KR101011554B1 - Power generation system and control method thereof - Google Patents

Abstract

An object of the present invention is to provide a power generation system and a control method of the power generation system which can prevent the pressure of the steam supplied to the steam utilization equipment from temporarily lowering beyond the allowable pressure range.

In this power generation system 20, when the steam flow rate into which the power generation device 32 is introduced is larger than the predetermined flow rate, the downstream steam pressure of the power generation device 32 is based on the detected pressure of the discharge pressure sensor 30. The steam flow rate passing through the power generation device 32 is controlled so as to be a second set pressure higher than the first set pressure of the pressure reducing valve 16 provided in the main pipe 14, and the introduced steam flow rate is up to the predetermined flow rate. When lowered, based on the detected pressure of the discharge pressure sensor 30, the downstream steam pressure of the power generator 32 is lower than the first set pressure of the pressure reducing valve 16 and is higher than 0 kPaG. The flow rate of the steam passing through the power generator 32 is controlled so as to be obtained.

Pressure Reducing Valves, Generators, Steam Generating Means, Pressure Reducing Valves Pressure Sensors, Discharge Pressure Sensors

Description

POWER GENERATION SYSTEM AND CONTROL METHOD THEREOF

The present invention relates to a power generation system and a control method of the power generation system.

Conventionally, a pressure reducing valve is provided, and a steam having a predetermined pressure is introduced into a power generation device from an upstream side of the pressure reducing valve in a main pipe for supplying steam generated by the steam generating means to a steam utilization facility, and generates power. There is known a power generation system for returning steam later to the downstream side of a pressure reducing valve in the main pipe and supplying it to a steam utilization facility (see Patent Document 1, for example).

6 shows the overall configuration of a conventional power generation system disclosed in Patent Document 1 above. As shown in FIG. 6, the steam generating means 100 is connected to the steam utilization facility 104 through the main pipe 102, and the pressure reducing valve 106 is provided in the main pipe 102. have. The introduction pipe 108 of the power generation system is connected to an upstream position of the pressure reducing valve 106 in the main pipe 102, and the introduction pipe 108 is connected to the driver 112 of the power generation device 110. It is connected to the entrance side. The discharge pipe 114 is connected to the downstream position of the pressure reducing valve 106 in the main pipe 102 from the outlet side of the driver 112 of the power generator 110. The generator 110 is provided with a generator 116 driven by the driver 112.

In this power generation system, steam sent from the steam generating means 100 is supplied to the steam utilization facility 104 through the main pipe 102 and the pressure reducing valve 106. On the other hand, steam is introduced into the driver 112 through the introduction pipe 108 from the main pipe 102 and the driver 112 is driven to generate power, and the steam after being used for the power generation is driven by the driver 112. It flows from the 112 through the discharge pipe 114 to the downstream of the pressure reduction valve 106 in the main pipe 102, and is supplied to the steam utilization facility 104.

[Patent Document 1] Japanese Patent Application Publication No. 2007-74894

By the way, in the power generation system as described above, the steam flow rate introduced into the driver 112 of the power generation device 110 may vary. When the flow rate of steam introduced into the driver 112 is too low, the driving of the driver 112 is stopped and all the steam supplied from the steam generating means 100 is passed through the main pipe 102. Control is generally performed. In this control, when the driver 112 stops, no steam flows to the downstream side, and the downstream steam pressure of the driver 112, that is, the downstream steam pressure of the pressure reducing valve 106 is set to the pressure of the pressure reducing valve 106. As a result, the pressure reducing valve 106 is opened to increase the flow rate of steam flowing through the main pipe 102 to the electric utility facility 104.

In this case, however, there is a problem that the pressure of the steam supplied to the steam utilization facility 104 temporarily deviates from the allowable pressure range and greatly decreases.

That is, in the above configuration, there is a time lag until the driver 112 is stopped and no steam flows downstream thereof, and the pressure reducing valve 106 is fully opened, and the period flows to the steam utilization facility 104. Since the steam flow rate greatly decreases, the pressure of the steam supplied to the steam utilization equipment 104 in this period temporarily decreases beyond the allowable pressure range.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to control the power generation system and the power generation system, which can prevent the pressure of the steam supplied to the steam utilization equipment from temporarily lowering beyond the allowable pressure range. To provide a way.

