve 55 when surrounding atmosphere temperature is higher than a specified surrounding atmosphere temperature.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a combined cycle plant including a gas turbine, an exhaust heat recovery boiler, and a steam turbine, a control apparatus for the combined cycle plant, and an operation method of the combined cycle plant.

  In the combined cycle power generation, first, the gas turbine is driven by using natural gas as a fuel to generate the first power generation, and then the exhaust heat recovery boiler recovers the energy of the gas turbine exhaust gas to generate steam, The steam turbine is driven by the steam to generate power for the second time, and the combined cycle plant is a power plant for executing the combined cycle power generation.

  In the combined cycle plant, the temperature of the exhaust gas discharged from the smoke projecting port of the exhaust heat recovery boiler tends to decrease when the atmospheric temperature increases in the summer. This is due to the characteristic of the heat exchanger that when the atmospheric temperature increases, the exhaust gas temperature of the gas turbine entering the exhaust heat recovery boiler increases, so that the gas temperature at the exhaust heat recovery boiler outlet decreases. And if the temperature of the exhaust gas discharged | emitted from a smoke protrusion port falls, the diffusibility of the exhaust gas discharged | emitted from a chimney will fall. Therefore, even when the atmospheric temperature is high, such as in summer, the temperature of the exhaust gas discharged from the smoke outlet becomes more than the regulation value by controlling the temperature of the exhaust gas from the exhaust heat recovery boiler Is required.

  As what solves such a problem, there exist some which were described in the following patent document, for example. In the combined power plant described in the patent document, the pressure in the drum is increased by the regulating valve at the inlet of the steam turbine so that the detected temperature of the exhaust gas temperature detector is maintained at a set temperature or higher.

JP 2010-121559 A

  In the combined power plant of Patent Document 1 described above, the temperature of the exhaust gas discharged from the smoke projection port of the exhaust heat recovery boiler is controlled by increasing the pressure in the drum. However, when the pressure in the drum is increased by the steam control valve, the amount of steam supplied to the steam turbine is greatly reduced, and power generation efficiency may be reduced.

  The present invention solves the above-described problem, and a combined cycle plant capable of maintaining the smoke protrusion temperature of exhaust gas discharged from the exhaust heat recovery boiler at a predetermined temperature or higher while suppressing a decrease in power generation efficiency, It aims at providing the control apparatus of a combined cycle plant, and the operating method of a combined cycle plant.

  In order to achieve the above object, a combined cycle plant of the present invention includes a gas turbine having a compressor, a combustor, and a turbine, an exhaust heat recovery boiler that generates steam by exhaust heat of exhaust gas from the gas turbine, A steam turbine driven by steam generated by the exhaust heat recovery boiler, a bypass line that bypasses the economizer in the exhaust heat recovery boiler and flows condensate downstream; and an on-off valve provided in the bypass line; And a control device for opening the on-off valve when the atmospheric temperature is higher than a predetermined temperature set in advance.

  Therefore, when the atmospheric temperature rises, the temperature of the exhaust gas discharged from the smoke outlet in the exhaust heat recovery boiler decreases, but when the atmospheric temperature is higher than the predetermined temperature, the on-off valve opens the bypass line to A part of the water flows to the bypass line and the flow rate of the condensate flowing to the economizer is reduced, the amount of exhaust gas heat recovered by the condensate is reduced, and the exhaust gas temperature is prevented from decreasing. Can be controlled. As a result, the smoke protrusion temperature of the exhaust gas discharged from the exhaust heat recovery boiler can be maintained at a predetermined temperature or higher while suppressing a decrease in power generation efficiency.

  In the combined cycle plant of the present invention, the control device increases the opening of the on-off valve in accordance with an increase in the atmospheric temperature.

  Therefore, by increasing the opening of the on-off valve according to the increase in the atmospheric temperature, even if the atmospheric temperature varies, the flow rate of the condensate flowing through the bypass line is adjusted according to the variation in the atmospheric temperature. The temperature of the exhaust gas can be maintained above the regulation value.

  In the combined cycle plant of the present invention, the control device adjusts the opening degree of the on-off valve in a part or all of the operating range of the atmospheric temperature.

  Therefore, by adjusting the opening of the on-off valve in part or all of the operating range of the atmospheric temperature, the reduction in power generation efficiency due to exhaust gas temperature control is suppressed while maintaining the exhaust gas temperature at the smoke outlet at the regulated value. be able to.

