Combustion engine, in particular a stationary gas engine, comprising a combustion chamber

专利摘要:
Internal combustion engine (1), in particular a stationary gas engine, comprising a combustion chamber (3) via which a fuel (Bi) can be supplied from a first fuel source (4), an antechamber (5) which is connected via a purge gas line (6 ) a purge gas (S) can be supplied, wherein a purge gas mixer (7) is provided, in which via a fuel line (8) feedable fuel (B2) from the first fuel source (4) or from a second fuel source (4 ') and a Synthesis gas (R) which can be supplied via a synthesis gas line (9) can be mixed and a mixer outlet (10) opens into the purge gas line (6), the synthesis gas (R) being able to be produced by a reformer (11) via a reformer feed line (12). a fuel (B3) from a fuel source (4, 4 ') can be supplied and its reformer outlet (14) opens into the synthesis gas line (9), wherein a cooling device (13, 15) for cooling the synthesis gas (R) is provided.
公开号:AT511338A4
申请号:T1529/2011
申请日:2011-10-19
公开日:2012-11-15
发明作者:Friedrich Gruber；Guenther Wall
申请人:Ge Jenbacher Gmbh & Co Ohg；
IPC主号:

专利说明:

70814 30 / cr 1
The present invention relates to an internal combustion engine, in particular a stationary gas engine, comprising a combustion chamber, via which a fuel from a first fuel source can be supplied via a combustion chamber conduit, a prechamber, which can be supplied with a purge gas via a purge gas conduit, wherein a purge gas mixer is provided in which Fuel which can be supplied via a fuel line from the first fuel source or from a second fuel source and a synthesis gas which can be supplied via a synthesis gas line are miscible and wherein a mixer outlet opens into the purge gas line, wherein the synthesis gas can be generated by a reformer which can be supplied with fuel from a fuel source via a reformer feed line is and whose reformer output opens into the synthesis gas line.
In Otto engine operated internal combustion engines, the ignition of a fuel-air mixture takes place in the combustion chamber by ignition devices, the mixture ignition is usually initiated by a sparkover at the electrodes of a spark plug. Alternatively, it is also known to use a laser spark plug as the ignition device, in which the required ignition energy is introduced in the form of laser light into the combustion chamber. In particular, in gas engines, in which a propellant gas-air mixture is ignited, one uses the lean concept for larger combustion chamber volumes. This means that a relatively large excess of air is present, whereby at maximum power density and high efficiency of the engine, the emission of pollutants and the thermal load on the components is minimized. The ignition and combustion of very lean fuel-air mixtures represents a significant challenge for the development and operation of modern high-performance gas engines.
From a certain size of the gas engines (usually about six liters displacement), it is necessary to use ZündVerstärker to go through the correspondingly large flame paths in the combustion chambers of the cylinder in the shortest possible time. As such booster usually serve prechambers, wherein the highly compressed at the end of the compression stroke fuel-air mixture in * «» · · «·« 4 · · · «« «* '1 ....... * ... .. ignited a separated from the main combustion chamber of the cylinder relatively small side room. In this case, a main combustion chamber of the working piston, the cylinder liner and the cylinder head bottom is limited, wherein the secondary chamber (the prechamber) is connected by one or more overflow holes with the main combustion chamber Frequently such prechambers are purged or filled with propellant during the charge cycle phase to the fuel-air Greasy mixture and thus improve the flame and combustion properties. For this purpose, a small amount of propellant gas is diverted from the propellant gas supply to the main combustion chamber and introduced via a suitable, provided with a check valve supply device in the antechamber. This amount of propellant flushes during the charge cycle the antechamber and is therefore often referred to as purge gas. During the compression phase, the very lean fuel-air mixture of the main combustion chamber flows through the overflow holes in the antechamber and mixes there with the purge gas. The ratio of fuel to air in the mixture is given in the form of the excess air coefficient λ. An excess air ratio of λ = 1 means that the amount of air present in the mixture exactly corresponds to the amount required to allow complete combustion of the fuel. The combustion takes place stoichiometrically in such a case. Large gas engines are usually operated lean at full load at an A of about 1.9 to 2.0, that is, the amount of air in the mixture corresponds to about twice the stoichiometric amount of air. By flushing the prechamber with propellant gas results after mixing with the propellant gas-air mixture from the main combustion chamber, a mean λ in the antechamber of about 0.8 to 0.9. This results in optimal conditions of ignition and, due to the energy density, intensive ignition torches emerging into the main combustion chamber, which lead to a rapid burning through of the fuel-air mixture in the main combustion chamber. At such λ values, however, the combustion takes place at the maximum temperature level, so that the wall temperatures in the prechamber region are correspondingly high. On the one hand, this results in a correspondingly high thermal load on the pre-chamber and components arranged therein (for example spark plug, valves) and, on the other hand, undesirably high nitrogen oxide emissions.