In order to achieve the above object, the power generation system according to the present invention has a pressure reducing valve, and is connected to a main pipe for supplying steam generated by steam generating means to a steam utilization facility, and generates electricity by using energy of steam. A power generation system, the inlet pipe connectable to an upstream side of the pressure reducing valve in the main pipe, the discharge pipe connectable to a downstream side of the pressure reducing valve in the main pipe, and the steam flow rate adjusting function; The power generation device which generates power by steam introduced through the introduction pipe from the gas pipe and discharges the steam used for the power generation to the main pipe via the discharge pipe, and the downstream side of the pressure reducing valve and the power generation device. A pressure detecting means for detecting a vapor pressure and a downstream of the pressure reducing valve based on the detected pressure of the pressure detecting means; And a pressure reducing valve controller for opening and closing the pressure reducing valve so that the steam pressure becomes the first set pressure, and the power generating device generates the power generation based on the detected pressure of the pressure detecting means when the flow rate of the introduced steam is greater than a predetermined flow rate. When the steam flow rate passing through the power generation device is controlled so that the downstream steam pressure of the device becomes a second set pressure higher than the first set pressure, while the introduced steam flow rate drops to the predetermined flow rate, Based on the detected pressure, the flow rate of the steam passing through the power generator is controlled so that the downstream steam pressure of the power generator is lower than the first set pressure and higher than 0 kPaG.

In this power generation system, when the steam flow rate at which the power generation device is introduced is larger than the predetermined flow rate, the steam flow rate passing through the power generation device so that the downstream steam pressure of the power generation device becomes a second set pressure higher than the first set pressure of the pressure reducing valve. While controlling the flow rate of the introduced steam flow rate to the predetermined flow rate, the downstream steam pressure of the power generation device passes through the power generation device so that the third set pressure is lower than the first set pressure and higher than 0 kPaG. Control the steam flow rate. As a result, when the steam flow rate introduced into the power generator is lowered to the predetermined flow rate, in parallel with the flow of steam through the power generator, the downstream steam pressure of the power generator, that is, the downstream steam pressure of the pressure reducing valve is set to the first set pressure. By controlling to the lower third set pressure, the pressure reducing valve is opened, and steam also flows through the pressure reducing valve. In this case, the steam flowing through each of the power generator and the pressure reducing valve to the downstream side is joined and supplied to the steam utilization facility. Therefore, unlike the conventional configuration, when the steam flow rate introduced into the power generation device drops to a predetermined flow rate, the power generation device is stopped and the pressure reducing valve is opened after the downstream steam pressure of the power generation device is lowered. The pressure of the steam to be supplied can be prevented from dropping temporarily beyond the allowable pressure range.

In the power generation system, the pressure detecting means includes a first pressure sensor provided on the downstream side of the pressure reducing valve in the main pipe and a second pressure sensor provided on the discharge pipe, and the pressure reducing valve controller includes the first pressure sensor. Preferably, the pressure reducing valve is opened and closed based on the detected pressure of the pressure sensor, and the power generation device controls the flow rate of steam passing through the power generation device based on the detected pressure of the second pressure sensor.

According to this configuration, since the pressure reducing valve controller can control the opening and closing of the pressure reducing valve based on the detected pressure of the first pressure sensor located near the downstream side of the pressure reducing valve, the pressure reducing valve can be precisely opened and closed. The downstream steam pressure of the pressure reducing valve can be precisely controlled. In addition, since the power generator can control the flow rate of steam passing through the power generator based on the detected pressure of the second pressure sensor located near the downstream side, the steam flow rate and the steam pressure flowing downstream of the power generator are accurate. Good control

