EP3105440A1

EP3105440A1 - Pressure regulating device for a gas supply system of a gas turbine plant

Info

Publication number: EP3105440A1
Application number: EP15712550.1A
Authority: EP
Inventors: Rainer Bickert
Original assignee: Siemens AG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2014-03-31
Filing date: 2015-03-13
Publication date: 2016-12-21
Also published as: CN106170617A; JP6286580B2; US20170159570A1; WO2015150056A1; JP2017520704A

Abstract

The invention relates to a pressure regulating device (1) for a gas supply system (3) of a gas turbine plant (5), comprising a pressure reduction unit (7) for reducing the pressure of an inflowing gas, in particular a combustion gas, a compressor system (9) for compressing the in-flowing gas and connected in parallel to the pressure reduction unit (7), and a regulating valve (24) arranged on the output side (22) of the pressure reduction unit (7), via which valve the pressure reduction unit (7) can be fluidically separated on the output side from the compressor system (9). The invention further relates to a gas supply system (3) for a gas turbine plant (5) comprising a corresponding pressure regulating device (1) and a method for pressure regulation of a gas, in which a gas supply system (3) with a corresponding pressure regulating device (1) is used.

Description

description

Pressure control device for a gas supply system of a gas turbine plant

The invention relates to a pressure control device for a gas supply system of a gas turbine plant. Furthermore, the invention relates to a gas supply system for a gas turbine plant, as well as a method for pressure regulation of a gas.

A gas turbine is used as part of a gas turbine plant for power generation by the combustion of gaseous fuels, such as natural gas. The gas turbine is operated in this case by means of the fuel and drives ih ^¬ hand, one or more generators. When using natural gas streams for operating a gas turbine, in particular the inlet pressure of the natural gas is to be considered. Since the sites of fuel gas production are usually far away from the place of consumers, a corresponding Anliefe ^¬ tion is necessary. For this purpose, the fuel gas is first compressed to high transport pressures and the gas pressure is set only at the je ^¬ perige consumption point to the required input pressure value. This inlet pressure is often not constant, but fluctuates.

To address this problem, pressure control devices are used in current practice, which are able to keep the pressure of the fuel gas, regardless of the fluctuations in the inlet pressure within predetermined limits in one or more controlled systems. For the operation of a gas turbine, for example, an operating pressure in a range between 36 bar and 40 bar is required. Previous concepts provide this to equip a Druckregelvorrich ^¬ processing gas supply of a gas turbine plant with two pa ^¬ rallel enabled control systems. One of the control systems is designed as a pressure reduction unit, which throttles the pressure of the incoming fuel gas to a preset value. As a second control system, a compressor system is used, which serves to compress the Brennga ^¬ ses and by means of which the pressure of the fuel gas when required, so if an undesirable pressure drop is expected or already recorded, can be increased again. Through a combination of both control systems, it is possible to set the necessary operating pressure at the input of the gas turbine for all gas inlet conditions.

While both the pure Reduzierbetrieb a pressure control device, ie the sole operation of the pressure reduction unit at high inlet pressure of an incoming fuel gas, and the pure compressor operation, so the sole operation of the compressor system at low inlet pressure of the incoming fuel gas, are relatively easy to control ge ^¬ staltet the Switchover phase between the two Regels ^¬ s ^¬ temen so far problematic. Since the parallel-connected control systems work in a common collector, they mutually influence each other during the switching phase, ie when switching between the reducing mode and the compressor mode.

Thus, during the switching of the pressure reduction unit on the compressor unit only guarantee this The required technical ^¬ te compression of the fuel gas, if it is able to "push away" the pressure reducing or suppressing the reduced mode. During the switching process in the opposite direction the pressure reduction unit can resume its operation only when the part of the

Compressor system no more compressor pressure is present.

