NL1037295C2 - Process for separating carbon dioxide from incineration gases from a gas turbine and gas turbine unit provided with means for separating carbon dioxide from incineration gases. - Google Patents

Description

Method for separating carbon dioxide from combustion gases from a gas turbine and gas turbine unit provided with means for separating carbon dioxide from combustion gases

The invention relates to a method for separating carbon dioxide from combustion gases from a gas turbine provided with a composite inlet to which air and a combustible gas are supplied and wherein the combustion gases are fed via a membrane unit which is adapted to separate at least carbon dioxide .

Such a method is known from US-A-4,781,907. The known method aims at producing relatively pure nitrogen gas for use in, for example, the chemical industry. The method according to the invention has for its object to remove carbon dioxide from the combustion gases from gas-fired power stations, so that this carbon dioxide does not end up in the atmosphere. The problem with this is that huge volumes of combustion gases are produced, making the membrane unit large and expensive. The method according to the invention obviates this drawback and is characterized in that only a part of the combustion gases is fed to the membrane unit and that a remaining part is fed back to the composite inlet. The result of this is that the volume to be processed by the membrane unit decreases, while the carbon dioxide content of the combustion gases increases, so that the membrane unit can work more efficiently.

A favorable realization of the inventive method is characterized in that 30-50% of the combustion gases is recycled to the composite inlet. As a result, the volume of the membrane unit can be halved by approximately 1037295 2.

A further very favorable realization of the inventive method is characterized in that separated carbon dioxide together with other gases separated by the membrane unit is compressed and fed to a carbon dioxide absorption unit. The absorption unit usually contains a physical or chemical absorption agent for carbon dioxide, such as glycols or MDEA, in which the carbon dioxide dissolves very quickly at an increased partial voltage. Together with the relatively small volume that needs to be processed, this results in a small and inexpensive absorption unit.

A further very favorable realization is characterized in that gases that have not been absorbed by the absorption unit are returned to the composite inlet. These other separated gases, when using a membrane unit according to the prior art, comprise approximately 75% nitrogen and 25% oxygen, so that they benefit combustion in the gas turbine. Moreover, due to their relatively high pressure, they increase the efficiency of the gas turbine.

The invention also relates to a gas turbine unit, comprising a gas turbine provided with a composite inlet via which air and a combustible gas are supplied and an outlet via which combustion gases are discharged, as well as a membrane unit coupled to the outlet, provided with a first an outlet for discharging at least carbon dioxide and a second outlet for discharging at least substantially nitrogen.

According to the invention, the gas turbine is provided with a return line, for returning part of the combustion gases from the outlet to the composite inlet. As a result, the volume to be processed by the membrane unit decreases while the percentage of carbon dioxide increases, so that a smaller membrane unit will suffice. The return line is preferably adapted to return 30-50% of the combustion gases to the composite inlet, which has the result that the volume of the membrane unit can be approximately halved.

A favorable embodiment of the inventive gas turbine unit is characterized in that the gas turbine unit is also provided with a pump unit for maintaining an underpressure at the first outlet. This increases the diffusion rate of carbon dioxide through the membrane unit to the first outlet, whereby the membrane unit can be made relatively small.

A further favorable embodiment is characterized in that the gas turbine unit is also provided with an absorption unit connected to the pump unit, adapted for absorbing carbon dioxide. The absorption unit usually contains a physical or chemical absorption agent for carbon dioxide, such as glycols or MDEA, in which the carbon dioxide dissolves rapidly at an increased partial voltage. The pump unit is preferably adapted to maintain a pressure of 20-50 bar in the absorption unit. This has the result that the carbon dioxide dissolves very quickly, so that the absorption unit can be made relatively small.

A further favorable embodiment is characterized in that the absorption unit is provided with an outlet connected to the composite inlet of the gas turbine. The gas mixture originating from the absorption unit that remains after carbon dioxide has been absorbed consists of approximately 75% nitrogen and 25% oxygen when using a prior art membrane unit, thereby benefiting combustion 4 in the gas turbine. Moreover, due to its relatively high pressure, the gas mixture contributes to the efficiency of the gas turbine, whereby the energy consumption of the pump unit is at least partially compensated.

5

The invention will now be further elucidated with reference to the following figures, wherein:

FIG. 1 schematically represents a possible embodiment of a gas turbine unit provided with a carbon dioxide separator according to the prior art;

FIG. 2 schematically represents a possible embodiment of a gas turbine unit provided with a carbon dioxide separator according to the invention;

FIG. 3 schematically represents a further embodiment of a gas turbine unit provided with a carbon dioxide separator according to the invention.