The control method of the power generation system according to the present invention has a pressure reducing valve, is connected to a main pipe for supplying steam generated by the steam generating means to the steam utilization equipment, the control of the power generation system to generate power by using the energy of the steam A method, comprising: an introduction pipe connectable to an upstream side of the pressure reducing valve in the main pipe, a discharge pipe connectable to a downstream side of the pressure reducing valve in the main pipe, and a function of adjusting the steam flow rate; A power generation device is provided for generating electricity by steam introduced from the main pipe through the introduction pipe and discharging the steam used for power generation to the main pipe through the discharge pipe, and the steam introduced into the power generation device. When the flow rate is higher than the predetermined flow rate, the downstream steam pressure of the power generator is the first setting of the pressure reducing valve. While controlling the steam flow rate passing through the power generator so as to have a second set pressure higher than the pressure, when the steam flow rate introduced into the power generator drops to the predetermined flow rate, the downstream steam pressure of the power generator is reduced in pressure. The flow rate of steam passing through the power generator is controlled to be a third set pressure lower than the first set pressure of the valve and higher than 0 kPaG.

In the control method of this power generation system, when the steam flow rate introduced into the power generation device is higher than the predetermined flow rate, the steam passing through the power generation device so that the downstream steam pressure of the power generation device becomes a second set pressure higher than the first set pressure of the pressure reducing valve. While controlling the flow rate, when the steam flow rate introduced into the power generation device drops to the predetermined flow rate, the downstream steam pressure of the power generation device is lower than the first set pressure of the pressure reducing valve and higher than the 0 kPaG to the third set pressure. Control the flow of steam through the generator. As a result, when the flow rate of the steam introduced into the power generation device drops to the predetermined flow rate in the same manner as the operation of the power generation system, steam flows through the pressure reducing valve in parallel with the flow of the steam through the power generation device. Steam flowing through each of the device and the pressure reducing valve is joined and supplied to the steam utilization facility. For this reason, it is possible to prevent the pressure of the steam supplied to the steam utilization equipment from temporarily dropping beyond the allowable pressure range.

As described above, according to the present invention, it is possible to prevent the pressure of the steam supplied to the steam utilization equipment from temporarily lowering beyond the allowable pressure range.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows roughly the whole structure of the power generation system by one Embodiment of this invention. First, with reference to this FIG. 1, the structure of the power generation system by one Embodiment of this invention is demonstrated.

The power generation system 20 according to the present embodiment generates power by using the energy of steam generated by the steam generating means 10 and used in the steam utilization facility 12.

Specifically, this power generation system 20 is connected to a main pipe 14 for supplying steam generated by the steam generating means 10 to the steam utilization facility 12. This main pipe 14 is provided with a pressure reducing valve 16.

The said steam generating means 10 is comprised by the some boiler 10a connected to the steam flow path 14 in parallel.

The steam utilization facility 12 is, for example, a facility that uses steam having a predetermined temperature, such as a hot water heater, a heater, a bathroom facility, a dryer, a cleaning facility, a kitchen device, a sterilizer, and the like.

The power generation system 20 according to the present embodiment includes a pressure reducing valve pressure sensor 22, a pressure reducing valve controller 24, an introduction pipe 26, a discharge pipe 28, a discharge pressure sensor 30, and power generation. The apparatus 32 is provided.

The pressure reducing valve pressure sensor 22 is provided at a position near the downstream side of the pressure reducing valve 16 in the main pipe 14, and detects the vapor pressure at the position. This pressure reducing valve pressure sensor 22 is included in the concept of the 1st pressure sensor of this invention.

The pressure reducing valve controller 24 controls the opening and closing of the pressure reducing valve 16 based on the detected pressure of the pressure reducing valve pressure sensor 22.

Specifically, data of the detected pressure of the pressure reducing valve pressure sensor 22 is always input to the pressure reducing valve controller 24. In the pressure reducing valve controller 24, the first set pressure SV ₁ of the pressure reducing valve 16 is set. The pressure reducing valve controller 24 opens the pressure reducing valve 16 when the downstream steam pressure of the pressure reducing valve 16 detected by the pressure reducing valve pressure sensor 22 is lower than the first set pressure SV ₁ . When the downstream steam pressure of the pressure reducing valve 16 becomes equal to or greater than the first set pressure SV ₁ , the pressure reducing valve 16 is controlled to close. Thereby, the pressure reducing valve 16 by the pressure-reducing valve reducing valve controller 24 on the downstream side of the steam pressure (16) such that the first set pressure (SV ₁₎ is controlled to be opened and closed.