  In the combined cycle plant of the present invention, a recirculation line is provided for returning a part of the condensate that has passed through the economizer to the upstream side of the economizer, and the bypass line is a condensate by the recirculation line. The upstream side from the return position is connected to the downstream side from the condensate intake position by the recirculation line.

  Therefore, by returning a part of the condensate that has been recovered by heat recovery in the economizer to the upstream side of the economizer via the recirculation line, it is possible to suppress the lowering of the condensate, It is possible to prevent the generation of rust inside the exhaust heat recovery boiler due to the formation of droplets of contained water, and to reduce the temperature of the exhaust gas without greatly reducing the temperature of the condensate flowing through the recirculation line. Can be suppressed.

  In the combined cycle plant of the present invention, a condensate temperature detector for detecting the temperature of the condensate flowing into the economizer is provided, and the control device is configured such that when the atmospheric temperature is higher than the predetermined temperature, According to the condensate temperature detected by the condensate temperature detector, the flow rate of the condensate returned by the recirculation line is adjusted to increase.

  Therefore, the condensate temperature supplied to the economizer inlet can be increased, and the decrease in the exhaust gas temperature can be suppressed while suppressing the decrease in the flow rate of the condensate supplied to the economizer.

  In the combined cycle plant of the present invention, a condensate flow rate detector for detecting the flow rate of condensate flowing into the economizer is provided, and the control device is configured to perform the operation when the atmospheric temperature is higher than the predetermined temperature. According to the condensate flow rate detected by the condensate flow rate detector, the flow rate of the condensate returned by the recirculation line is adjusted to increase.

  Therefore, the condensate temperature supplied to the economizer inlet can be increased, and the decrease in the exhaust gas temperature can be suppressed while suppressing the decrease in the flow rate of the condensate supplied to the economizer.

  The control apparatus for a combined cycle plant according to the present invention includes a bypass line that flows condensate by bypassing a economizer in the exhaust heat recovery boiler in a combined cycle plant including a gas turbine, an exhaust heat recovery boiler, and a steam turbine. And an open / close valve provided in the bypass line, and the open / close valve is opened when the atmospheric temperature is higher than a predetermined temperature set in advance.

  Therefore, by opening the bypass line with the open / close valve when the atmospheric temperature is higher than the predetermined temperature, a part of the condensate flows to the bypass line and the flow rate of the condensate flowing to the economizer decreases. The amount of exhaust gas heat recovered is reduced, and a decrease in the temperature of the exhaust gas is suppressed, and the temperature of the exhaust gas can be maintained at or above the regulation value. As a result, the smoke outlet temperature of the exhaust gas discharged from the heat recovery boiler can be maintained at a predetermined temperature or higher while suppressing a decrease in power generation efficiency.

  The combined cycle plant operating method of the present invention is a combined cycle plant comprising a gas turbine, an exhaust heat recovery boiler, and a steam turbine, wherein the exhaust water is discharged when the atmospheric temperature is higher than a predetermined temperature. It is characterized by flowing around the economizer in the heat recovery boiler.

  Therefore, by opening the bypass line with the open / close valve when the atmospheric temperature is higher than the predetermined temperature, a part of the condensate flows to the bypass line and the flow rate of the condensate flowing to the economizer decreases. The amount of exhaust gas heat recovered is reduced, and a decrease in the temperature of the exhaust gas is suppressed, and the temperature of the exhaust gas can be maintained at or above the regulation value. As a result, the smoke protrusion temperature of the exhaust gas discharged from the exhaust heat recovery boiler can be maintained at a predetermined temperature or higher while suppressing a decrease in power generation efficiency.

  According to the combined cycle plant, the combined cycle plant control device, and the combined cycle plant operating method of the present invention, the bypass line is opened by the on-off valve when the atmospheric temperature is higher than the predetermined temperature, so that a decrease in power generation efficiency is suppressed. However, the smoke outlet temperature of the exhaust gas discharged from the exhaust heat recovery boiler can be maintained at a predetermined temperature or higher.

FIG. 1 is a schematic configuration diagram illustrating a combined cycle plant of the present embodiment. FIG. 2 is a schematic configuration diagram illustrating the control apparatus for the combined cycle plant of the present embodiment. FIG. 3 is a graph showing the smoke outlet exhaust gas temperature with respect to the atmospheric temperature of the present embodiment. FIG. 4 is a graph showing the bypass flow rate with respect to the atmospheric temperature of the present embodiment. FIG. 5 is a graph showing the smoke outlet exhaust gas temperature with respect to the atmospheric temperature of the modified example of the present embodiment. FIG. 6 is a graph showing the bypass flow rate with respect to the atmospheric temperature in the modified example of the present embodiment.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of a combined cycle plant, a combined cycle plant control device, and a combined cycle plant operating method according to the present invention will be described in detail with reference to the accompanying drawings. In addition, this invention is not limited by this embodiment, and when there are two or more embodiments, what comprises combining each embodiment is also included.