FIG. 1 schematically shows a possible embodiment of a gas turbine unit provided with a carbon dioxide separator according to the prior art. A gas turbine 1 provided with a compressor part 2 to which air is supplied via an inlet 3, a combustion part 4 to which a combustible gas is supplied via an inlet 5, and a turbine part 6 produces combustion gases which are cooled in a heat exchanger 7 and subsequently to a membrane unit 8 can be supplied in which the combustion gases are split in a manner known per se into mainly nitrogen which is released to the atmosphere via a first outlet 9 and a nitrogen-oxygen-carbon dioxide mixture which via a second outlet 10 is pumped to a absorption unit 12 is fed. Membrane unit 8 comprises, for example, a large number of tubular membranes made from, for example, polyphenylene oxide, provided with pores through which carbon dioxide can diffuse faster than nitrogen. In absorption unit 12, the carbon dioxide is absorbed in a manner known per se in a suitable physical or chemical absorbent such as, for example, MDEA, and the remaining mixture of nitrogen and oxygen is released to the atmosphere via an outlet 13. The carbon dioxide-containing absorbent is fed to a desorption unit 14, where the carbon dioxide is released, for example, by brief heating of the absorbent and / or by lowering the pressure, after which the absorbent is returned to absorption unit 12. The released carbon dioxide is compressed with a pump 15 and discharged via a discharge pipe.

It can be noted from turbine 1 that compressor part 2 is provided with an inlet 3 to which air is supplied under atmospheric pressure and that combustion part 4 is provided with an inlet 5 to which a combustible gas is supplied under a relatively high pressure. It can be noted from pump 11 that it performs two functions. On the one hand, pump 11 creates an underpressure in membrane unit 8, whereby the gas diffusion will proceed faster. On the other hand, pump 11 provides a high pressure in absorption unit 12, as a result of which carbon dioxide will be absorbed very quickly by the absorber.

FIG. 2 schematically shows a possible embodiment of a gas turbine unit provided with a carbon dioxide separator according to the invention. The gas turbine unit actually corresponds to the one shown in FIG. 1, but compressor part 2 is provided with an additional input 16 to which a part of the combustion gases supplied by turbine part 4 and cooled by heat exchanger 7 is supplied. In this way up to about 50% of the combustion gases can be recycled. This has the result that the total volume of 6 combustion gases decreases and that the carbon dioxide content of the combustion gases supplied to membrane unit 8 virtually doubles, so that membrane unit 8 can be made considerably smaller and cheaper compared to the ones shown in FIG. 1 membrane unit shown.

FIG. 3 schematically shows a further embodiment of a gas turbine unit provided with a carbon dioxide separator according to the invention. The gas turbine unit actually corresponds to the one shown in FIG. Gas turbine unit shown in 1, wherein compressor part 2 is provided with an additional input 16 to which a part of the combustion gases supplied by turbine part 4 and cooled by heat exchanger 7 is supplied. In addition, combustion part 4 is provided with an additional input 17 to which the residual mixture of nitrogen and oxygen delivered by absorption unit 12 via outlet 13 is supplied. When a membrane unit and an absorption unit according to the state of the art are used, this gas mixture consists of approximately 75% nitrogen and 25% oxygen and is therefore very suitable for maintaining the combustion in combustion part 4, all the more so because it contains no carbon dioxide. The pressure at which this gas mixture is released is mainly determined by pumps 11 and 25 is approximately 35 bar. This pressure is preferably chosen such that the gas mixture can be supplied directly to combustion part 4, which increases the efficiency of the gas turbine and thereby lowers the costs for removing the carbon dioxide. The energy consumption of pump 15 is also relatively small, because the removed carbon dioxide is offered under high pressure.

1037295

Claims (10)

Method for separating carbon dioxide from combustion gases from a gas turbine provided with a composite inlet to which air and a combustible gas are supplied and wherein the combustion gases are passed through a membrane unit which is adapted to separate at least carbon dioxide, characterized in that only a portion of the combustion gases is fed to the membrane unit and that a remaining portion is returned to the composite inlet. 2. A method according to claim 1, characterized in that 30-50% of the combustion gases is recycled to the compound inlet. 3. A method according to claim 2, characterized in that separated carbon dioxide is compressed together with other gases separated by the membrane unit and sent to a carbon dioxide absorption unit. A method according to claim 3, characterized in that gases that are not absorbed by the absorption unit are recycled to the composite inlet. 25 5. Gas turbine unit, comprising a gas turbine provided with a composite inlet via which air and a combustible gas are supplied and an outlet via which combustion gases are discharged, as well as a membrane unit coupled to the outlet, provided with a first outlet for discharging at least carbon dioxide and a second outlet for discharging at least substantially nitrogen, characterized in that the gas turbine is provided with a return line for returning part of the combustion gases to the composite inlet. 1037295 Gas turbine unit according to claim 5, characterized in that the return line is adapted to return 30-50% of the combustion gases to the composite inlet. 5 7. Gas turbine unit as claimed in claim 5 or 6, characterized in that the gas turbine unit is also provided with a pump unit for maintaining an underpressure at the first outlet. 10 8. Gas turbine unit as claimed in claim 7, characterized in that the gas turbine unit is also provided with an absorption unit connected to the pump unit and adapted to absorb carbon dioxide. 15 Gas turbine unit according to claim 8, characterized in that the pump unit is adapted to maintain a pressure of 20-50 bar in the absorption unit. 10. Gas turbine unit according to claim 8 or 9, characterized in that the absorption unit is provided with an outlet connected to the composite inlet of the gas turbine. 1037295