SE0900237A1 - Procedure for operation of a gas turbine power plant and gas turbine power plant - Google Patents

Description

10 15 20 25 DJ C) of the second group is shown to include a combustion device, which results in an arrangement in which the combustion gases from the combustion device have been given one radial component of movement at the entrance to the housing of the turbine. AND MOST IMPORTANT FEATURES OF THE INVENTION The background technique works well though according to the present invention, a further development is provided. focusing on increased economy, primarily with regard to to the power plant itself and in the alternative in relation to flexibility and simplicity in the arrangement of it the second turbine group.

These objects are addressed in accordance with the present invention. finding.

When the combustion gas stream is produced in a coaxial combustion device and brought axially into the second turbine the group's turbine reduces the complexity of the plant and in in particular the inlet to the second turbine device. That too- also provides the use of an uncomplicated incinerator which gives high performance in terms of temperature distribution and emissions.

Preferably straightforward provides the invention also the freedom to make an incinerator without any particularly tight geometric constraints, which otherwise is the case when incinerators must be designed for to fit traditional gas turbines.

When the gas flow stream from the second turbine device between the second turbine device and the second the compressor device, with substantially lower temperatures than from combustion device output, the conditions become acceptable for uncomplicated long-term operation of the first turbine device ningen. Temperature-influenced problems can thereby be reduced and geometric constraints are avoided. 76006.beWrite; 2010-06-03 10 15 20 25 U) C) Opportunities increase to reach high temperature levels for degree improvement through an even temperature distribution of due to the presence of high amounts of steam in the incinerator and due to the advantageous IR distribution characteristics the creatures of steam. For example, the invention allows freer and more efficient selection of points and areas for steam and / or water tin injection. The combustion is made more harmonious in comparison with the situation in processes in accordance with the background technique.

Geometric solutions can be chosen more freely in terms of design a combustion chamber of the combustion device.

Overall, the method according to the invention is made more economically to operate and components more economical to educate and to entertain.

In previous gas turbine designs, it has been intended that create an incinerator that produces high temperatures tours and efficient temperature distribution inside and in gas starting from the incinerator and to produce flame emissions from the incinerator. This has often resulted in in a very complex combustion device design, mainly due to geometric constraints from the gas turbine structure itself. Especially because of the requirement for a central shaft for the transmission of mechanical work from the turbine to the compressor there is a requirement for the burner placements spaced around the circumference of the turbine inloppet. This has resulted in either annular design design or design with multiple cans. Incinerators gas turbines in accordance with that background technique will thus surround the engine. It has been most disturbing fact that the incinerator and the first steps of the turbine are the components that are most exposed to maintenance due to high temperatures and pressures. These components are due to their complexity expensive to maintain and replace. 76006.beSkriV; 2010-06-03 10 15 20 25 UJ C) It is preferred that process water and / or steam be injected in a gas flow stream whereby necessary compression work can reduced. In particular, water and / or steam are injected into such amounts that at least 60% of the oxygen content of the air in the gas flow stream is consumed by combustion.

When, in accordance with a preferred aspect of this invention, a first gas stream is compressed by a first compressor unit of the second compressor device, then brought to a heat exchanger for cooling said first gas stream and heating of said process water and / or steam and thereafter brought to a second compressor unit of said second compressor device, provides a natural and efficient option to intermediate cooling of the compressor air, supply the possibility of improved flow geometry and printing performance for the second compressor device.

Alternatively, water spray can be injected into the compressor. the flow between the first and second units of the second the compressor device instead of inter-cooling through a heating changer. This can be achieved by, for example, extracting one gas flow to a separate water spray unit and return again.

The invention also relates to a power plant and corresponding features and benefits are obtained in relation to requirements aimed at this.