  FIG. 1 is a schematic configuration diagram illustrating a combined cycle plant of the present embodiment, and FIG. 2 is a schematic configuration diagram illustrating a control apparatus for the combined cycle plant of the present embodiment.

  In the present embodiment, as shown in FIG. 1, the combined cycle plant 10 includes a gas turbine 11, an exhaust heat recovery boiler (HRSG) 12, and a steam turbine 13.

  The gas turbine 11 includes a compressor 21, a combustor 22, and a turbine 23, and the compressor 21 and the turbine 23 are coupled to each other by a rotating shaft (rotor) 24 so as to be integrally rotatable. The compressor 21 compresses the air taken in from the air intake line 25. The combustor 22 mixes and combusts the compressed air supplied from the compressor 21 through the compressed air supply line 26 and the fuel gas supplied from the fuel gas supply line 27. The turbine 23 is rotationally driven by the combustion gas supplied from the combustor 22 through the combustion gas supply line 28. The generator 29 is provided coaxially with the compressor 21 and the turbine 23, and can generate power when the turbine 23 rotates.

  The exhaust heat recovery boiler 12 generates steam by exhaust heat of the exhaust gas discharged from the gas turbine 11 (turbine 23) via the exhaust gas discharge line 31. The exhaust heat recovery boiler 12 includes a superheater 32, an evaporator 33, and a economizer 34. As the exhaust gas from the gas turbine 11 introduced from the gas inlet of the exhaust heat recovery boiler 12 rises inside, steam is generated by performing heat recovery in the order of the superheater 32, the evaporator 33, and the economizer 34. To do.

  Therefore, the feed water heated by the economizer 34 is sent to the steam drum 37 through the feed water line 36, and the feed water in the steam drum 37 is communicated with the evaporator 33 via the drum precipitation line 38 and the drum ascending line 39. It is heated by circulating in to produce steam. The steam generated by the steam drum 37 is sent to the superheater 32 via the saturated steam line 40 and is heated there. A flow rate adjustment valve 41 is provided in the water supply line 36.

  The steam turbine 13 is driven by steam generated by the exhaust heat recovery boiler 12, has a turbine 42, and a generator 43 is connected coaxially with the turbine 42. The steam generated by the superheater 32 is supplied to the turbine 42 via the steam supply line 44, and the generator 43 can generate power by rotating the turbine 42. A flow rate adjusting valve 45 is provided in the steam supply line 44.

  The steam discharged from the turbine 42 is supplied to the condenser 47 through the steam discharge line 46. The condenser 47 has a function of condensing the recovered steam with cooling water (such as seawater) and returning it to water (condensate). The condenser 47 sends the generated condensate to the economizer 34 via the condensate supply line 48. A condensate pump 49 is provided in the condensate supply line 48.

  Therefore, when operating the combined cycle plant 10, the compressor 21 compresses air in the gas turbine 11, and the combustor 22 mixes and supplies the supplied compressed air and fuel gas for combustion. Then, the turbine 23 is rotationally driven by the combustion gas supplied from the combustor 22, and the generator 29 generates power. Further, the exhaust gas discharged from the gas turbine 11 (turbine 23) is sent to the exhaust heat recovery boiler 12. The feed water heated by the economizer 34 is sent to the steam drum 37 and circulated between the evaporator 33 and heated to generate steam. The steam generated by the steam drum 37 is sent to the superheater 32 and superheated, and the superheated steam is sent to the steam turbine 13. The turbine 42 is rotationally driven by the superheated steam, and the generator 43 generates power. The steam used in the turbine 42 is cooled by cooling water to become condensate, and is returned to the economizer 34 by a condensate pump 49.

  By the way, in the combined cycle plant 10 configured as described above, when the atmospheric temperature increases in summer or the like, the temperature of the exhaust gas discharged from the smoke projecting port of the exhaust heat recovery boiler 12 tends to decrease. When the temperature of the exhaust gas discharged from the smoke outlet decreases, the diffusibility of the exhaust gas discharged from the chimney decreases. For this reason, even if the atmospheric temperature fluctuates, it is necessary to maintain the temperature of the exhaust gas discharged from the chimney of the exhaust heat recovery boiler 12 above the regulation value.

