EP2122179A1 - Method for operating a compressor arrangement, and a compressor arrangement - Google Patents

Abstract

The invention relates to a method for operating a compressor arrangement (COAN), particularly a pipeline compressor station (PCO), which compressor arrangement has a turbine (gas turbine GT) and a compressor (Co) in a torque-transferring connection. Previous systems work over long periods with poor efficiency when the turbine (gas turbine GT) is working under a partial load. The invention provides a remedy for this in that an electrodynamic machine (GeMo) is in a torque-transferring connection to the compressor (Co), wherein the turbine (gas turbine GT) has a maximum efficiency (H1) at a particular, first turbine output (P1), wherein the electrodynamic machine (GeMo)is operated as a generator at a compressor output below the first turbine output (P1),and as an engine at a compressor output above the first turbine output (P1).

Description

description

Method for operating a compressor assembly and compressor assembly

The invention relates to a method for operating a compressor arrangement, in particular a pipeline compressor station, which compressor arrangement has at least one turbine and at least one compressor. In addition, the invention relates to a compressor arrangement for operation by the method according to the invention.

In the course of increasing scarcity of raw materials and in the shadow of threatening climate change, the most urgent task of energy-converting machines is to conserve scarce resources and to limit emissions, in particular the emission of climate-changing gases. In order to make it more than just moral appeals, so-called carbon credits have been introduced in Europe in response to decisions taken in the Kyoto Protocol, which increase the economic interest in reducing the emission of so-called greenhouse gas emissions. This motivation increasingly encompasses smaller and more specialized units.

A problem related to the problem described above is the distribution of natural gas by means of a network of pipelines that in its meshed

Nature is difficult to operate with simultaneous irregular distribution of consumers. At various points in the mesh network, contracts determine the pressure range in which the amount of gas in standard cubic meters must be made available over a certain period of time. However, the demand for gas here at the customer stations is so fluctuating that the promotion often reaches the technical limits and all capacities have to be prevented under all circumstances, that pressures fall below contracted limits. Despite the valiant use of so-called pipeline compressor stations and complex experiments, this sometimes happens to allow the gas network to "breathe" optimally at the right moment, whereby the pipeline compressor stations over a certain period of time produce a pressure difference while conveying the gas in one direction Within the limits of what is technically feasible, a pipeline compressor station will provide flow in both directions of 0 - 1,000,000 standard cubic meters / hour in both directions, with the drive of the compressor arrangement providing a drive power variation of at least 65%. The compres- sors of the compressor arrangements are regularly driven by gas turbines, which achieve their optimum efficiency under full load - ie at 100% nominal power - and in the partial load range or at over- load regularly have dramatic efficiency losses. In addition, the

Part load range also accompanied by additional undesirable emissions and a disproportionate reduction in the service life.

The invention has been made on the basis of the difficulties described above to the object, method for operating compressor stations and a

To provide compressor station, which has both a good efficiency and good emissions in all load ranges even with fluctuating load.

To solve the problem, an initially mentioned method is proposed according to the invention, in which an electrodynamic machine is in torque-transmitting connection with the compressor, wherein the turbine has a maximum efficiency at a certain first turbine power, wherein at a

Compressor capacity below the first turbine power the electrodynamic machine is operated as a generator and at a compressor power above the first turbine power, the electrodynamic machine is operated as a motor. In addition, a compressor system is proposed with a turbine and a compressor, which are in torque-transmitting connection with each other, wherein an electrodynamic machine with the compressor in torque-transmitting connection, wherein the turbine is designed such that they at a certain first power a Maximum efficiency reached, with a

Regulation provided and is designed such that it controls the power consumption and delivery of electrodynamic machine such that at a compressor power below the first power, the electrodynamic machine is operated as a generator and at a compressor power above the first power, the electrodynamic machine is operated as a motor.

Due to the variable use of the electrodynamic machine according to the invention, it is possible, the turbine, which is preferably designed as a gas turbine, in the partial load range or in the region of an overload always closer to

Efficiency to operate maximum, as is the case with conventional systems. Preferably, the entire system is always operated in close proximity to the maximum efficiency of the turbine or gas turbine, so that both the fuel consumption and the pollutant emission are minimal.

If the maximum of the thermal efficiency and the minimum of the emission are not in the same operating point of the turbine or gas turbine, in this case, for example, an economically oriented compromise can determine the preferred operating point.