The introduction pipe 26 is configured to be connectable to an upstream position of the pressure reducing valve 16 in the main pipe 14, and introduces steam into the power generation device 32. An opening / closing valve 34 is provided in the vicinity of the connection portion with the main pipe 14 of the inlet pipe 26.

The discharge pipe 28 is configured to be connectable to a downstream side of the pressure reducing valve 16 in the main pipe 14, and allows steam discharged from the power generator 32 to flow into the main pipe 14. An opening / closing valve 36 is provided in the vicinity of a connection portion of the discharge pipe 28 with the main pipe 14. The on-off valve 36 and the on-off valve 34 provided in the inlet pipe 26 are simultaneously opened and closed, steam is introduced into the inlet pipe 26 from the main pipe 14, and through the power generator 32. The steam returned from the discharge pipe 28 to the main pipe 14 and the steam generated by the steam generating means 10 without introducing steam from the main pipe 14 into the inlet pipe 26 are all The state which flows into the steam utilization facility 12 through the main pipe 14 is mutually switched.

In addition, in the discharge pipe 28, the discharge pressure sensor 30 is provided on the downstream side of the power generation device 32 and at an upstream side of the on-off valve 36, and the discharge pressure sensor ( 30, the downstream steam pressure of the power generator 32 is detected. The discharge pressure sensor 30 is included in the concept of the second pressure sensor of the present invention. In the present embodiment, the pressure detecting means of the present invention is performed by the discharge pressure sensor 30 and the pressure reducing valve pressure sensor 22. This is composed.

The power generation device 32 is connected to the introduction pipe 26 and the discharge pipe 28, generates power by steam introduced from the main pipe 14 through the introduction pipe 26, and generates power. The steam after used in the above is discharged to the main pipe 14 through the discharge pipe 28. The power generation device 32 and the discharge pressure sensor 30 are provided in the housing 33 and are configured as one unit.

And the power generation device 32 has a function of adjusting the steam flow rate. Specifically, the power generator 32 includes a driver 38, a generator 40, a frequency converter 42, a drain separator 44, a flow regulating valve 46, and an emergency shutoff valve 48. ), An introduction pressure sensor 50, and a controller 52.

The driver 38 is driven by steam introduced through the introduction pipe 26, and is configured by, for example, various turbines, screw expanders, and the like.

The introduction pipe 26 is connected to the inlet side of the driver 38, and the discharge pipe 28 is connected to the outlet side of the driver 38. As a result, the driver 38 is driven by the steam introduced from the main pipe 14 through the inlet pipe 26, and the steam discharged from the driver 38 returns to the main pipe through the discharge pipe 28. It is supposed to be.

The drive shaft 38a of the driver 38 is connected to the rotary shaft 40a of the generator 40. As a result, when the driver 38 drives and the drive shaft 38a rotates, the rotational force of the drive shaft 38a is transmitted to the rotation shaft 40a of the generator 40, and the generator 40 drives to generate power. have.

Power generated in the generator 40 is introduced into the frequency converter 42. The frequency converter 42 converts the frequency of the power generated by the generator 40 into a desired frequency and outputs it. The power output from the frequency converter 42 is transmitted to the system 56 through an external transformer 54. Supplied.

The drain separator 44, the flow regulating valve 46, the emergency shutoff valve 48, and the introduction pressure sensor 50 are provided in the inlet pipe 26 with the open / close valve 34 and the driver 38. It is provided in this order from an upstream side in between.

The drain separator 44 is for separating the drain from the steam flowing through the inlet pipe 26.

The flow rate regulating valve 46 adjusts the flow rate of steam introduced into the driver 38 through the introduction pipe 26, and is configured to be open and closed control by the controller 52. In this embodiment, the flow volume of the steam passing through the power generator 32 is adjusted by the flow rate regulating valve 46.

The emergency shutoff valve 48 completely shuts off the inlet pipe 26 and can be controlled by the controller 52.

The introduction pressure sensor 50 detects the pressure of the steam introduced into the driver 38 through the introduction pipe 26.

The controller 52 derives an appropriate rotational speed based on the detected pressures of the introduction pressure sensor 50 and the discharge pressure sensor 30. The frequency converter 42 outputs a rotation speed control signal to the generator 40 based on the proper rotation speed derived by the controller 52, so that the generator 40 has an appropriate rotation speed according to the steam flow rate. It is supposed to be operated.

