DE1526997C - Method for starting up a forced once-through steam generator and forced once-through steam generator - Google Patents

Description

is the enthalpy of the saturated steam discharged from the expansion tank.

In a further development of the invention, the method is preferably carried out so that gradually a pressure equalization between the two superheater sections is established by using the first superheater section exiting working fluid in a gradually increasing extent to the second superheater section supplied and the working medium supply from the expansion tank to the second superheater section on the one hand and gradually from the first superheater section to the flash tank on the other hand is throttled so that a substantially constant flow rate through the first superheater section until the connection between this and the expansion tank is interrupted is maintained.

Furthermore, the invention provides a once-through steam generator created for carrying out the method according to the invention, the one in bypass to one between a first superheater section and a second superheater section located shut-off valve arranged with in the lines from the outlet of the first superheater section to the expansion tank and from the expansion tank to the inlet of the second superheater section arranged control valves and according to the invention by an additional upstream of the first superheater section branching off, provided with a control valve} and leading to the expansion tank. management excels.

The invention alters the commissioning process simplified, and there are low costs as well as fast and controlled start-up allows adequate protection of the steam superheater section is ensured, with the thermal Stresses are always within acceptable limits and the greatest possible heat recovery is achieved during commissioning and operation with a low load.

The invention is illustrated below with reference to the drawing of a preferred exemplary embodiment explained in more detail.

In the power plant system shown, working fluid (feed water) is fed from a boiler feed pump 10 through a line 11 to a feed water high-pressure preheater 12. It then passes through a line 13 to the tubing of a once-through steam generator 14. This flow path contains an economizer 16, a steam generator section 17 and a superheater section 18. The superheater section 18 has a first superheater section ISA and a second superheater section 18 B, which are connected to one another by a Line 15 are connected. This contains a shut-off valve 20. The second superheater section 18 B is connected to the steam turbine 22 by a line 23 via the shut-off valve 24 and a control valve 26. A bypass line 21 with a shut-off valve 25 is provided to the shut-off valve 24. Fuel and air for combustion are supplied to the steam generator 14 through lines 27 and 28, respectively. The gaseous products of combustion, after passing the steam generator and superheater surfaces and the economizer, are exhausted through an outlet shown diagrammatically at 29. The valves 27 A and 28 A represent the usual control devices for fuel and air supply.

During normal operation, the working medium goes through the economizer 16, the one after the other Steam generator section 17 and the superheater section 18. The superheated steam arrives from the superheater section 18 through the pipeline 23 the high pressure stage of the steam turbine 22 and expands in this, whereupon the steam then through a

ίο pipe 30 exits to a main condenser 31, where it is condensed for return to the feed water system at a low pressure. The condensate passes from the condenser via a pipe 32 to a pump 33, from which it passed through a pipeline 34 and a low-pressure feedwater preheater 36 to a degasser 37 will. The condensate passes from the degasser through a line 38 to the suction side of the feed pump 10 for the purpose of returning to the steam generator.

In parallel to the shut-off valve 20 between the first and second superheater sections, an expansion tank 42 is provided, the inlet side of which is connected to the outlet of the first superheater section 18 A and the steam outlet of which is connected to the inlet of the second superheater section 18 B via shut-off valves 41, 4 and 50, respectively is, which are in the line 39 A, 55 and 60, respectively. In addition, there is a line 39 with a throttle valve 41, one end of which is connected to the line 19

. and the other end opens into the expansion tank 42, which separates the diverted working fluid into steam and water. Provision is made to the vapor of the flash chamber through a line 60 to the secondary superheater section 18 B to conduct. This line 60 contains a control valve 50 and a check and check valve 50 A. Its inlet end is connected to the expansion tank 42 and its outlet end at a point between the valve 20 and the superheater 18 B to the line 15. The valve 20 is bypassed by a pipeline 15 ^ 4 which contains a pressure reducing valve 20 ^ 4 and is connected with one end at a point upstream of the valve 41.4 to the line 55 and opens into this, while the opposite end at one Place is connected downstream with respect to the valve 50 to the line 60 and opens into this.