  As shown in FIGS. 1 and 2, the exhaust heat recovery boiler 12 includes a superheater 32 (secondary superheater 32 a and primary superheater 32 b), an evaporator 33, and a economizer 34 in the flow direction of the exhaust gas. Arranged in order. The economizer 34 is arranged on the most downstream side in the flow direction of the exhaust gas, and the exhaust gas heat-recovered by the economizer 34 is released from the chimney (not shown) to the outside (atmosphere). In the economizer 34, the downstream side of the condensate supply line 48 is connected to the base end side, and the upstream side of the water supply line 36 is connected to the distal end side.

  In the exhaust heat recovery boiler 12, when the temperature of the exhaust gas after the heat recovery by the economizer 34 is reduced at the end in the exhaust gas flow direction, the moisture contained in the exhaust gas becomes droplets, There is a risk of rusting due to adhesion to the heat exchanger of the charcoal 34. Therefore, a economizer recirculation line 51 is provided for returning the condensate that has been recovered by heat recovery in the economizer 34 to the inlet side of the economizer 34. The economizer recirculation line 51 has one end connected to the water supply line 36 and the other end connected to the condensate supply line 48. The economizer recirculation line 51 is provided with an economizer recirculation pump 52 and a flow rate adjustment valve 53. Therefore, by driving the economizer recirculation pump 52, a part of the condensate recovered by the economizer 34 can be returned from the water supply line 36 to the condensate supply line 48 through the economizer recirculation line 51. it can. At this time, the return amount of the condensate through the economizer recirculation line 51 can be adjusted by changing the opening degree of the flow rate adjustment valve 53.

  Further, a condensate bypass line 54 is provided in the exhaust heat recovery boiler 12 so that the condensate supplied to the economizer 34 bypasses the economizer 34 and flows downstream. The condensate bypass line 54 has one end connected to the condensate supply line 48 and the other end connected to the water supply line 36. In this case, one end of the condensate bypass line 54 is connected to the condensate supply line 48 upstream from the connection position (condensate return position) of the economizer recirculation line 51, and the other end is the economizer. The recirculation line 51 is connected to the water supply line 36 downstream of the connection position (condensate intake position). The condensate bypass line 54 is provided with a flow rate adjustment valve (open / close valve) 55. Therefore, by opening the flow rate adjustment valve 55, a part of the condensate supplied to the economizer 34 can be diverted from the condensate supply line 48 to the water supply line 36 through the condensate bypass line 54. At this time, the detour amount of the condensate through the condensate bypass line 54 can be adjusted by changing the opening degree of the flow rate adjustment valve 55.

  Therefore, when the condensate temperature supplied to the economizer 34 is lower than the preset first predetermined condensate temperature, the control device 60 recycles the economizer provided in the economizer recirculation line 51. The circulation pump 52 is driven and the flow rate adjustment valve 53 is opened. At this time, the control device 60 increases the rotation speed of the economizer recirculation pump 52 and increases the opening of the flow rate adjustment valve 53 as the condensate temperature is lower. That is, a condensate temperature detector 61 for detecting the condensate temperature flowing through the condensate supply line 48 for supplying condensate to the economizer 34 is provided, and the condensate temperature detector 61 detects the measured condensate temperature. Output to the control device 60. The condensate temperature detector 61 measures the condensate temperature downstream of the connection position of the economizer recirculation line 51 in the condensate supply line 48.

  Further, the control device 60 opens the flow rate adjustment valve 55 provided in the condensate bypass line 54 when the atmospheric temperature is higher than a predetermined atmospheric temperature set in advance. At this time, the controller 60 increases the opening degree of the flow rate adjustment valve 55 as the atmospheric temperature is higher. Here, the atmospheric temperature is the temperature of the air taken in from the air intake line 25 by the compressor 21 in the gas turbine 11 (gas turbine intake temperature). That is, an air temperature detector 62 that detects the temperature of the intake air flowing through the air intake line 25 is provided, and the air temperature detector 62 outputs the measured intake air temperature to the control device 60.

  FIG. 3 is a graph showing the smoke outlet exhaust gas temperature with respect to the atmospheric temperature of the present embodiment, and FIG. 4 is a graph showing the bypass flow rate with respect to the atmospheric temperature of the present embodiment.