It is preferred that the combustion device be of coaxial type, is a stand-alone and out-of-engine combustion and / or is a turbine-integrated axial displacement burning device. The second turbine group is separated from the main engine (the first turbine group) and gas are extracted between its turbine and its compressor. It has become practically possible in accordance with the invention to integrate arrangements with other turbine groups in new as well as already operational facilities 76006.beSkriV; 20l0 ~ 06-03 10 15 20 25 U) C) in that the arrangement formed by the second turbine group is easy to install and replace and maintain.

When said second compressor device has a first and a second compressor unit, it is especially preferred that it the turbine of the second turbine group has a first and a second turbine unit, the first compressor unit being rotationally driven of the second turbine unit through a hollow first shaft and the the second compressor unit is rotationally driven by the first unit through a second shaft as this arrangement simple control and allows for easy independent control of respective units. In particular, the first and second the shafts be coaxial with the first hollow shaft partially surrounding the second axis.

Preferably at least a portion of the water content is used. the content of the combustion gases as process feed water and / or process vapor, which allows recovery with certain excess, due to the formation of water during combustion.

Steam is preferably used for cooling the combustion gas stream, and at least a portion of said steam is then introduced into the gas stream, preferably into the combustion chamber. for further use as a working fluid.

As a definition, the gas flow enters the first the compressor unit first and then in the second compressor called. The same applies to a gas turbine that has a first and a second turbine unit, a gas flow entering it first turbine unit first and then in the second turbine the device.

Said second compressor unit may also include additional compressor units in addition to the first and second compressors rressor units.

The invention also relates to a top coil arrangement including a second turbine group. With the term "top coil" refers here to a special compressor-turbine arrangement set up 76006.beWrite; 2010-06-03 10 15 20 25 b) C) to supplement a main turbine group device with reaching more efficient operation.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail guidance of embodiments and with reference to the appended the drawings, in which: Fig. 1 schematically shows a power plant according to the invention in a first embodiment, Fig. 2 schematically shows a power plant according to the invention in a second embodiment, and Fig. 3 schematically shows a power plant according to the finding in a third embodiment Fig. 4 shows a detailed embodiment of a second turbine group with a shaft in an axial section, and Fig. 5 shows a detailed embodiment of a second turbine group with two axles in an axial section.

DESCRIPTION OF EMBODIMENTS In the power plant according to the invention, the other works the gas turbine group in a temperature range where cooling is required and this can preferably be provided using steam. The steam can participate in this process in a very beneficial way method by first cooling the high temperature components before introduced into the incinerator. Hereby this can steam also participate in the expansion process and provide further work. However, some of the steam is used for film cooling of parts where convection cooling does not provide the reversible effect. This film cooling, where the steam acts as a protective layer between the gas stream and the metal, is much efficient when using steam due to the higher heat of the steam capacity compared to air. 76006.beWrite; 2010-06-03 10 15 20 25 bd C) The first gas turbine group will work with the sentences that do not require, or primarily, require only one limited amount of cooling. The spread of cooling air in a corresponding "dry" construction of such a gas turbine group can therefore be drastically reduced and instead allow a larger flow of working fluid in the turbine.

The optimal efficiency for a dry process, ie. for a traditional gas turbine cycle, is achieved at the relatively low pressure conditions of 5 - 40 bar. However, the opti- grinding efficiency at much higher pressure conditions for one steam-injected bicycle. Consequently, it is important to increase the pressure ratio in steam-injected gas turbine cycles for purposes to reach the optimal operating conditions. An appropriate pressure range for the power plant according to the invention is 30 - 300 bar and preferably 50 - 200 bar. Combustion temperature levels are between 1000 - 2200 ° K, preferably 1200 - 2000 ° K.

In some vapor-injected cycle configurations, addition The water content is so large that combustion takes place at such close stoichiometric conditions that are practically possible, ie. 'Almost all the oxygen content in the air is used. This is one of the primary objects in the operation of the invention the power plant.

Combustion at near stoichiometric conditions leads to a efficient, compact and cost-effective power plant. Aquatic networks that have participated in the process are not but can be recovered by combustion gas condensation.