A vent through a line 49 is provided from the expansion tank, which controls the water level contains in the degasser regulating valve 51 and located between the expansion tank 42 and the Degasser 37 extends. Furthermore, a branch line 52 is provided which contains a valve 53 and with one end at a point upstream of valve 51 to conduit 49 and the opposite End is connected to the capacitor 31. The fume cupboard also has a branch line 65, which includes a valve 70 and has one end at a point upstream of the Valve 53 to line 52 and at the opposite end to the housing of the feedwater preheater 12 is connected.

The steam connections from the flash tank to the high pressure feed water preheater, the degasser and the turbine stuffing boxes supply steam for these components during commissioning, whereby heat is returned for the cycle

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is won. Thus, a conduit 54, controlled by a valve 56, extends between the flash tank 42 and the housing of the preheater 12. A conduit 57 with a valve 58 is referenced with one end at a point upstream of the valve 56 is connected to the line 54 and at its opposite end to the degasser 37. A line 59, which is controlled by a valve 61, leads from the expansion tank to the turbine stuffing boxes. A steam line 62 containing a valve 63 and from which Expansion tank 42 leads to the condenser 31, acts by the fact that it removes any outflow Allow excess steam to condenser 31, as a pressure control for the flash tank 42.

With a typical cold start-up of the power plant system shown, about a quarter the full load amount of working fluid through the boiler feed pump 10 via the degasser 37 through the line 11, the preheater 12, the line 13, the economizer 16, the steam generator section 17 and the line 39 is conveyed to the expansion tank 42. The shut-off valve 20, the pressure reducing valve 20.4, the valve 41Λ, the shut-off valve 24 and the shut-off valve 25 in the bypass are closed so that there is no flow through the superheater section 18 takes place. The valve 41 is adjusted so that it the full load pressure at the outlet of the Maintains steam generator section during commissioning.

From the expansion tank 42 water flows through the line 49 to the degasser 37 and then to, back to the feed pump 10. At the beginning the VerP valve 51 is set so that it the water level in the Keeps relaxation tank below normal. Then the heating is initiated and the temperature of the gas, entering superheater 18 is maintained at about 538 ° C. Since the enthalpy of the fluid entering the expansion tank increases increases, more residual heat is introduced into the degasser, reducing the pressure in the degasser and expansion tank increases. When the degasser reaches about 1.4 at, valve 51 begins to close and that Control valve 70 for the level in the expansion tank opens so that there are drains from the expansion tank can flow to the preheater 12 to reduce the heat loss, the 'preheater drains then pass through a line 71 to the capacitor 31. The line 71 is controlled by a valve 72. After 1.4 at in the degasser are reached, the valve 51 controls the degasser pressure, and the control valve 70 for the level of the expansion tank now controls the expansion tank water level. When the expansion tank water level exceeds the normal water level, the valve 53 opens to the excess water to derive to the capacitor. The valve 70 is also controlled so that it is at high The water level in the preheater 12 closes.

As the temperature of the water entering the flash tank increases, it becomes steam available and the pressure in the flash tank continues to increase until the gland steam control valve opens 61 is reached. At this point, separated steam is passed through line 59 and valve 61 to seal the Turbine headed. When the turbine is sealed, the condenser vacuum can be drawn or set will. As the enthalpy of the fluid continues to rise, the expansion tank pressure decreases until the opening pressure of the valve 58 adjusting the steam in the degasser is reached. To this At this point, the flash tank pressure is about 5.27 atm, and steam from the flash tank goes via lines 54 and 57 to degasser 37 until the degasser pressure reaches about 1.76 atm. to this time the valve 51 is closed because it has a set point of 1.4 at degasser pressure, and the valve 70 is open so that more water is diverted to the preheater 12 and from there via the Line 71 reaches the capacitor 31. This increases the feed water temperature and heat by using the flash tank steam to degasser 37 and flash tank drain water recovered in the high pressure preheater 12. When the expansion tank pressure 3.5 to 5.6 at above the pressure at which the degasser is supplied with the amount of Steam is saturated, opens the steam control valve 56 for the high pressure feedwater preheater, so that excess steam is diverted to the housing of the preheater 12. Because the expansion tank pressure continues to rise, the pressure in the preheater 12 will increase and so will the feed water temperature increase and recover more heat.