In the present embodiment, the power generation device 32 passes through the power generation device 32 by controlling the opening and closing control of the flow rate adjusting valve 46 based on the detected pressure of the discharge pressure sensor 30 by the controller 52. The steam flow rate is controlled.

Specifically, the controller 52 outputs a control output value corresponding to the steam flow rate required by the steam utilization facility 12 to the flow rate control valve 46, and the opening degree of the flow rate control valve 46 according to the control output value. Is controlled to adjust the steam flow rate introduced into the power generation device 32, that is, the steam flow rate flowing through the power generation device 32 to the downstream side and supplied to the steam utilization facility 12.

In the controller 52, the capacity control range is set as the range of the steam flow rate to be introduced to drive the driver 38, and the second set pressure as the set value of the downstream steam pressure of the power generation device 32. SV ₂ and the third set pressure SV ₃ are set.

As shown in FIG. 2, the second set pressure SV ₂ has a predetermined pressure difference with respect to the first set pressure SV ₁ of the pressure reducing valve 16, and the first set pressure SV ₁ . It is set to higher pressure. The controller 52 discharges when the control output value output to the flow regulating valve 46, that is, the steam flow rate introduced into the power generation device 32 is greater than the predetermined flow rate set slightly higher than the flow rate of the lower limit of the capacity control range. by controlling the opening degree of the flow rate adjusting valve 46 to the downstream vapor pressure of the sensor 30, developing device 32 on the basis of the detected pressure such that the second predetermined pressure (SV _2), generator (32) Control the steam flow through it.

And since the downstream side of the electric power generation device 32 and the downstream side of the pressure reduction valve 16 are connected, the flow regulating valve 46 and the pressure reduction valve 16 of the electric power generation device 32 are those power generation devices ( 32) and opening / closing control is performed based on the same vapor pressure on the downstream side of the pressure reducing valve 16. At this time, the second set pressure SV ₂ serving as a reference for opening / closing control of the flow regulating valve 46 is predetermined with respect to the first set pressure SV ₁ serving as a reference for opening / closing control of the pressure reducing valve 16. Since the pressure difference is set to a high pressure, hunting between the pressure reducing valve 16 and the flow regulating valve 46 is prevented.

The third set pressure SV ₃ is set to a pressure lower than the first set pressure SV ₁ of the pressure reducing valve 16 and higher than 0 kPaG, that is, an atmospheric pressure. The controller 52 reduces the flow rate of steam required by the steam utilization facility 12 and the control output value outputted to the flow rate adjustment valve 46 to reduce the flow rate of steam introduced into the power generation device 32 to the predetermined flow rate. When it is lowered, the set value of the downstream steam pressure of the power generator 32 is changed from the second set pressure SV ₂ to the third set pressure SV ₃ . As a result, the controller 52 opens the flow regulating valve 46 such that the downstream steam pressure of the power generator 32 becomes the third set pressure SV ₂ based on the detected pressure of the discharge pressure sensor 30. The degree is controlled to control the steam flow rate through the power generation device 32.

In addition, the controller 52 further reduces the control output value output to the flow regulating valve 46, and when the steam flow rate introduced into the power generation device 32 falls to the lower limit of the flow rate control range, the flow rate control valve. The flow rate of steam introduced into the power generator 32 by closing 46 is set to 0, and the driver 38 is stopped.

Fig. 2 shows the relationship between the steam flow rate passing through the power generation device 32 and the downstream set pressure of the pressure reducing valve 16 and the power generation device 32 for explaining the control method of the power generation system 20 according to the present embodiment. Is shown. Next, with reference to FIG. 1 and FIG. 2, the control method of the power generation system 20 by this embodiment is demonstrated.

First, steam generated by the steam generating means 10 is introduced into the driver 38 of the power generation device 32 from the main pipe 14 through the inlet pipe 26, and the driver 38 is driven by the steam. Is driven and power generation is being performed in the generator 40. The steam discharged from the driver 38 is returned to the downstream side of the pressure reducing valve 16 in the main pipe 14 through the discharge pipe 28 and supplied to the steam utilization facility 12.