The condensate obtained can be treated continuously and recycled circulated to the power cycle. The process of combustion gas condensation is simplified at near stoichiometric conditions on due to the fact that the dew point is very high under such conditions and the bike can be made water self-sufficient. Condensation ringing water from the combustion gases also helps to remove particles and, to some extent, contaminating 76006.beSkriV; 2010-06-03 10 15 20 25 b) Cl substances from the combustion gases. Thus the least possible is achieved environmental impact. Near stoichiometric combustion also implies that the combustion gas flow to the environment minimized.

Plant operations should be designed so that at least 60%, preferably at least 80% of, preferably at least 90% of the oxygen content of the intake air is consumed. This represents a significant deviation from the existing technology and provides the benefits listed above.

The net result of introducing steam into the traditional the gas turbine process is to increase efficiency and tion of useful work. Well-developed steam-injected gas turbine cycles operated at similar pressures and temperature levels that existing technology usually achieves efficiencies of approximately 50 - 55%. Steam-injected bicycles powered by higher pressure levels receive efficiencies around 55 - 65% and useful work taken will be 2 - 3 times higher than its corresponding conventional gas turbine process.

In order for the bicycle to work efficiently and portable with pressure conditions required to reach 30 - 300 bar, need at least two or for the highest pressure levels, three axes with different rotational speeds are used in the second the compressor device of the second turbine group. High pressure the compressor and the turbine would be driven with the higher rotary tion rate.

Thus, a multi-axis solution would give a conventional one gas turbine device operating with one shaft, a second compressor device and turbine device operating on separate shafts, which rotates at higher speeds, and an incinerator, which operates at higher pressures and temperatures, with close stoichiometric combustion. Steam and / or water can also introduced by injecting high-pressure steam before combustion 76006 .describe; 2010-06-03 10 15 20 25 chamber or by injecting a medium pressure bed and / or water before any of the compressor steps.

During operation at higher pressures, the need to cool the air increases between the compressor units; on the one hand to reduce the temperature level and material requirements in the compressor, and the other side to reduce the amount of compressor work required.

Lowering the temperature of the compressor air can also lead to more favorable conditions for combustion.

The easiest way to reach lower temperatures is to spray water into the compressed air stream. Alternatively can the heat content of the compressed air used to produce steam in a boiler.

Fig. 1 schematically shows a gas turbine power plant according to the invention, which includes a first and a other 20 gas turbine group. The first gas turbine group 10 includes a first turbine device 13, which is rotationally tied over a shaft 11 with a device 15 for taking out such as an electric generator or the like. The the first gas turbine group 10 also includes a first compression device 12, which is mechanically connected to the first the turbine device 13.

The second gas turbine group 20 includes a second turbine device 23. The second gas turbine group 20 also includes a second compressor device 22. The second gas turbine group 20 further includes a device 25 for taking out useful work, which is an electric generator or the like.

Furthermore, it is positioned between the first and second the compressor devices an air cooler 74 in the form of a heating exchanger, which is used to produce steam for injection to the process. After the output of the second compressor device 22 the air is led over a line 43 to the inlet of a combustion device 35, which is arranged axially 76006 .beskriiu 2010-06-03 10 l5 20 25 U) C) 10 current of the second turbine device 23, opposite to the pressorn 22.

The combustion device 35 is coaxial and feeds combustion gases to an axial inlet to the second turbine bee device 23. Furthermore, there are inlets for combustion devices. hot water 61 'and / or steam 61 for the purpose of provide a combustion process in which at least 60% of the oxygen content of the air in the flow stream is consumed by combustion in the incinerator 35. Fuel supplied is held to the combustion device 35 over the line 51.

The gases from the outlet of the other turbine group turbine device 23 flows through line 48 to the first turbine group turbine device 13.

The gases then exit the first turbine 13 and flows through line 49 to an additional heat exchanger 73, which contributes to the heating of steam for injection in the process through management 61.