  In the present embodiment, the control device 60 opens the flow rate adjustment valve 55 of the condensate bypass line 54 when the atmospheric temperature is higher than the predetermined atmospheric temperature. Here, as shown in FIG. 3, an atmospheric temperature-exhaust gas temperature map is set such that the smoke outlet exhaust gas temperature is equal to or higher than the regulation value with respect to the atmospheric temperature. And as shown in FIG. 4, the atmospheric temperature-bypass flow rate map which sets the bypass flow volume with respect to atmospheric temperature is set so that the smoke outlet exhaust gas temperature may become more than a regulation value with respect to atmospheric temperature.

  In the atmospheric temperature-exhaust gas temperature map of FIG. 3, the operating range of the exhaust heat recovery boiler 12 at the atmospheric temperature is the atmospheric temperature T1 ° C. to T3 ° C., and the atmospheric temperature T2 ° C. is the planned atmospheric temperature. Here, in the operation range from the atmospheric temperature T1 ° C. to T2 ° C., the exhaust gas temperature decreases as the atmospheric temperature rises, and becomes the regulation value at the planned atmospheric temperature T2 ° C. In the operating range from the atmospheric temperature T2 ° C. to T3 ° C., the exhaust gas temperature decreases as the atmospheric temperature increases, and becomes lower than the regulation value as indicated by the dotted line. The control device 60 adjusts the bypass flow rate to the condensate bypass line 54 by adjusting the opening degree of the flow rate adjustment valve 55 within the range. Here, the above-mentioned predetermined atmospheric temperature is the planned atmospheric temperature T2 ° C.

  That is, in the atmospheric temperature-bypass flow rate map of FIG. 4, the bypass flow rate is increased as the atmospheric temperature rises in the operating range from the atmospheric temperature T2 ° C. to T3 ° C. Then, the bypass flow rate from the condensate supply line 48 to the condensate bypass line 54 increases, while the condensate flow rate supplied from the condensate supply line 48 to the economizer 34 decreases. Therefore, in the economizer 34, the heat recovery amount of the exhaust gas due to the condensate is reduced, so that a decrease in the temperature of the exhaust gas is suppressed, and the temperature of the exhaust gas is maintained above the regulation value.

  Note that the atmospheric temperature-exhaust gas temperature map and the atmospheric temperature-bypass flow map are not limited to the above-described configuration. FIG. 5 is a graph showing the smoke outlet exhaust gas temperature with respect to the atmospheric temperature of the modified example in the present embodiment, and FIG. 6 is a graph showing the bypass flow rate with respect to the atmospheric temperature of the modified example in the present embodiment.

  In the present embodiment, the control device 60 opens the flow rate adjustment valve 55 of the condensate bypass line 54 when the atmospheric temperature is higher than the predetermined atmospheric temperature. In the atmospheric temperature-exhaust gas temperature map of FIG. 5, the operating range of the exhaust heat recovery boiler 12 at the atmospheric temperature is the atmospheric temperature T1 ° C. to T3 ° C., and the atmospheric temperature T1 ° C. is the planned atmospheric temperature. Here, the control device 60 adjusts the opening of the flow rate adjustment valve 55 in all operating ranges from the atmospheric temperature T1 ° C. to T3 ° C., thereby adjusting the bypass flow rate to the condensate bypass line 54. Here, the above-mentioned predetermined atmospheric temperature is the planned atmospheric temperature T1.

  That is, in the atmospheric temperature-bypass flow rate map of FIG. 6, the bypass flow rate is increased as the atmospheric temperature rises in all operating ranges from the atmospheric temperature T1 ° C. to T3 ° C. Then, the bypass flow rate from the condensate supply line 48 to the condensate bypass line 54 increases, while the condensate flow rate supplied from the condensate supply line 48 to the economizer 34 decreases. Therefore, in the economizer 34, the heat recovery amount of the exhaust gas due to the condensate is reduced, so that a decrease in the temperature of the exhaust gas is suppressed, and the temperature of the exhaust gas is maintained above the regulation value.