In this state, the steam flow rate introduced into the power generation device 32, that is, the steam flow rate introduced into the driver 38, becomes a flow rate higher than the predetermined flow rate (see Fig. 2) within the capacity control range of the driver 38. . At this time, the controller 52 of the power generator 32 controls the opening degree of the flow regulating valve 46 based on the detected pressure of the discharge pressure sensor 30, and the downstream steam pressure of the power generator 32 is mainly controlled. than the first set pressure (SV ₁₎ of the pressure reducing valve 16 of the pipe 14 has controlled the steam flow flowing toward the second high pressure setting (SV ₂₎ downstream through the power generator 32 so that the.

As a result, the downstream steam pressure of the pressure reducing valve 16 detected by the pressure reducing valve pressure sensor 22 is also set to the second set pressure SV ₂ higher than the first setting pressure SV ₁ of the pressure reducing valve 16. The pressure reducing valve 16 is closed. For this reason, the main pipe 14 is interrupted | blocked, and all the steam produced | generated by the steam generating means 10 is supplied to the steam utilization facility 12 via the power generation apparatus 32. As shown in FIG.

Next, when the steam flow rate required by the steam utilization facility 12 is lowered, the control output value output from the controller 52 to the flow rate adjustment valve 46 is lowered, thereby passing through the power generation device 32. At the same time as the steam flow rate decreases, the downstream steam pressure of the power generator 32 detected by the discharge pressure sensor 30 also decreases.

When the control output value output from the controller 52 to the flow regulating valve 46, that is, the steam flow rate introduced into the power generator 32 drops to the predetermined flow rate, the controller 52 causes the The set value of the downstream steam pressure is changed to the third set pressure SV ₃ lower than the first set pressure SV ₁ of the pressure reducing valve 16 and higher than 0 kPaG. Thereby, the power generation device 32 is controlled by the controller 52 so that the downstream steam pressure of the power generation device 32 becomes the third set pressure SV ₃ based on the detected pressure of the discharge pressure sensor 30. The opening degree of the flow regulating valve 46 is controlled to control the steam flow rate passing through the power generation device 32.

When the downstream steam pressure of the power generation device 32 is controlled to be the third set pressure SV ₃ , the downstream steam pressure of the pressure reducing valve 16 is also changed from the second set pressure SV ₂ to the third set pressure ( SV ₃ ). In the process, when the downstream steam pressure of the pressure reducing valve 16 falls below the first set pressure SV ₁ , the pressure reducing valve 16 is opened by the pressure reducing valve controller 24 accordingly. As a result, the steam is supplied to the steam utilization facility 12 through the pressure-reducing valve 16 in parallel with the supply of steam to the steam utilization facility 12 through the power generation device 32.

Thereafter, when the flow rate of steam introduced into the power generation device 32 is further lowered to the flow rate of the lower limit of the capacity control range, the flow rate adjusting valve 46 is closed by the controller 52 to the power generation device 32. The introduced steam flow rate becomes zero, and the driver 38 is stopped. As a result, the steam flow rate supplied to the steam utilization facility 12 through the power generator 32 becomes zero. On the other hand, at this point, the pressure reducing valve 16 is opened at a predetermined opening, and all the steam generated by the steam generating means 10 passes through the main pipe 14 and the pressure reducing valve 16. Supplied to. In this state, the pressure reducing valve controller 24 reduces the pressure so that the downstream steam pressure of the pressure reducing valve 16 becomes the first set pressure SV ₁ based on the detected pressure of the pressure reducing valve pressure sensor 22. The valve 16 is controlled to open and close.

By the way, unlike the control method of this embodiment mentioned above, when the steam flow volume introduce | transduced into the power generation device 32 like the comparative example shown in FIG. 3 fell to the flow volume of the lower limit of the said capacity | capacitance control range, At the time when the steam flow rate passing through the power generation device 32 reaches zero, the pressure reducing valve 16 is opened to allow steam to flow to the steam utilization facility 12, the driver 38 stops and Since there is a time lag until the pressure-reducing valve 106 is completely opened after the steam does not flow downstream, the steam pressure supplied to the steam utilization facility 12 temporarily decreases significantly during that time. Thereby, as shown in FIG. 4, the steam pressure supplied to the steam utilization equipment 12 may fall temporarily beyond the allowable pressure range of the steam utilization equipment 12, and may fall.