After the heat exchanger 73, the combustion gases are passed through a heat exchanger 70, which contributes to the heating of water for injection into the process through line 61 'and wherein the condensate sat from a combustion gas condenser 71 are heated before led to a vent 72 over line 83.

Water is supplied to the heating circuit inclusive the heat exchangers 73 and 74 over the deaerator 72, which has the goal of ensuring that the water in the circuit is free from oxygen.

A certain amount of steam is led in a flow 63 through a line and is injected into the second turbine device 23 for film cooling. Additional steam used for additional convention cooling inside The lurbine leaves are then extracted in a stream 68 through a line and fed into the incinerator for to participate in the expansion process. 76006.beSkriV; 2010-06 ~ 03 10 15 20 25 U.) C) ll Fig. 2 schematically shows a gas turbine power plant according to the invention, which differs from that in Fig. 1 in that the second gas turbine group 20 includes a second turbine device 23, which is constituted by a first turbine unit 23 ' and a second turbine unit 23 ”. The second gas turbine group 20 also includes a second compressor device 22, which in its turn consists of a first compressor unit 22 'and a second compressor unit 22 ”.

The first compressor unit 22 'is rotationally connected with the second turbine unit 23 ”over a first, hollow, shaft 2l ', which partially surrounds a second shaft 21, which in turn rotationally connects the second compressor unit 22 'to the first turbine unit 23 '. An air flow to run into the first compressor unit is indicated by 42 and after exit from the first compressor unit, the compressor air through one line 42 'to the inlet of the other the compressor unit 22 ”. Furthermore, is positioned between the first and the second compressor units an air cooler 74 in the form of a heat exchanger, which is used to produce steam for injection ~ tering into the process. As an alternative, the second gas the turbine assembly includes three turbine units, each of which are rotationally connected to each of the three compressor included in the compressor device. Three connections axes for the three respective steps are in that case coaxial corresponding to the two axis alternative mentioned above.

After exiting the second compressor unit 22 ”is led the air over a line 43 to the inlet of a combustion device 35, which is arranged axially upstream of it first turbine opposite the compressor unit 22 ”.

The combustion device 35 is coaxial and feeds combustion gases to an axial inlet to the first turbine the bee assembly 23 'of the second turbine assembly 23 and thereafter 76006 .describe 2010-06-03 10 15 20 25 bd C) 12 to the inlet of the second turbine unit 23 "of the other the turbine device 23.

The first gas turbine group 10 in Fig. 2 includes one first turbine device 13, which is rotationally connected across a shaft 11 with a device 15 for taking out useful work such as an electric generator or the like. The second gas however, the turbine assembly 20 does not include a device for removal of useful work, the other compressor and tur- the bee devices are balanced to each other. Compressor- the device 12 of the first turbine group is relatively low energy consuming and at least essentially all useful work produced by the plant is taken from the first bingruppen. Thus, only the first turbine group needs be connected to an electric generator or similar.

In this embodiment, steam is passed through line 63 and injected into the second turbine device 23 for film cooling purpose not subsequently taken to be forwarded into the incinerator.

Fig. 3 shows an embodiment which differs from it shown in Fig. 2 essentially by all compressor work is produced in the second group, which provides more opportunity to improved flow geometry with respect to the second turbine the group. Another difference is that the meadow generator 74 in the embodiment the ring mold of Fig. 2 has been replaced by a spray intercooler 91.

Fig. 4 shows in more detail the second turbine group 20 in one axial cross section with a combustion device in the form of a axially aligned burner 35 connected to a turbine device 23.

The burner is fed with a mixture of fuel and air and also by steam and / or water for further control of burner temperature.

The temperature of the combustion device 35 is intended to be about 1400 ° C, while the temperature downstream of it 76006.describe; 2010-06-03 10 15 20 25 UJ C) 13 the second turbine device 23 is about 1000 ° C, which is one level that is completely manageable for the transfer to and operation of the first turbine device 13 without any cooling requirements.