While the effluent is passed from the steam generator section 17 in the initial phase of start-up through the conduit 39 to the flash tank 42, the valve is held closed 41.4, until the working medium temperature at the inlet to the valve exceeds 41.4 15O ⁰ C. By controlling the valve 41A in this way , it will never be subjected to the severe damaging stress of the cold water pressure drop. When the working medium temperature at the inlet of the valve 41 exceeds the value of 150 ° C, the valve is opened to a predetermined smallest possible position 41.4, so that a portion of the effluent from the steam generating portion by the first superheater section 18 A, and then through conduit 39 A is passed to the line 39 in order to flow to the expansion tank 42 together with the working medium which arrives directly from the steam generator section 17 to the line 39. The valve 41 A is held in this minimum setting until the working medium temperature at the valve inlet is such that its corresponding enthalpy is approximately 566 kcal / kg. After the working fluid entering the valve 41 A is in this state, the valve opening is adjusted so that a. such set temperature point is maintained while valve 41 is adjusted to maintain the full load pressure at the outlet of the first superheater section during start-up. For example, the temperature set point is the valve 41.4 415 ⁰ C for a full-load operating pressure of 246 atm and 374 ° C for a full-load operating pressure of 169 atm in the first superheater section 18 A.

The passage of the working fluid through the first superheater section 18 A and the shunt 39 A to the flash tank 42 causes the absorbed through the first superheater section heat enters the flash tank. In older systems, the outflow from the first superheater section was sequentially through the second