In addition to maintaining a regulated form, a gas turbine also requires a limitation of the pressure gradients in the ancillary system. Therefore, a pressure control device for a gas supply system of a gas turbine must also be designed so that pressure shocks are avoided ^¬ particular during the switching. In conventional pressure control devices therefore the control systems, ie in particular the compressor system and the pressure reduction unit, shut-off valves and self-medium-operated control valves are assigned, which interact during the switching phase in ge ^¬ suitable manner. For example, the output side of the compressor system a motor-driven blocking valve ^¬ til be provided, wherein the output-side pressure of the compressor system as a back pressure on the integrated Druckreduzierein- used by its own medium-operated control valves acts.

When switching from the reduction operation to the compressor operation, the shut-off valve is opened, while the Regelventi ^¬ le close due to the now increased back pressure. Open vice versa ^¬ the control valves for closing the blocking valve tils the compressor system. The system dynamics is then be ^¬ true by the response times of the shut-off valves and control valves, and can only be optimized by selecting suitable verfüg ^¬ cash valves. However, it is not possible to speak of a regulated or constant pressure gradient during the switching phase.

Further, in a pressure regulating device as described above, the need remains to set the pressure setting of

To set the compressor unit higher than the pressure setting value of the pressure reducing unit. The pressure difference needed is calculated mainly consist of the Geräteparame ^¬ tern of the valves used in the pressure control device. The required pressure setting value of the compressor system is approximately 3 bar to 4 bar above the pressure setting value of the pressure reduction unit. Through this pressure increase in the switching, the reducing unit can be taken out of service (close the control valves) and thus sufficient for the operation of the gas turbine plant stable operation ^¬ pressure suitable height to ensure the existing system,

However, due to the necessary pressure difference of about 3 bar to 4 bar between the setting value of the pressure reducing unit and the setting value of the compressor system, the combustion gas in the compressor system generally compressed to a pressure which is higher than would be necessary for operating a Gasturbi ^¬ nena position. The compressor system is to be designed for egg ^¬ NEN pressure bar is 3 to 4 lent actual bar above the required operating pressure of the gas turbine.

It is therefore a first object of the invention to provide an improved over the prior art pressure control device for a gas supply system of a gas turbine plant.

A second object of the invention is to provide a gas supply system ^¬ with a corresponding pressure regulating device.

A third object of the invention is to provide a method for pressure regulation of a gas, in particular a fuel gas, which makes use of the advantages of the improved pressure control device.

The first object of the invention is inventively achieved by a pressure control device for a gas supply system of a gas turbine plant comprising a pressure reducing unit for pressure reduction of a flowing gas, in particular a fuel gas, a parallel peeled ^¬ te to the pressure reducing unit compressor unit for compression of the incoming gas, as well as on the output side of the Pressure reducing unit to ^¬ ordered control valve comprises, via the pressure reduction unit on the output side fluidly separable from the compressor system.

In a first step, the invention is based on the fact that, due to the pressure difference between the setpoint value of the compressor installation and the setting value of the pressure reduction unit, an unnecessarily high compressor capacity is required, which causes unnecessary additional costs and the energy required to operate a pressure regulator undesirably increased. In a second step, the invention based on the consideration of that the pressure increase so far required for the compressor unit can be omitted, if the reciprocal influencing of the control systems used to regulate the pressure, ie the pressure reducing unit and the compressor unit, currency ^¬ rend the switchover is prevented.

In a third step, the invention recognizes that this is possible by a fluidic separability of the control systems, which can be implemented in a simple and effective manner by integrating a control valve arranged at the outlet side of the pressure reduction unit into the pressure control device. By such a control valve, the pressure can be shut off if required on the output side of the compressor plant ^¬ reduction unit.

During the changeover from reduction mode to compressor mode, the pressure on the output side of the pressure reduction unit can be lowered slowly and in a controlled manner and in compressor operation the first control system (pressure reduction unit) can be disconnected from the second control system (compressor unit). This ensures that the compressor system does not have to push away the function of the pressure reduction unit, in particular in the switchover phase, so that the overall compressor pressure can be set lower than before.