On the other hand, in the present embodiment, the control as described above is performed, so that the pressure reducing valve 16 is opened when the steam flow rate introduced into the power generation device 32 drops to the predetermined flow rate as shown in FIG. Since the steam flow rate introduced into the power generation device 32 decreases from the predetermined flow rate to the flow rate of the lower limit of the capacity control range, the steam flowing through the power generation device 32 and the pressure reducing valve ( The steam flowing through 16 joins and is supplied to the steam utilization facility 12. When the steam flow rate introduced into the power generation device 32 drops to the flow rate of the lower limit of the capacity control range, since the pressure reducing valve 16 is already opened to a predetermined opening degree, the pressure reducing valve 16 starts to open. Then, even if there is a time lag, the vapor pressure supplied to the steam utilization facility 12 is not lowered by the control method according to the comparative example, and as shown in FIG. 5, the steam pressure supplied to the steam utilization facility 12 is utilized. It is maintained within the allowable pressure range of the installation 12.

As described above, in the present embodiment, when the steam flow rate at which the power generation device 32 is introduced is greater than the predetermined flow rate, the downstream steam pressure of the power generation device 32 is determined by the pressure reducing valve 16 of the main pipe 14. When the steam flow rate passing through the power generator 32 is controlled so as to be the second set pressure SV ₂ higher than the first set pressure SV ₁ , while the introduced steam flow rate drops to the predetermined flow rate, the power generator The downstream steam pressure of 32 passes through the power generator 32 so that the third set pressure SV ₃ is lower than the first set pressure SV ₁ of the pressure reducing valve 16 and higher than 0 kPaG. Control the steam flow rate. As a result, when the steam flow rate introduced into the power generation device 32 drops to the predetermined flow rate, the downstream steam pressure of the power generation device 32, that is, the pressure reducing valve 16 in parallel with the flow of the steam through the power generation device 32. By controlling the downstream steam pressure of) by the third set pressure SV ₃ lower than the first set pressure SV ₁ , the pressure reducing valve 16 is opened, and steam also flows through the pressure reducing valve 16. In this case, the steam flowing downstream through each of the power generator 32 and the pressure reducing valve 16 joins and is supplied to the steam utilization facility 12. For this reason, the pressure of the steam supplied to the steam utilization equipment 12 can be prevented from falling temporarily beyond the permissible pressure range.

Moreover, in this embodiment, the pressure reduction valve controller 24 is the pressure reduction valve 16 based on the detected pressure of the pressure reduction valve pressure sensor 22 provided downstream of the pressure reduction valve 16 in the main pipe 14. Control the opening and closing of the power generation device 32, the controller 52 of the power generation device 32 by opening and closing the flow rate control valve 46 on the basis of the detected pressure of the discharge pressure sensor 30 provided in the discharge pipe (28). To control the flow of steam through For this reason, since the pressure reduction valve controller 24 can open and close the pressure reduction valve 16 based on the detected pressure of the pressure reduction valve pressure sensor 22 located downstream of the pressure reduction valve 16, a pressure reduction valve The opening and closing control of the 16 can be precisely controlled, and the downstream steam pressure of the pressure reducing valve 16 can be controlled with high precision. In addition, since the power generator 32 can control the flow rate of steam passing through the power generator 32 based on the detected pressure of the discharge pressure sensor 30 located near the downstream side, the power generator 32 It is possible to precisely control the steam flow rate and the steam pressure flowing downstream of.

In addition, embodiment disclosed this time is an illustration and restrictive at all points, and should be considered. The scope of the present invention is disclosed by the claims rather than the description of the above-described embodiments, and includes all changes within the scope and meaning equivalent to the claims.

For example, instead of the pressure reducing valve pressure sensor 22 and the discharge pressure sensor 30, one common pressure sensor is provided downstream of the pressure reducing valve 16 and the power generation device 32, and the pressure sensor. The pressure reducing valve controller 24 may open and close the pressure reducing valve 16 on the basis of the detected pressure, and the controller 52 may control the opening and closing of the flow control valve 46.