  In the combined cycle plant 10 configured as described above, as shown in FIGS. 1 and 2, the exhaust gas discharged from the gas turbine 11 is sent to the exhaust heat recovery boiler 12, and the superheater 32, the evaporator 33, After being recovered by the economizer 34, it is discharged from the chimney. At this time, the control device 60 constantly monitors the atmospheric temperature (gas turbine intake temperature), and when the atmospheric temperature is higher than the predetermined atmospheric temperature, opens the flow rate adjustment valve 55 and adjusts its opening. That is, the control device 60 sets the bypass flow rate according to the current atmospheric temperature using the atmospheric temperature-bypass flow rate map of FIG. 4 (or FIG. 6). If the current atmospheric temperature is lower than the predetermined atmospheric temperature (planned atmospheric temperature), nothing is done. On the other hand, if the current atmospheric temperature is equal to or higher than the predetermined atmospheric temperature, the opening degree of the flow rate adjustment valve 55 is set according to the set bypass flow rate. In this case, it is desirable to set in advance a map representing the relationship between the opening degree of the flow rate adjustment valve 55 and the bypass flow rate, and to set the opening degree of the flow rate adjustment valve 55 according to the bypass flow rate using this map.

  Then, the condensate bypass flow rate from the condensate supply line 48 to the condensate bypass line 54 increases, while the condensate flow rate supplied from the condensate supply line 48 to the economizer 34 decreases. Therefore, in the economizer 34, the decrease in the exhaust gas temperature is suppressed by reducing the heat recovery amount of the exhaust gas due to the condensate. That is, as shown in FIG. 3 (or FIG. 4), the condensate to the condensate bypass line 54 in the operating range from the atmospheric temperature T2 ° C to T3 ° C (or the operating range from the atmospheric temperature T1 ° C to T3 ° C). Since the bypass flow rate is adjusted, the temperature of the exhaust gas discharged from the chimney of the exhaust heat recovery boiler 12 is maintained above the regulation value.

  In the above-described embodiment, the control device 60 is configured to adjust the opening degree of the flow rate adjustment valve 55 provided in the condensate bypass line 54 when the atmospheric temperature is higher than the predetermined atmospheric temperature. However, the present invention is not limited to this configuration. For example, a condensate temperature detector 61 that detects the condensate temperature flowing through the condensate supply line 48 is provided, and the controller 60 detects that the condensate temperature detector 61 is in a state where the atmospheric temperature is higher than a predetermined atmospheric temperature. The rotational speed of the economizer recirculation pump 52 provided in the economizer recirculation line 51 and the opening degree of the flow rate adjustment valve 53 are adjusted according to the detected condensate temperature.

  As described above, the condensate temperature detector 61 detects the condensate temperature flowing through the condensate supply line 48 to the economizer 34, and the control device 60 determines that the condensate temperature supplied to the economizer 34 is the first. 1 The discharge force (rotation speed) of the economizer recirculation pump 52 is adjusted so that the predetermined condensate temperature is reached, and the opening of the flow rate adjustment valve 53 is adjusted. Therefore, when the atmospheric temperature is higher than the predetermined atmospheric temperature, the control device 60 first sets the condensate temperature supplied to the economizer 34 to the second predetermined condensate temperature higher than the first predetermined condensate temperature. In addition, the discharge force (rotation speed) of the economizer recirculation pump 52 is adjusted, and the opening degree of the flow rate adjustment valve 53 is adjusted.

  Then, the flow rate of the hot condensate supplied to the inlet side of the economizer 34 by the economizer recirculation line 51 increases, so that the condensate temperature supplied to the economizer 34 rises, and the exhaust heat is exhausted. A decrease in the temperature of the exhaust gas discharged from the chimney of the recovery boiler 12 is suppressed. Then, when the discharge force (rotational speed) of the economizer recirculation pump 52 is maximized and the opening degree of the flow rate adjusting valve 53 is maximized, a decrease in the temperature of the exhaust gas cannot be suppressed. The device 60 adjusts the opening degree of the flow rate adjustment valve 55 provided in the condensate bypass line 54.

  The control device 60 adjusts the discharge force of the economizer recirculation pump 52 according to the condensate temperature detected by the condensate temperature detector 61 and adjusts the opening of the flow rate adjustment valve 53. The configuration is not limited. That is, a flow rate detector 63 for detecting the flow rate of condensate flowing through the condensate supply line 48 is provided, and the control device 60 determines the flow rate of condensate supplied to the economizer 34 when the atmospheric temperature is higher than a predetermined temperature. The discharge force (rotation speed) of the economizer recirculation pump 52 is adjusted so that the condensate flow rate is obtained, and the opening of the flow rate adjustment valve 53 is adjusted.

  Moreover, the temperature detector which detects the temperature of the condensate which flows through the economizer recirculation line 51 is provided, and the control apparatus 60 has the condensate temperature of the economizer recirculation line 51 lower than a preset predetermined temperature. In this case, the discharge force of the economizer recirculation pump 52 and the opening degree of the flow rate adjustment valve 53 may be adjusted, or the opening degree of the flow rate adjustment valve 55 may be adjusted.