By the required lower output pressure of the compressors sor-ianlage a lower compressor power is erforder ^¬ Lich, whereby the operating costs of the compressor system can be reduced. According to prevailing calculations, the drive power of the compressor system is reduced by a value of 3 on the basis of a typical gas turbine system consumption of 16 kg / s at an inlet pressure of approx. 20 bar and a final pressure of 30 to 40 bar when lowering the compressor setting value bar at about 300 kW. In a multistage compressor system can thus be dispensed play a compressor stage at ^¬.

Furthermore, no special backflow-proof, back-pressure-resistant control valves are required that were previously used as control valves in the compressor system and the pressure reduction unit. Since the pressure reducing unit can be completely separated from the rest of the system by the output side arrangement of the control valve in the operation of the compressor system, can now be used on cheaper and easier-to-use control valves.

The controlled changeover from the reduction mode to the compressor mode and vice versa is by selecting a suitable closing or opening law for actuating the

Control valve, ie via the pressure gradient in the downstream piping, easily controlled. The control valve is controlled accordingly via an actuator ^¬ . In other words, the control valve allows during the switchover adjustability of Druckgra ^¬ served in the downstream pipeline system, ie on the output side of the compressor system and the Druckreduzierein ^¬ ness. In a preferred development of the pressure control device, the pressure reduction unit and the compressor system lead on the outlet side via a T branch piece into a common manifold, wherein the control valve is arranged between the pressure reduction unit and the T branch piece. At this point, during a switching phase, the separation of the

Pressure reduction of the compressor system under maintenance ^¬ tion of the predetermined pressure gradients are technically comparatively easy and manageable achieved In an advantageous embodiment of the invention, the pressure setting value in the compressor system essentially ^¬ chen the pressure set value in the pressure reduction unit. If the pressure reduction unit is equipped with a main control line and an formed ner reserve track distance, the pressure set value in the compressor system preferably corresponds to the low ^¬ th pressure setting value in the pressure reduction, ie the value specified for the reserve controller. In other words, the final pressure of the compressor system is at the pressure level of the pressure reducing unit, the hitherto necessary adjustment of a pressure difference between the two control systems can be omitted by the integrated control valve. Conveniently, the control valve is designed as a control ball valve. Control ball valves are particularly suitable for ge ^¬ rings pressure differences, as prevr ^¬ rule in the switching phase between the pressure reduction unit and the compressor system. The pressure loss of a control ball valve in the open state is almost zero.

The pressure reduction unit preferably comprises two redundant pressure control sections connected in parallel. Here, a pressure controlled systems is before ^¬ Trains t used as a main controller and the other pressure control system as a backup controller. The backup controller is to this is ^¬ to a pressure value is, which is lower than the pressure set the master. As long as the main controller is working properly and no other fault occurs in the main line, the back pressure is in an area where the reserve controller remains closed, for example via self-medium-operated control valves used there. Is that sinking?

Back pressure, the reserve controller automatically opens for self-medium-operated control valves. In other words, in a preferred embodiment, the two controlled systems are staggered with respect to one another, wherein the pressure setting values differ.

The second object of the invention is achieved by a gas supply system for a gas turbine plant, comprising a gas supply, a flow with the gas supply ^¬ technically coupled pressure control described above direction, and a fluidically coupled to the pressure control device supply line to the gas turbine plant.

The specified gas supply system makes it possible, by the controlled switching between the pressure reduction of a fuel gas in the reduction mode and the compression of a

Fuel gas in compressor operation, the permanent provision of a fuel gas at a suitable pressure level for Ver ^¬ combustion in a gas turbine plant with a comparatively low cost and energy consumption.