The second turbine device 23 is shown here to be cooled a steam flow 63, which enters through a steam flow inlet 65, said steam stream 63 being initially injected into stationary parts and further transferred into rotating parts of the other the turbine device 23. The steam flow 61 (see also Figures 1 - 3) enters through one or both of the inlets 64 and 64 '. A water flow 61 ' occurs by injection through an inlet 64 "at a fuel injection end of a combustion chamber 66 directly into the combustion chamber. the combustion chamber 66 of the combustion device 35. A steam flow preferably cools the combustion chamber walls. This is the case, in this embodiment, for inlet 64 ', which leads to clothing cooling means. Reference 51 indicates fuel supply lines.

The second turbine group is of the one-shaft type and has an axial type turbine included in the second turbine assembly 23 and a radial type compressor included in the second compressor. the presser device 22, which are mechanically coupled to each other. A shaft 21 includes means 24 for the connection to a power take-off device.

The flow line 48 'transmits the gas flow 48 from it the second turbine device 23 to the first turbine device 13 is separated by compressed air flow 42 from the first compressor. the presser 12, inside a line 48 ”in the arrangement shown in fig. 4 before leaving the second turbine group 20. Reference 43 indicates a line for air flowing from the other the compressor device 22 to the second turbine device 23 (see above).

A vapor stream 63 injected through an inlet 65 into it the second turbine device 23 is used for both film cooling and 76006.beskriV; 2010-06-03 10 15 20 25 U! C) 14 convention cooling. The corresponding used meadow flow 68 is taken through an outlet 65 '. It can then be fed into the incinerator. through inlet 64 and / or 64 'to participate in the expansion sion process.

The embodiment in Fig. 5 differs from that in Fig. 4 in mainly by presenting here, in more detail, a biaxial axis turbine group, from the plant as can be seen in Fig. 2 or 3.

The turbine-to-compressor coupling can be designed to be operated at higher pressure conditions and enable the whole group to operated without any power take-off.

The second turbine device 23 has two single stages high pressure turbines. The second turbine device 23 consists of one first turbine unit 23 ', which is a single stage high pressure turbine and a second turbine unit 23 ", which is a single stage low pressure turbine. The second gas turbine group 20 includes also a second compressor device 22, which in turn is constituted of a first compressor unit 22 'and a second compressor unit 22 ”. The first turbine unit 23 'is supported by a bearing position. tioned in a central position by a joint wall of it second turbine device and is driven by the shaft 21 (see also Fig. 2). The second turbine unit 23 ”is supported by a bearing positioned in the center of the guide rail of the second turbine stage and driven by the shaft 21 '(see also Fig. 2).

Reference is made to the above with respect to the remainder reference numerals in Fig. 5. Steam flows 63 injected only for film cooling, after use, is not subsequently removed for feeding to the combustion chamber. See Fig. 2.

The positioning of the burner coaxially to an adjacent turbine facilitates isolation of the burner from the main engine as well as from essential components of the second turbine the group.

The temperature from the burner is intended to be around 1500 ° C, while the temperature downstream of the second 76006.beWrite; 2010-06-03 lO 15 the bee device is about 100 ° C, which is a level that is completely manageable for the transfer to and operation of the first the turbine device.

The invention can be modified within the scope of the claims.

For example, it is possible in some applications to include another low power consumer such as an auxiliary device, the first or the other turbine group. Also the embodiments in fig. 2 and 3 can be supplemented in this way. A device for sockets of small amounts of useful work or the like can also in some applications are also connected to the other turbine group also in the embodiments of Figs. 2 and 3.