  When adjusting the discharge force of the economizer recirculation pump 52 and the opening of the flow rate adjustment valve 53 according to the condensate temperature and the condensate flow rate supplied to the economizer 34, the condensate temperature and the exhaust gas temperature It is desirable to grasp and map the relationship and the relationship between the condensate flow rate and the exhaust gas temperature in advance.

  As described above, in the combined cycle plant of the present embodiment, the gas turbine 11 having the compressor 21, the combustor 22, and the turbine 23, and the exhaust heat recovery that generates steam by the exhaust heat of the exhaust gas from the gas turbine 11. A boiler 12, a steam turbine 13 driven by steam generated by the exhaust heat recovery boiler 12, a condensate bypass line 54 that bypasses the economizer 34 in the exhaust heat recovery boiler 12 and flows downstream, and a condensate bypass A flow rate adjustment valve 55 provided in the line 54 and a control device 60 that opens the flow rate adjustment valve 55 when the atmospheric temperature is higher than a predetermined atmospheric temperature are provided.

  Therefore, when the atmospheric temperature is high, the heat recovery rate in the exhaust heat recovery boiler 12 is improved and the temperature of the exhaust gas discharged from the smoke outlet is lowered. However, when the atmospheric temperature is higher than the predetermined atmospheric temperature, the flow rate adjustment valve By opening the condensate bypass line 54 by 55, a part of the condensate flows into the condensate bypass line 54 and the flow rate of the condensate flowing into the economizer 34 is reduced. This reduces the temperature of the exhaust gas, and the exhaust gas temperature can be maintained at or above the regulation value. As a result, the smoke protrusion temperature of the exhaust gas discharged from the exhaust heat recovery boiler 12 can be maintained at a predetermined temperature or higher while suppressing a decrease in power generation efficiency.

  In the combined cycle plant of the present embodiment, the control device 60 increases the opening degree of the flow rate adjustment valve 55 in accordance with an increase in the atmospheric temperature. Therefore, even if the atmospheric temperature fluctuates, the flow rate of the condensate flowing through the condensate bypass line 54 is adjusted in accordance with the fluctuation of the atmospheric temperature, and the exhaust gas temperature can be maintained at or above the regulation value with high accuracy. Can do.

  In the combined cycle plant of the present embodiment, the control device 60 adjusts the opening degree of the flow rate adjustment valve 55 in a partial region or all regions in the operating range of the atmospheric temperature. Therefore, the control range can be narrowed and the control can be simplified by adjusting the opening degree of the on-off valve in a part of the operating range of the atmospheric temperature. Further, by adjusting the opening of the on-off valve in the entire operating range of the atmospheric temperature, the exhaust gas temperature can be maintained near the regulation value, and the heat recovery efficiency in the exhaust heat recovery boiler 12 can be improved. Can do.

  In the combined cycle plant of the present embodiment, a economizer recirculation line 51 for returning a part of the condensate that has passed through the economizer 34 to the upstream side of the economizer 34 is provided. The upstream side from the condensate return position by the recirculation line 51 is connected to the downstream side from the condensate intake position by the economizer recirculation line 51. Therefore, by reducing a part of the condensate that has been recovered by heat recovery in the economizer 34 to the upstream side of the economizer 34 through the economizer recirculation line 51, the low temperature of the condensate can be suppressed. It is possible to prevent the generation of rust due to the droplets of moisture contained in the exhaust gas. Moreover, the fall of the temperature of exhaust gas can be suppressed, without reducing the temperature of the condensate which flows through the economizer recirculation line 51.

  In the combined cycle plant of the present embodiment, a condensate temperature detector 61 that detects the temperature of the condensate flowing into the economizer 34 is provided, and the control device 60 restores the condensate when the atmospheric temperature is higher than a predetermined atmospheric temperature. It adjusts so that the flow volume of the condensate returned by the economizer recirculation line 51 may be increased according to the condensate temperature detected by the water temperature detector 61. Therefore, the condensate temperature supplied to the inlet of the economizer 34 can be increased, and the decrease in the exhaust gas temperature can be suppressed while the decrease in the flow rate of the condensate supplied to the economizer 34 is suppressed. it can.