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Superheater section and a turbine bypass the full load is the maximum operating pressure of the condenser, so that the heat expansion tank 42 is about 70 atmospheres. In order to increase the sorption of the first superheater section, the pressure in the second superheater section did not reach the expansion tank. By passing the over the flash tank pressure, steam heat absorption of the first superheater section in Fig. 5 must be passed through the pressure reducing valve 20 A to the flash tank, where it is recovered. Accordingly, the valve 20 A is opened until the unit can be operated at a given pressure of the second superheater section is heated up somewhat faster than the heating power or is the same as that of the expansion tank. At this time, heated with a lower heating power. the steam flow from the expansion tank stops when the expansion tank pressure approaches io tank to the second superheater section 18 B 21 atm, the valve 50 is opened, thereby ceasing and the valve 50 A closes by backflushing the expansion tank steam through the line action. At this time, the flow to the 60, the second superheater section 18 B and the expansion tank consists only of the difference between the main steam line 23 to a valve-controlled start-up flow and that which can flow to the drain line 66, whereby the main 15 via the pressure reducing valve 20 A directly to the steam line and the second superheater section Toggle second superheater section 18 proceeds B. During the be warmed. The discharge line 66 starts from an opening of the valve 20 A , the valve 41 A is so located above the seat of the shut-off valve 25, and controlled that it closes its discharge can be passed to the condenser 31 by a comparable value. So will the flow be through the first. 20 Superheater section 18 A essentially constant. If the heating continues, the voltage release increases. The valve 41 A is controlled so that there is voltage tank pressure. Achieving the pressure that keeps the outflow temperature of the first superheater section temperature and the flow rate of the steam at a set value so that its enthalpy predetermined by the expansion tank 42 is approximately the same as that which is suitable for the turbine , then 25 enthalpy of the saturated steam of the expansion, the steam flow is directed into the turbine 22 and is container. Since the flow in the first Uberhitzerdie flow through the drain line 66 interrupted portion 18 A is held constant, and since the surfaces. At this point in time, the expansion enthalpy of the tank pressure in the second superheater section is approximately 35 atmospheres. The steam flow to 18 B entering steam is kept constant, the turbine with the turbine stop valve 30, an appropriate 25 is controlled without changes in temperature, thereby making it possible that the 'and controlled transition from the inflow into steam supply to the turbine with the valves 26 the second superheater section is wide open from the expansion. This leads to a uniform expansion tank to which the inflow takes place, which is derived from the heating of the valve cone, valve housing, valve = 'first superheater section,
boxes and the housing area of the first turbine 3S The next step in the loading of the turbine stage. The valve 25 is controlled to throttle the steam, the increase in the pressure of the second overpressure below a value which is sufficient to bring the heater section to its full load value. There one to turn the turbine. Any excess steam such pressure is increased when the throttle in the flash tank is in a fixed position via line 62, valves 26 are delivered to condenser 31, valve 40 proportionally increasing the flow of steam to the turbine. 63 is set by the expansion tank pressure. In the practical version, the throttle is set. The opening size of valve 63 is used to set valves 26 so that they supply a turbine as an indication of the amount of steam that is available in the expansion load at maximum expansion tank pressure vessel to increase the turbine speed or so that the turbine load is about 30% of the load available. 45 Full load at full load pressure and the same throttle - Since the selector valve setting of the first superheater section is 18 A. For example, the heat absorbed during the start-up operation is used for the operation of the tank with a maximum value of steam generation, lower heating power of 70 atmospheres are required during start-up than with earlier start-up throttle valves are set so that they are a system where they Turbine load of approximately 8% of full load were used to superheat the steam. At a predetermined load point of the door - 30% at full load throttle pressure of 246 atm.
transferred to the valve 26. When the turbine is loaded to the pressurization of the second superheater About 8% of the maximum continuous power, 55 section 18 B is by gradual opening of it is normally brought about in Partialbogen supply valve 2OA. Because the valve 20A is switched over by simultaneously opening the valve 25 and closing all of the steam at a high specific pressure of the valve 26. The valve volume can now be processed, and because the outflow of the 24 is wide open and the valve 25 is closed, valve 20 A is at the relatively small volume. From this point on, it is desired that door 60 men of the secondary superheater section 18 B gebine continue to charge, the throttle valve 26 is conducting, the pressure rises herein as a function in a specified setting, to the throttling of such a valve opening almost instantaneous temperature drop at valve 26 almost constant bar. This pressure dependency can hold as a display. A load increase will be used by cost increases to the setting of the Druckredugerung to correct the vapor pressure in the second superheater 65 for ornamental valve 20 A. The result is a section 18 B and adequate and controlled pressurization of the main steam line 23. second superheater section 18 B, because the Aufhei with an amount of steam to the turbine of about 8% Zung speed, the outflow from the

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second superheater section and the setting of the on, and the pressure in the expansion tank valve 20 ^ 4 parallel to each other within narrow limits and the bypass system falls completely. can be effected. Normal turbine taps replace the extraction, the first superheater section is live and the discharge flows for the ISA are at a constant pressure, so that degassing and feedwater preheating. To this its heat storage does not change. Point in time, the shut-off valve 20 can be opened wide

During the pressurization of the second overpressure and the valve 20 A are closed,
During the period of time after which the expander set point of the outlet temperature of the first expansion tank reaches its normal operating pressure, superheater section that controls the setting of the auxiliary io any steam that regulates the expansion tank circuit valve 41 A is set in this way Be that beyond that which follows the door's natural heat absorption parameters, binenabdichtung, degassing and feed water in front of the first superheater section. When heating up and for turbine operation is required, valve 41 A is completely closed at about 10% of the turbine load due to the expansion tank overpressure control, and is discharged via valve 63 to the condenser. During this value, the first superheater section becomes - a cold start, little or no steam intake is effective in superheating the steam, current to the condenser is available,
while the production of steam in it gradually decreases. start-up is essentially the same

If the valve 20 ^ 4 is wide open, the 20 before as for a cold start-up with the off valve 41 is closed, and the entire flow would take that the heating power is higher goes directly to the superheater. So listen to the higher steam temperatures which get the Flows to and from the flash tank exit the second superheater section.