The electrodynamic machine is fed during operation as a motor from an electrical power grid, in which this preferred during operation as a generator, the energy generated with the interposition of a

Inverter again fed. This way saves the operator on the one hand fuel for the operation and on the other hand emissions for emission rights. In addition, where appropriate, using the non-optimal operating ranges of the turbine, this arrangement can handle higher peak loads due to the possibility to connect the electrodynamic machine as a motor. A gas turbine, which can be used for example between 4 and 8 MW, in combination with an electrodynamic machine according to the invention, which has 4 MW power, a compressor with a power between 0 and 12 MW

Drive power operate. If the turbine is only operated at an optimum efficiency of, for example, 7 MW, the margin is still between 3 MW and 11 MW drive power.

In a reversible conveying direction of the compressor system great efficiencies are achieved even with high fluctuations in the delivery pressure and the flow rate with the inventive system.

The inventive concept is suitable both for compressor systems which are operated at a constant speed and, for example, with a Eintrittsleitapparat the compressor as well as for compressor systems with variable speed, with a frequency converter is regularly provided at the connection of the electrodynamic machine to the electrical power grid.

Advantageously, the turbine, in particular in the case of a gas turbine by means of the electrodynamic machine for starting can also be brought to a corresponding speed, which makes a separate starter motor for the turbine unnecessary.

To avoid unwanted delays during maintenance work on the compressor, this is preferably designed in a pot construction and provided with non-continuous shaft, so that the electrodynamic machine are mounted only on one side of the compressor can. The electrodynamic machine here is preferably equipped with a continuous shaft, so that either the turbine is directly connected to the free end or preferably a torque-transmitting operational arrangement is coupled to a free end of the independent turbine shaft. This second shaft arrangement has particular advantages with regard to the use of standard modules and brings with it a suitable shaft dynamics.

In connection with the electrodynamic machine according to the invention, the rotor dynamics is of particular importance, because a unified shaft train of turbine, electrodynamic machine and compressor due to the length of the arrangement would have a particularly complex rotor dynamics, in particular with respect to the bending vibrations.

Hereinafter, a specific embodiment will be described with reference to drawings for clarity. This description has only exemplary character, because in the spirit of the invention, other possible embodiments in addition to the detailliert here described for the skilled person. Show it:

Figure 1 is a schematic representation of a

Gas distribution network,

Figure 2 is a schematic representation of a compressor system according to the invention, which is operated by the method according to the invention.

FIG. 1 shows a gas distribution network 1 which extends over a specific territory 2 and has various interfaces 3 to neighboring areas. At the interfaces, standard volume flows U, V, W, X, Y, Z flow into the gas distribution network 1 of the territory 2 or out at respectively determined pressure levels. The pressure level can for example be between 50 and 100 bar. The gas distribution network 1 is a meshed network with several nodes 4. At various locations there are supplier withdrawals 5, at which gas of a certain individual pressure pl - plO is taken from the gas distribution network 1. At the same time it is possible that storage feeds into the grid take place. The pressure pl - plO can fluctuate within contractually defined limits, which are usually set between 50 and 100 bar. In each case a pipeline compressor station PCO or compressor arrangement COAN is arranged at different points in the gas distribution network 1, wherein only a single one is shown by way of example in FIG. The task of the pipeline compressor station PCO, which corresponds to the compressor installation COAN according to the invention, is to ensure the various standard volume flows and pressures at the supplier withdrawals 5. In this case, the withdrawals may fluctuate greatly, in particular as a function of the season, as well as the standard volume flows U, V, W, X, Y, Z at the interfaces 3 of the gas distribution network 1, so that operational situations which are difficult to predict for the pipeline compressor station PCO arise. Accordingly, both the pressures pl - plO and the standard volume flows U, V, W, X, Y, Z are subject to great fluctuations, for example fluctuations between 0 and 1,000,000 cubic meters / hour even when the conveying direction is reversed.

Figure 2 shows a schematic representation of

Pipeline compressor station PCO or a compressor assembly according to the invention COAN of Figure 1 in detail, which is operated by the method according to the invention. The compressor assembly COAN of the embodiment consists essentially of a

Gas turbine GT with a compressor COGT and a turbine GTGT, an electrodynamic machine according to the invention GeMo and a compressor Co. The compressor Co is located with the electrodynamic machine GeMo on a first shaft train SHl. The turbine compressor COGT together with the gas turbine turbine GTGT on a second shaft train SH2, with the first shaft strand SHl in a torque-transmitting connection in the form of a transmission TRI is. The compressor Co is designed in a pot construction, so that no continuous shaft is provided as part of the first shaft strand SHl of the compressor Co. The side of the compressor housing CoCs, from which no end of the shaft strand SHl emerges, can be opened for maintenance, so that, for example, a not shown in detail impeller red can be changed with little time.