  Moreover, in the control apparatus for the combined cycle plant of the present embodiment, the opening degree of the flow rate adjustment valve 55 is adjusted when the atmospheric temperature is higher than a predetermined atmospheric temperature. Therefore, the smoke outlet temperature of the exhaust gas discharged from the exhaust heat recovery boiler 12 can be maintained at a predetermined temperature or higher while suppressing a decrease in power generation efficiency.

  Further, in the operation method of the combined cycle plant of the present embodiment, when the atmospheric temperature is higher than a predetermined atmospheric temperature set in advance, the condensate bypasses the economizer 34 in the exhaust heat recovery boiler 12 and is steamed. I try to flow. Therefore, when a part of the condensate flows into the condensate bypass line 54, a decrease in the temperature of the exhaust gas is suppressed, and the temperature of the exhaust gas can be maintained above the regulation value. As a result, the smoke protrusion temperature of the exhaust gas discharged from the exhaust heat recovery boiler 12 can be maintained at a predetermined temperature or higher while suppressing a decrease in power generation efficiency.

  In the above-described embodiment, the exhaust heat recovery boiler 12 is configured by the superheater 32, the evaporator 33, and the economizer 34, but is not limited to this configuration, and the high pressure, the medium pressure, and the low pressure, respectively. It may be divided into two parts.

  Further, in the above-described embodiment, one gas turbine 11 and one steam turbine 13 are combined in the combined cycle system 10, but the rotation axis (rotor) may be coaxial or another axis. A plurality of gas turbines 11 and one steam turbine 13 may be combined.

DESCRIPTION OF SYMBOLS 10 Combined cycle plant 11 Gas turbine 12 Exhaust heat recovery boiler 13 Steam turbine 21 Compressor 22 Combustor 23 Turbine 29, 43 Generator 32 Superheater 33 Evaporator 34 Economy unit 36 Water supply line 37 Steam drum 42 Turbine 45 Flow control valve 47 Condenser 48 Condensate supply line 49 Condensate pump 51 Conservator recirculation line 52 Conservator recirculation pump 53 Flow control valve 54 Condensate bypass line 55 Flow control valve (open / close valve)
60 Control device 61 Condensate temperature detector 62 Air temperature detector 63 Flow rate detector

Claims (8)

A gas turbine having a compressor, a combustor, and a turbine;
An exhaust heat recovery boiler that generates steam by exhaust heat of exhaust gas from the gas turbine;
A steam turbine driven by steam generated by the exhaust heat recovery boiler;
A bypass line that bypasses the economizer in the exhaust heat recovery boiler and flows condensate downstream;
An on-off valve provided in the bypass line;
A control device for opening the on-off valve when the atmospheric temperature is higher than a predetermined temperature set in advance;
A combined cycle plant comprising:   2. The combined cycle plant according to claim 1, wherein the control device increases the opening of the on-off valve in accordance with an increase in the atmospheric temperature.   3. The combined cycle plant according to claim 2, wherein the control device adjusts an opening degree of the on-off valve in a partial region or all regions in the operating range of the atmospheric temperature.   A recirculation line is provided for returning a part of the condensate that has passed through the economizer to the upstream side of the economizer, and the bypass line is located upstream of the return position of the condensate by the recirculation line and the recirculation line. The combined cycle plant according to any one of claims 1 to 3, wherein the downstream side of the condensate intake position by the circulation line is connected.   A condensate temperature detector for detecting the temperature of condensate flowing into the economizer is provided, and the control device detects the condensate temperature detector when the atmospheric temperature is higher than the predetermined temperature. 5. The combined cycle plant according to claim 4, wherein the flow rate of the condensate returned by the recirculation line is adjusted to increase according to the condensate temperature.   A condensate flow detector for detecting the flow rate of condensate flowing into the economizer is provided, and the controller detects the condensate flow detector when the atmospheric temperature is higher than the predetermined temperature. 5. The combined cycle plant according to claim 4, wherein the flow rate of the condensate returned by the recirculation line is adjusted to increase in accordance with the condensate flow rate. In a combined cycle plant including a gas turbine, an exhaust heat recovery boiler, and a steam turbine,
A bypass line that bypasses the economizer in the exhaust heat recovery boiler and flows condensate;
An on-off valve provided in the bypass line,
Opening the on-off valve when the atmospheric temperature is higher than a predetermined temperature set in advance;
A control apparatus for a combined cycle plant. In a combined cycle plant including a gas turbine, an exhaust heat recovery boiler, and a steam turbine,
When the atmospheric temperature is higher than a preset predetermined temperature, the condensate flows around the economizer in the exhaust heat recovery boiler,
A method for operating a combined cycle plant.

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