With increasing engine power and measures to increase the efficiency, it also causes more soot formation in the prechamber. The resulting soot content in the engine exhaust gas adversely affects the heat transfer in the waste heat boiler as well as problems in certain applications of gas engines, for example for CC > 2 fertilization of greenhouses.
One way to avoid soot formation is to deposit the fuel-air mixture in the antechamber and oxidize the free carbon by a slight excess of oxygen. However, there are other problems associated with the fact that excess oxygen at very high combustion temperatures just above λ = 1 for hot corrosion at critical points in the pre-chamber, especially at the overflow holes and the spark plug electrodes, can result.
From the prior art it is also known to enrich the pre-chamber to be supplied purge gas with appropriate gases in order to increase the ignitability of the purge gas in lean operation of the internal combustion engine. Thus, US Pat. No. 6,739,289 B2 shows a method for enriching a prechamber purge gas with hydrogen. The fuel for the pre-chamber is passed through a reformer to enrich the fuel with hydrogen. As a reformer known thermochemical reactors such as steam reformer can be used. A disadvantage of the known devices and methods is to be mentioned that results in a reduced supply life of the pre-chambers and the components arranged therein by a direct supply of the synthesis gas generated by the reformer to the antechambers of the internal combustion engine.
Object of the present invention is to remedy this situation and to achieve an increased life of the prechamber and arranged therein components.
In particular, an unintentional thermal load (e.g., hot corrosion) of the prechamber and the components disposed therein should be avoided.
This object is achieved by an internal combustion engine with the features of claim 1. Advantageous embodiments of the invention are indicated in the dependent claims.
According to the invention, it is thus provided that a cooling device is provided for cooling the synthesis gas.
The known from the prior art reforming lead the synthesis gas generated by the reformer directly to the antechambers or the combustion chambers of the internal combustion engine. However, the synthesis gas from reforming processes, depending on the operating point temperatures of 500 ° C to 900 ° C. Now, if the synthesis gas is introduced with these high temperatures in the pre-chamber, this leads to an increased thermal load on the components and disadvantages in the combustion, for example, an unwanted auto-ignition can be triggered.
By cooling the synthesis gas, the temperature of the prechamber supplied purge gas can be further reduced, whereby an unnecessarily high thermal load on the prechamber and the components arranged therein can be avoided.
It can preferably be provided that the cooling device has a first cooling stage and a second cooling stage connected downstream of the first cooling stage. In order to achieve optimum integration of the reformer operation with the gas engine operation, it can preferably be provided that the cooling device is part of a cooling circuit which also serves to cool further components of the internal combustion engine, preferably the cylinder liners and / or the cylinder heads.
The reformer may be an autothermal chemical reactor containing hydrocarbons to produce the synthesis gas
Fuel (e.g., natural gas) can be supplied from a fuel source. In an expedient development of the invention it can be provided that the fuel source for the reformer is the first fuel source or the second fuel source. It can also be provided that a single source of fuel supplies both fuel for the combustion chamber and the purge gas and the fuel for the reformer.