Preferably, in the gas supply is a conditioning stage and in the supply line to the gas turbine plant, a Nachbereitungs ^¬ stage connected. The treatment or post-treatment stage is used to prepare the fuel gas, for example, in terms of its temperature or in terms of the content of foreign particles for the pressure control device and for the gas turbine plant accordingly. In an advantageous embodiment, the treatment stage comprises a filter unit and / or a preheating unit. The treatment stage is upstream of the pressure control device. The filter unit serves to pre-purify the fuel gas, for example by removing unwanted particles. In the pre-heating unit, which is the filter inlet ^¬ ness expediently downstream of flow, the pre-cleaned fuel gas is preheated in order to avoid condensate ^¬ sation in relaxation and finally processing for setting the desired pressure of the Druckregelvorrich- so fed to the pressure reduction unit and the compressor unit.

After passing the pressure control device, the fuel gas is fed to a post-processing stage downstream of the pressure control device. The post-processing stage also comprises, prior ^¬ preferably a filter unit and / or a preheating ^¬ unit. After the pressure regulation, the fuel gas is reprocessed (or post-processed), and this one another Purification and heating, wherein in the case of post-processing, the final cleaning in the filter unit is advantageously carried out after preheating. Zusätz ^¬ Lich can binenanlage influenced and the Wobbe index, so the Ver ^¬ ratio between the calorific value and the square root of the rela tive ^¬ density in the pre-heating efficiency of the gas-turbine can be adjusted.

The other advantages mentioned for the pressure control device and its advantageous further developments can be transferred analogously to the gas supply system.

The third object of the invention is inventively achieved by a method for pressure regulation of a gas, in particular a fuel gas of a gas turbine plant, wherein the gas to a pressure reducing unit and / or a switched to this pa ^¬ rallel compressor unit is supplied, wherein the gas in reduced over the Pressure reducing unit ge ^¬ leads, the gas in the compressor operation on the

Compressor system is performed, and wherein during a switching phase between ^¬ switching between reduction and compressor operation, the pressure reduction on the output side of the

Compressor plant separating control valve is actuated. By means of such a process can be ensured that during a switching between the Reduzierbe ^¬ operation and the compressor operation, the predetermined limit values for pressure values and pressure gradient are observed. For this purpose, the control valve is actuated during the switching phase with a corresponding opening or closing law, so that the pressure reducing unit and the compressor system cooperate in a specific and fixed manner in the common collector or are fluidically connected thereto or disconnected from it. The provision of the control valve makes it possible, in particular, to operate the compressor system at a pressure setting value which corresponds to the minimum pressure setting value of the pressure reduction unit, for which purpose the corresponding statements to the pressure control device is referenced.

When the supply of fuel gas in a prescribed gel apparatus Druckre- it flows through a pressure reducing unit and / or by a compressor connected in parallel thereto ^¬ system. Within the pressure reducing unit, the einströ ^¬ Mende fuel gas is redu ^¬ sheet to a preset pressure value. In the case of an undesirable reduction of the system inlet pressure below the specified value, the

Compressor plant started to increase the pressure back to a predetermined pressure setpoint for the compressor system hen ^¬ hen. Accordingly, when the system start-up pressure is increased, the compressor operation switches back to the reduction mode. During a switchover Zvi ^¬ rule the compressor operation and reduced operation impressive ^¬ influence as already described both control systems in an undesirable manner, which can be avoided by using the control valve.

In an advantageous development, the control valve during a switching phase of Reduzierbetrieb on the

Compressor operation is closed and remains during the

Compressor operation closed. Further preferably, the control armature is opened during a switching phase of the compressor operation on the Reduzierbetrieb and remains open during Redu ^¬ ornamental operation. The control valve is preferred currency ^¬ rend actuates the switching phases to maintain a predetermined range of the pressure gradient in the downstream piping system.

As a result of the operation of the control valve during a switching phase, the pressure increase can be omitted by the compressor system. Preferably, the pressure of the compressor is anläge set according to a value which corresponds We ^¬ sentlichen the minimum pressure value of the pressure-reduced in the pressure reducing gas. Conveniently, the gas is treated before entering the pressure ^¬ regulating unit in a treatment stage. Preferably, the conditioning stage includes a filter inlet ^¬ standardized and / or a pre-heating unit.