The electro-dynamic machine GeMo is equipped with a through

Housing continuous wave SHGeMo formed as part of the first wave train SHl, so that at a first end of the shaft Sl of the electrodynamic machine GeMo the compressor Co is disposed and at a second end of the transmission TRI. The electro-dynamic machine GeMo is electrically connected to a frequency converter CONV, so that electrical energy generated by the electro-dynamic machine GeMo at different rotational frequencies can be fed into a connected electric power network ELN at the mains frequency of 50 Hz. In addition, the frequency converter CONV is used to control the speed of the compressor drive by means of the electro-dynamic machine GeMo.

The compressor Co is connected to the gas distribution network 1 and allows the promotion of

Volume flows (standard volume flows U, V, W, X, Y, Z) as needed in one direction or in the opposite direction of a pipeline PL of the gas distribution network 1. This possibility is opened by an arrangement CIR gas lines PEP and valves VAV. Depending on the opening of certain valves VAV, this arrangement CONV, which also includes a conduit arrangement generally referred to as a "brace" circuit, allows the gas to be conveyed by means of the unmodified compressor Co in one or the opposite other direction of the pipeline PL two different possibilities are shown in phantom in FIG. 2 or dashed.

The inventive method for operating the pipeline compressor station PCO or the compressor assembly COAN provides that the gas turbine GT at a certain power P has a maximum efficiency η, as indicated by the sketch-like diagram in Figure 2. The fluctuating load requirements on the compressor Co, as indicated by the diagram representing the volume flow V over the time T in Figure 2, mean in conventional systems that the gas turbine GT is to be operated for long periods in areas only moderate efficiency η. According to the method according to the invention for operating the compressor arrangement COAN The electrodynamic machine compensates the load peaks and valleys of the compressor Co, so that the gas turbine is always operated closer to the optimum efficiency GT closer to the maximum efficiency GT. Here, it is provided that the electrodynamic machine GeMo is operated at a load request from the compressor Co lower than a first power Pl at which the gas turbine has the efficiency maximum ηl as a generator and when the compressor Co has a power demand which is higher as the first power Pl, the electrodynamic machine is operated as a motor. For this purpose, a control CR is provided, which controls the electrodynamic machine according to the operating situation. The electrical power generated during the generator operation of the electrodynamic machine GeMo is brought by means of the frequency converter CONV mains frequency and fed to the electric power network ELN.

Claims

claims

1. A method for operating a compressor assembly (COAN), in particular a pipeline compressor station (PCO), which compressor assembly comprises a turbine (gas turbine GT) and a compressor (Co) in torque-transmitting connection, characterized in that an electrodynamic machine (GeMo) in Torque-transmitting connection with the compressor (Co) is, wherein the turbine (gas turbine GT) at a certain first turbine power (Pl) has an efficiency maximum (Hl), wherein at a compressor power below the first turbine power (Pl) the electrodynamic

Engine (GeMo) is operated as a generator and at a compressor power above the first turbine power (Pl), the electrodynamic machine (GeMo) is operated as a motor.

2. The method according to claim 1, characterized in that the conveying direction of the compressor assembly (COAN) is reversible.

3. The method according to claim 1, characterized in that the compressor (Co) is operated substantially at a constant speed (n).

4. The method according to claim 1, characterized in that the compressor (Co) is operated at variable speed (s).

5. compressor system (COAN) with a turbine (gas turbine GT) and a compressor (Co), which together in Torque-transmitting compound, characterized in that an electrodynamic machine (GeMo) with the compressor (Co) is in torque-transmitting connection, wherein the turbine (gas turbine GT) is designed such that they at a certain first power (Pl) reaches an efficiency maximum (Hl), wherein a control (Cr) is provided and is designed such that it controls the power consumption and delivery of the electrodynamic machine (GeMo) such that at a compressor power below the first power (Pl) the electrodynamic machine (GeMo ) is operated as a generator and at a compressor power above the first power (Pl), the electrodynamic machine (GeMo) is operated as a motor.

6. compressor unit (COAN) according to claim 5, characterized in that the turbine (gas turbine GT) and the compressor each have their own separate

Shaft (wave strand SHl, SH2) have.

7. compressor system (COAN) according to claim 5, characterized in that the compressor (Co) is designed in pot construction, so that no continuous wave (SHl) is provided.