However, the supply of the fuel from a separate from the first fuel source and / or the second fuel source fuel source proves to be particularly advantageous when a very low-calorific propellant gas is used as the main fuel for the internal combustion engine. In these cases, the use of the propellant gas of the internal combustion engine as a basis for the thermochemical conversion in the reformer would result in unfavorable combustion properties in the antechambers. By using high calorific value and, for example, for better storage in liquid form fuels, a relatively high calorie synthesis gas can be produced with good combustion properties , The generation of an optimally assembled purge gas, regardless of the nature of the main fuel for the internal combustion engine, allows a much better usability of very low-calorie propellant gases. For example, blast furnace gas or blast furnace gases can be mentioned as the low-heating propellants. For example, diesel fuel or heating oil, LPG (butane or propane) or biogenic fuels such as ethanol or methanol can be used as alternative purge gas fuels.
In a particularly preferred embodiment of the invention it can be provided that at least one of the following material flows can be fed to the reformer via at least one material flow line: water and / or water vapor and / or air and / or a fuel-air mixture and / or an exhaust gas Internal combustion engine and / or the fuel.
In order to be able to optimally mix the streams to be fed to the reformer, a reform gas mixer can be provided, into which the material flow lines open, wherein the streams which can be fed to the reformer are miscible in the reform gas mixer and a reform gas mixer outlet opens into the reformer feed line.
In order to bring the material flows supplied to the reformer or reform gas mixer to a favorable pressure level, a compressor can be provided by which the air supplied to the reformer and / or the fuel-air mixture fed to the reformer can be compressed.
It can also be provided that the air supplied to the reformer and / or the fuel-air mixture supplied to the reformer is a partial flow of the air or of the fuel-air mixture for the combustion chamber. The use of a charged for the combustion chamber of the internal combustion engine fuel-air mixture as 02-stream for the reformer brings a significant energy savings over a compression of ambient air in a separate compression device.
A particular embodiment provides that a steam generating device is provided for generating the water vapor which can be fed to the reformer.
Preferably, it can be provided that the steam generating device uses an exhaust heat of the internal combustion engine or the waste heat generated during the generation of the synthesis gas for generating the steam by the steam generating device is arranged in an exhaust pipe or in the synthesis gas line.
In the context of an integrated reformer gas engine concept can also be provided that for the reforming and shift reaction in the reformer, the heat, fuel and cooling circuits of the internal combustion engine and the pressure level of the exhaust gas of the internal combustion engine are used in such a way that for the heating of the streams before Entry into the reformer - especially for the start-up from the cold state - the exhaust heat, for the supply of carbon dioxide (C02),
Water (H20) and oxygen (02) a part of the exhaust gas and for the recooling of the
Reformates or synthesis gas of Gemischkühlwasserkreislauf be used.
Among other things, it may therefore be provided that the exhaust gas of the internal combustion engine can be supplied to the reformer via a material flow line. This exhaust gas stream for the reformer can also be volume controlled via a corresponding flow control valve. A particularly advantageous embodiment provides that the reformer, the exhaust gas is supplied before it flows through an exhaust gas turbocharger, whereby the prevailing front exhaust gas pressure level can be used accordingly.
This can be achieved by virtue of the fact that the stream of material flow branches off from the exhaust line for the exhaust gas, preferably in front of an exhaust gas turbocharger or between exhaust gas turbines of an exhaust gas turbocharger of the internal combustion engine. In multi-stage exhaust gas turbochargers - for example with two exhaust gas turbines - can therefore be provided that the exhaust gas is removed between the two exhaust gas turbines and thus has the prevailing pressure level there. But it is of course also possible to remove the exhaust gas after flowing through the exhaust gas turbocharger and supply the reformer. In this case, the exhaust gas has a lower pressure level than before the exhaust gas turbocharger or between the exhaust gas turbines of the exhaust gas turbocharger.
Preferably, it can also generally be provided that an exhaust gas filter is arranged in the material flow line for the exhaust gas. This has a positive effect on the service life of the catalyst surface of the reformer.
Depending on the engine operating point, exhaust gas usually consists of the components water vapor of about 11% by volume, carbon dioxide (CO 2) of about 5% by volume and oxygen (O 2) of about 10% by volume. The rest are nitrogen (N2) and other trace components. About the ratio of the metered exhaust gas to be reformed fuel, the combustion behavior of the internal combustion engine can be influenced. With a higher proportion of exhaust gas combustion in the pre-chamber is cooler and the ignition pulse in the combustion chamber weaker. Thus, e.g. increases the burning time and increases the knock resistance at the expense of a slightly poorer efficiency of the internal combustion engine and the maximum cylinder pressure can be reduced. This may be desirable in order to achieve an optimal adjustment of the combustion process to propellants with temporally variable knock resistance or to operate the internal combustion engine temporarily in an overload operation, for example for peak load coverage.