It is also possible within the scope of the requirements to add overheating in addition to hot water and steam for combustion the gases and intermediate compressor flow path. 76006 .describe; 2010-06-03

Claims (29)

A method of operating a gas turbine power plant having a first gas turbine assembly (10) including a first turbine assembly (13) and a second gas turbine assembly (20) including a second compressor assembly (22) and a gas turbine assembly. second turbine device (23), which are mechanically connected to each other, and useful work is carried out by at least one device (15,25) included in a plant, a combustion gas stream being produced by a combustion device (35), which is located in a gas flow stream (42,48) upstream of the second turbine device (23) and wherein process water and / or steam is heated by a process gas stream and the produced water and / or steam is injected into a gas flow stream (42,4B) upstream of and / or in the combustion device (35). ) in such quantities that at least 60% of the oxygen content of the air in the gas flow stream (42,48) is consumed by combustion and that the combustion gas fed to the second turbine device (23) h is a pressure of about 50 - 300 bar, characterized in that the combustion gas stream is generated in a coaxial combustion device (35) and is led axially into a side of the second turbine device (23) opposite to a side thereof which is closest to the second compressor device (22), that the gas flow stream (48) from the second turbine device (23) exits between the second turbine device (23) and the second compressor device (22). The method according to claim 1, characterized in that the pressure in the outlet of the second turbine device (23) is about 5 - 50 bar and most preferably between 10 - 30 bar. The method of claim 1 or 2, characterized in that the first gas turbine group (10) includes a first 76006. Compressor device (12), which is mechanically connected to the first turbine device (13). The method according to any one of claims 1 to 3, characterized in that a first gas stream is compressed by a first compressor unit of said second compressor device (22), then brought to at least a second compressor unit of said second compressor device (22) . The method according to claim 4, characterized in that the first gas stream after the first compressor unit and before the second compressor unit is brought to a heat exchanger (74) for cooling said first gas stream and heating said process water and / or steam. The method according to claim 4, characterized in that the first gas stream after the first compressor unit and before the second compressor unit is brought to a spray unit for exposing the gas stream to a water and / or steam spray. The method according to any one of the preceding claims, wherein said second compressor device (22) has a first and a second compressor unit, characterized in that the first turbine device has a first and a second turbine unit, the first compressor unit being rotationally driven of the second turbine unit over a first hollow shaft and the second compressor unit is rotationally driven by the first turbine unit over the second shaft. The method according to any one of the preceding claims according to claim 4, wherein said second compressor device has a first and a second compressor unit, characterized by 76006. 2010-06-03 10 15 20 25 br) C) 10 that the first gas flow after the second compressor unit of said second compressor device (22) is brought to at least one further compressor unit of said second compressor device (22). The method according to claim 8, characterized in that each of said at least one further compressor unit (s) is driven by a corresponding turbine unit over a further shaft. The method according to claim 7 or 9, characterized in that the compressor units are driven by coaxial shafts, at least partially surrounding each other. ll. The method according to any one of the preceding claims, characterized in that at least a part of the water content in combustion gases is used as process feed water and / or process steam. The method according to any one of the preceding claims, characterized in that steam is used for cooling combustion gases and that at least a part of said steam is subsequently introduced into the gas stream (42,48), preferably in the combustion device, for further use as a working fluid. Method according to one of the preceding claims, characterized in that a flow line (48 ') transmitting a gas flow (48) from the second turbine device (23) to the first turbine device (13) is cooled by a compressed air stream ( 42), from the first compressor (12) inside a line (48 ”) before leaving the second turbine group (20). 