More preferably, the gas leaving the pressure control device is fed to a post-processing stage. This order ^¬ conveniently summarizes also a filter unit and / or a pre-heating unit. After passing the Nachbereitungs- stage, the gas is then advantageously fed via a feed line ^¬ a gas turbine plant.

In the following, embodiments of the invention are explained in detail. Showing:

1 shows a pressure control device as part of a gas supply system of a gas turbine plant, as well

2 shows a gas supply system with the Druckregelvorrich- device according to FIG. 1

1 shows a pressure control device 1 as part of a gas ^¬ supply system 3 for a gas turbine system 5. The pressure ^¬ regulating device 1 comprises a first control system, namely, a pressure reducing unit 7, and a second control system, namely, a compressor unit 9, which are mutually ge ^¬ connected in parallel ,

In order to set the pressure of the fuel gas, this is supplied to the pressure reduction unit 7 after a corresponding preparation, which will be explained in more detail below with reference to FIG.

The pressure reduction unit 7 comprises two parallel-connected pressure control lines 13, 15, each holding a preferred egg gen-imediumbetätigtes control valve 16, two valves 17 and two safety stop ^¬ handbetägigbare shut-off valves 19 to ^¬. In the present case, the pressure setting value is the first one Pressure control line 13, for example, set to a value of 36 bar and the pressure setting value of the second pressure reducing stage 15 to a value of 35 bar. Accordingly, the first pressure control section 13 operates as a main and the second pressure control section 15 as a reserve controller. In normal operation, the self-medium-actuated control valves 16 of the second control loop 15 will remain closed because of the ^¬ be hired by the first controlled system 13 higher back pressure. The compressor unit 9 comprises a compressor part 20, a self-medium-actuated control valve 16, two Sicherheitsab ^¬ shut-off valves 17 and two motor-operated shut-off valves 21. The compressor unit 9 is set to a pressure setting value, the pressure set value of the second control path 15 of the pressure reduction unit 7, in the present case 35 bar corresponds.

The compressor unit 9 and the pressure reduction unit 7 deliver on the output side into a common collector 22. Via a T branch piece 23, the collector 22 is connected to the gas turbine plant 5.

If the system input pressure falls below a limiting pressure, below which a reduction operation is no longer possible, the compressor system 9 is switched on by opening the motor-operated shut-off valves 21. The pressure reduction unit 7 must be taken out of service. In order to achieve a defined pressure value without pressure surges in this switching phase on the output side, a control valve 24 arranged between the pressure reduction unit 7 and the T branch piece 23 is closed in accordance with a predetermined closing law. During compressor operation, this control valve 24 remains closed.

Conversely, the control valve is in a switching phase from the compressor operation on the Druckreduzierbetrieb opened according to a predetermined law opening 24, while the motorbe ^¬ driven shut-off valves 21 are closed, and remains open during the Druckreduzierbetriebs. In FIG. 2, a gas supply system 3 with the pressure control device 1 according to FIG. 1 is shown. To operate the Gasturbi ^¬ nena position 5, a fuel gas through a supply line configured as a gas supply 31, in this case natural gas, a conditioning stage 33 is fed from a pipeline 29th The treatment stage 33 comprises a filter unit 35 and a preheating unit 37. In the filter unit 35, the natural gas is cleaned and finally preheated in the preheating unit 37 downstream of the filter unit 35.

Subsequently, the natural gas for adjusting the desired pressure via a further supply line 38 of the pressure control device 1 is supplied. Here, as written in detail sawn in FIG 1, the pressure of the natural gas in the pressure reducing unit 7 is reduced and / or compressed in the compressor unit 9 on the ge ^¬ desired pressure.