In addition, by using the driver 38 together with the flow rate adjustment valve 46, the controller 52 may control the rotation speed of the driver 38 to control the steam flow rate passing through the power generator 32.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows roughly the whole structure of the power generation system by one Embodiment of this invention.

2 is a diagram showing a relationship between a steam flow rate passing through a power generation device and a downstream set pressure of a pressure reducing valve and a power generation device for explaining a control method of a power generation system according to an embodiment of the present invention.

Fig. 3 is a diagram showing changes in the passage steam flow rate of the power generation device and the passage steam flow rate of the pressure reducing valve in one embodiment and comparative example of the present invention.

4 is a view showing a change in the steam pressure supplied to the steam utilization equipment in the power generation system of the comparative example of the present invention.

5 is a view showing a change in the steam pressure supplied to the steam utilization facility in the power generation system according to the embodiment of the present invention.

Fig. 6 is a diagram schematically showing the overall configuration of a power generation system according to a conventional example.

<Description of the symbols for the main parts of the drawings>

10 steam generating means

12: steam equipment

14: main piping

16: pressure reducing valve

20: power generation system

22: pressure reducing valve pressure sensor (first pressure sensor)

24: pressure reducing valve controller

26: introduction tube

28: discharge pipe

30: discharge pressure sensor (second pressure sensor)

32: power generation device

Claims (3)

It is a power generation system which has a pressure reducing valve, is connected to the main piping which supplies the steam produced | generated by the steam generating means to a steam utilization facility, and uses the energy of steam, and An introduction pipe connectable to an upstream side of the pressure reducing valve in the main pipe; A discharge pipe connectable to a downstream position of the pressure reducing valve in the main pipe; A power generation device having a function of adjusting the flow rate of steam and generating power by steam introduced from the main pipe through the inlet pipe, and discharging steam after being used for power generation to the main pipe through the discharge pipe; Pressure detecting means for detecting a vapor pressure at a downstream side of the pressure reducing valve and the power generator; A pressure reducing valve controller configured to open and close the pressure reducing valve so that the downstream steam pressure of the pressure reducing valve becomes a first set pressure based on the detected pressure of the pressure detecting means; When the flow rate of steam introduced is greater than a predetermined flow rate, the power generation device is such that the downstream steam pressure of the power generation device becomes a second set pressure higher than the first set pressure based on the detected pressure of the pressure detecting means. While controlling the flow rate of steam passing through the gas, the downstream steam pressure of the power generation device is lower than the first set pressure on the basis of the detected pressure of the pressure detecting means when the introduced steam flow rate drops to the predetermined flow rate. And a power generation system for controlling the flow rate of steam passing through the power generator so as to have a third set pressure higher than 0 kPaG. The said pressure detection means is a 1st pressure sensor provided downstream of the said pressure reduction valve in the said main piping, and the 2nd pressure sensor provided in the said discharge pipe, The pressure reducing valve controller controls the opening and closing of the pressure reducing valve based on the detected pressure of the first pressure sensor, And the power generation device controls a steam flow rate passing through the power generation device based on the detected pressure of the second pressure sensor. It is a control method of the power generation system which has a pressure reduction valve, is connected to the main piping which supplies the steam produced | generated by the steam generating means to a steam utilization facility, and uses the energy of steam, and An inlet pipe connectable to an upstream position of the pressure reducing valve in the main pipe, and a discharge pipe connectable to a downstream side of the pressure reducing valve in the main pipe, are provided, and have a function of adjusting steam flow rate. A power generation device is provided for generating electricity by steam introduced through the introduction pipe from the gas pipe and discharging the steam used for the power generation to the main pipe through the discharge pipe. When the flow rate of steam introduced into the power generator is greater than a predetermined flow rate, the flow rate of steam passing through the power generator is controlled so that the downstream steam pressure of the power generator is a second set pressure higher than the first set pressure of the pressure reducing valve. On the other hand, when the steam flow rate introduced into the power generator is lowered to the predetermined flow rate, the downstream steam pressure of the power generator is lowered to the third set pressure lower than the first set pressure of the pressure reducing valve and higher than 0 kPaG. Control method of the power generation system to control the flow rate of steam passing through the power generation device.

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