76006 .describe; 2010-06-03 10 15 20 25 U) C) 19 A gas turbine power plant having a first gas turbine assembly (10) including a first turbine assembly (13) and a second gas turbine assembly (20) including a second compressor assembly (22) and a second turbine assembly (23), which are mechanically coupled to each other, and at least one of the first and second turbine groups (10,20) have a device (15,25) for taking out work, a combustion device (35) for generating a combustion gas stream being placed in a gas flow stream (42,48) upstream of the second turbine device (23) and wherein heating means are arranged to heat process water and / or steam from a process gas stream and injection means are arranged to inject the generated water and / or steam into a gas flow stream (42, 48) upstream of and / or in the combustion device, characterized in that a coaxial combustion device (35) for generating the combustion gas stream is positioned axially to the second turbine device (23) on a side thereof opposite to a side closest to the second compressor device (22), and - that the outlet of the gas flow stream (48) from the second turbine device (23) is positioned between the second turbine device ( 23) and the second compressor device (22). The plant according to claim 14, characterized in that the coaxial combustion device (35) is one or more from the group: thin-type burners, a stand-alone burner set up outside the engine, a turbine-integrated axial burner. k ä n n e t e c k - | ..- \ The plant according to claim 14 or 15, wherein the second compressor device (22) includes a first and a second compressor unit (22 ', 22 "). 76006 describe; 2010 ~ O6-03 10 15 20 25 (JJ C »20 The plant according to claim 16, characterized in that a heat exchanger (74) for cooling said first gas stream and heating said process water and / or steam is located after the first compressor unit (22 ') and before the second compressor unit (22 ”). The plant according to claim 16, characterized in that a spray unit for exposing the gas stream to a water and / or steam spray is located after the first compressor unit (22 ') and before the second compressor unit (22 "). The plant according to any one of claims 14 - 18, characterized in that the glass flow current outlet from the second turbine device (23) is between the second turbine device (23) and the second compressor device (22). The plant according to any one of claims 14 - 19, wherein said second compressor device (22) has a first and a second compressor unit (22 ', 22 "), characterized in that the second turbine device (23) has a first ( 23 ') and a second (23 ") turbine unit, the first compressor unit (22') being rotationally coupled to the second turbine unit (23") over a first, hollow shaft (21 ') and the second compressor unit (22 ") being rotationally coupled to the first turbine unit (23 ') over a second shaft (21). The plant according to claim 20, characterized in that the second turbine device (23) has more than two turbine units and that the second compressor unit has more than two compressor units. The plant according to claim 19 or 20, characterized in that the first and further shafts are coaxial and that the further shaft is at least partially surrounded. of the first shaft. The plant according to any one of claims 14 to 22, characterized in that the first turbine group includes a first compressor device. A top coil arrangement for a gas turbine power plant having a first gas turbine group (10) including a first turbine device (13), said top coil arrangement including a second gas turbine group (20), in turn including a second compressor device (22) and a second turbine device (23), which are mechanically coupled to each other, wherein a combustion device (35) for generating a combustion gas stream is located in a gas flow stream (42, 48) upstream of the second turbine device (23), said plant including heating means are arranged to heat process water and / or steam from a process gas stream and injection means are arranged to inject the generated water and / or steam into a gas flow stream (42,48) upstream of and / or in the combustion device, and at least one of the first and second turbine groups (10, 20) have a device (l5,25) for taking out work, characterized by - a coaxial combustion device ng (35) for generating the combustion gas stream is positioned axially to the second turbine device (23) on a side thereof opposite to a side closest to the second compressor device (22), and - the outlet of the gas flow stream (48) from the second the turbine device (23) is positioned between the second turbine device (23) and the second compressor device (22). 76006.describe; 2010-06-03 10 15 20 25 22 The arrangement according to claim 24, characterized in that the coaxial combustion device (35) is one or more from the group: thin-type burners, a stand-alone burner arranged outside the engine, a turbine-integrated axial burner. The arrangement according to claim 24 or 25, characterized in that the second compressor device (22) includes a first and a second compressor unit (22 ', 22 "). The arrangement according to claim 26, characterized in that a heat exchanger (74) for cooling said first gas stream and heating said process water and / or steam is located after the first compressor unit (22 ') and before the second compressor unit (22 ”). The arrangement according to claim 26, characterized in that a spray unit for exposing the gas stream to a water and / or steam spray is located after the first compressor unit (22 ') and before the second compressor unit (22 "). . The arrangement according to any one of claims 24 - 28, characterized in that the glass flow current outlet from the second turbine device (23) is between the second turbine device (23) and the second compressor device (22). 76006.beskriV; 2010-06-03