1 sheet of drawings

Claims (3)

1 2 applied to the pressure prevailing at normal load Claims:. is and the working medium behind a first over hitzer section in a bypass to a between 1. Method for starting a forced the first and a second superheater section through-flow steam generator, with the steam generator 5 lying shut-off valve arranged expansion generator To start up, a smaller container than the full container is routed, of which the volume contained therein is discharged Amount of working fluid with the different steam the. second superheater section the pressure prevailing at normal load and the separated liquid working medium to the and the working fluid is fed behind a first inlet of the steam generator and after the heater-superheater section in a bypass to an io range of a predetermined start-up state that between the first and a second over shut-off valve is opened to allow working fluid from Heater section lying shut-off valve arranged- the first superheater section to the second superheater net Relaxation tank is passed by section bypassing the relaxation tank to supply the steam separated in it to the ters. second superheater section and the separated 15 From Dürr announcements No. 1 from September dene liquid working fluid at the entrance of 1956 and US Pat. No. 2,989,038 is a ,. Steam generator supplied and after reaching the method of the aforementioned type basically one predetermined start-up state the loan known, with during the start-up from the shut-off valve is opened to work fluid from the cold state of the steam first in a entersten Superheater section bypassing the 20 spanner is directed where steam and entrained Expansion tank to the second superheater water are separated from each other and from where feed section, by which the steam is fed to a superheater section, draws that part of the working equipment before In addition, it is also from the US patentdem first superheater section in the Entspan-'schrift 3 183 896 known, a steam-water separation vessel is directed and to use the derived 35 ner, in which the from a first over-part is continuously dimensioned so that the - heater section escaping steam is partially low-enthalpy which is knocked out of the first superheater section, while an antes exiting working fluid approximately equal to that part of the steam from the steam-water enthalpy des from the flash tank separator via a second superheater section of the discharged saturated steam is. ; 30 turbine is supplied for heating. 2. The method as claimed in claim 1, characterized in that considerable amounts occur in these known methods indicates that gradually a pressure equalization difficulties in controlling the steam temperature between the two superheater sections on start-up. is made by the from the first Überr .. ^ - At the beginning of the transition of the work equipment Working fluid escaping from the heater section in all- 35 from the first superheater section to the second gradually increasing the second super-superheater section, partially bypassing the Heated section supplied and the working medium expansion tank namely occur in the second supply from the expansion tank to the second superheater section due to the now changed Superheater section on the one hand and from the first changed the amount and temperature of the Superheater section to the expansion tank 40 menden working medium uncontrollable temperature on the other hand, it is gradually throttled, so that turret changes on. These make up both in the '' an essentially constant flow rate of steam outlet temperature as well as in the material - disadvantageously noticeable due to the first superheater section up to the un- temperature of the superheater, Interruption of the connection between this and beyond result due to the changing the expansion tank is maintained. 45 th amount, which also with a changed temperature 3. Forced once-through steam generator for through-temperature in the second superheater section, supply of the method according to claim 1 or 2 additional changes in the steam outlet temperature, with one in bypass to one between a there additional storage heat of the second superheater, -first superheater section and a second zerabschnittes the steam temperature influenced.
The object of the invention, on the other hand, is to create an orderly expansion tank with in the Lei process for starting a forced flow from the output of the first superheater exhaust generator, in which the temperature cut to the expansion tank and from the steam to the for the second superheater expansion tank is adapted to the inlet of the second cut necessary temperature in the stage of the superheater section arranged control valve, in which steam len, characterized by an additional branching off from the first superheater section by bypassing the first superheater section (18 A). of the expansion tank is introduced directly into the second region provided with a control valve (41) and superheater section in order to prevent the second superheater section leading to the expansion tank (42) from becoming too hot (39). ... - ^6o changes, especially before temperature shocks, to protect. This task is compared with the one mentioned at the beginning The method according to the invention is achieved in that a part of the working fluid before the first superheater The invention relates to a method for starting 65 section is passed into the expansion vessel and ren of a once-through steam generator, whereby the part to be diverted is continuously dimensioned in such a way that the steam generator for start-up is less than that of the enthalpy from the first superheater Full load amount of working fluid is roughly the same as that of some of the exiting working fluid