After passing the pressure control device 1, the natural gas is supplied via a supply line 39 to a post-processing stage 41. In the follow-up stage 41 the natural gas is again preheated in a preheater 43 and then supplied to a ^¬ from closing cleaning a further filter unit 45th Starting from the filter unit 45, the natural gas is then supplied via a feed line 47 of a gas turbine 49 of the gas turbine plant 5 and can be used there to generate elekt ^¬ cal energy.

Claims

claims

1. Pressure control device (1) for a gas supply system (3) of a gas turbine plant (5), comprising a pressure reduction unit (7) for reducing the pressure of an incoming gas, in particular a fuel gas, a pressure reduction unit (7) connected in parallel compressor system (9) for compression of the inflowing gas, as well as on the output side (22) of the pressure reduction unit (7) arranged control valve (24) via which the pressure reduction unit (7) on the output side flow ^¬ technically from the compressor unit (9) is separable.

2. Pressure control device (1) according to claim 1, wherein the pressure reduction unit (7) and the compressor system (9) on the output side via a T-branch piece (23) in a common manifold (22), and wherein the control valve (24) between the pressure reduction unit (7) and the T-branch piece (23) is arranged.

3. Pressure control device (1) according to claim 1 or 2, wherein the pressure setting value in the compressor system (9) substantially ^¬ the pressure set value in the pressure reduction unit (7).

4. Pressure control device (1) according to one of the preceding claims, wherein the pressure reduction unit (7) comprises two parallel-connected pressure control sections (13, 15).

5. Pressure control device (1) according to claim 3, wherein the pressure control sections (13, 15) of the pressure reduction unit (7) are each ^¬ Weil set to different pressure values.

6. Gas supply system (3) for a gas turbine plant (5), comprising a gas supply (31), a fluidically coupled to the gas supply (31) pressure control device (1) according to one of claims 1 to 5, and one with the Druckregelvor- Direction (1) fluidly coupled supply line (47) to the gas turbine plant (5).

7. Gas supply system (3) according to claim 6, wherein in the gas supply (31) a treatment stage (33) and in the to ^¬ guide line (47) to the gas turbine plant (5) a subsequent preparation ^¬ stage (41) is connected.

8. Gas supply system (3) according to claim 7, wherein the processing stage (33) comprises a filter unit (35) and / or a

Preheating unit (37) includes.

9. Gas supply system (3) according to claim 7 or 8, wherein the post-processing stage (41) comprises a filter unit (45) and / or a preheating unit (43).

10. A method for pressure regulation of a gas, in particular a fuel gas of a gas turbine plant (5),

wherein the gas is supplied to a pressure reducing unit (3) and / or to a compressor unit (9) connected in parallel thereto,

wherein the gas is conducted in a reduced operation via the pressure regulating ^¬ duziereinheit (3),

the gas in a compressor operation over the

Compressor system (9) is performed, and

wherein during a separate switchover between Redu ^¬ ornamental plant and a compressor operating the Druckreduzierein ^¬ unit (3) on the output side of the compressor system (9) ^¬ de control valve (24) is actuated.

11. The method according to claim 10,

wherein the control valve (24) is closed during a switching phase of the Reduzierbetrieb to the compressor operation and remains closed during the compressor operation, and / or wherein the control valve (24) is opened during a switching phase of the compressor operation to the Reduzierbetrieb and remains open during the Reduzierbetriebs.

12. The method according to claim 10 or 11, wherein the pressure setting value is set within the compressor system (9) to a value which substantially corresponds to the pressure setting value of in the pressure reduction unit (7) druckredu ^¬ edged gas.

13. The method according to any one of claims 10 to 12, wherein the gas is treated before entering the pressure control device (1) in a treatment stage (33).

14. The method according to any one of claims 10 to 13, wherein the from the pressure control device (1) exiting gas is fed to a post-processing stage (45).

15. The method according to any one of claims 10 to 14, wherein the gas emerging from the post-processing stage (45) via a feed line (47) of a gas turbine plant (5) is supplied.