It has proved to be advantageous if the fuel quantity supplied to the reformer is about 1 to 2% by volume of the total fuel quantity of the internal combustion engine. In relation to this, favorably, the amount of exhaust gas supplied to the reformer may be about 3 times to 5 times that of the gas volume flow.
Compared with the use of steam, exhaust gas also has chemical advantages in addition to the energetic ones, so that, ideally, the use of exhaust gas makes it possible to dispense with a separate metering in of steam.
The higher the proportion of water vapor in the mass flow mixture in the reformer feed line, the more the reaction equilibrium shifts to the side of H 2 and CO 2 at the expense of CO and the lower the risk of fouling of the catalyst surface of the reformer. However, the introduced into the reformer water vapor is only used up to a part of chemical. The other part leaves the reformer with the synthesis gas. According to a preferred embodiment of the invention can therefore be provided that the cooling device is followed by a Kondensatabscheidevorrichtung. After re-cooling the synthesis gas to e.g. 45 ° C., a condensate, preferably water, accumulating in the condensate separation device can be traceable to the reformer via a condensate line. The condensate can be injected directly under pressure into the reformer or a reform gas mixer or in a material flow leitu ng for the exhaust gas of the internal combustion engine or even after evaporation as steam in the reformer or reforming gas mixer or in a material flow line for the exhaust gas Internal combustion engine are introduced. For evaporation, while the 9
Generating the synthesis gas resulting waste heat or waste heat of the internal combustion engine, e.g. the waste heat, be used.
In general, the amounts of the material flows to be supplied to the reformer or the reform gas mixer (eg water, air, fuel-air mixture, water vapor, exhaust gas, fuel) can be controlled via corresponding mass flow valves and the fuel to be supplied to the purge gas or the purge gas mixer or methane contained therein ( CH4) are adjusted via a purge gas fuel valve, for example via a corresponding control or regulating device. A change in the corresponding mass flow and purge gas fuel quantities can also be made by an existing engine management system.
This allows adjustment and regulation of the composition of the purge gas according to engine operating parameters by controlling the reformer on the material flow rates of the streams and thus reforming the optimum amount of the fuel and subsequent mixture of synthesis gas with non-reformed fuel. Such a setting and regulation of a suitable composition of the purge gas, which is dependent on an operating parameter of the internal combustion engine (eg, engine load), enables optimization of engine operation with regard to efficiency, optimization of engine operation with regard to emissions and minimization of energy losses due to the high temperatures in the reformer ( exothermic reformer reaction). In particular, this can be achieved that in the reformer only that amount of hydrogen (H2) is produced, which is necessary for optimum purge gas properties. As a result, optimum and economical operation can be ensured even in fluctuating operating states of the internal combustion engine and partial load cases. In general, this can be used to respond to changes in engine operation (e.g., partial load) and thereby achieve minimum levels of nitrogen oxide (NO *) emissions while minimizing soot and total hydrocarbon emissions (THC).
Preferably, the composition of the purge gas can be adjusted so that it has a hydrogen content of 10-35 vol .-% and a Methanantei! of 10-35 ················································································································································································································· · * - *
% By volume. The hydrogen and methane content in the spinning gas may also be in an analytical function to an operating parameter of the internal combustion engine (e.g., engine load) and to the fuel composition.
In the case of a control or regulation of the purge gas composition, sensors for hydrogen and / or carbon monoxide and / or carbon dioxide can be present at sensors at suitable measurement points in the internal combustion engine installation known to the person skilled in the art. Furthermore, the volume flows of the material streams to the reformed gas mixer and to the purge gas mixer can be measured at suitable locations with suitable measuring devices. Thus, for example, the gas composition of the synthesis gas can be measured with gas sensors at the reformer outlet and used for metering the material flows to be fed to the reformer, depending on an operating parameter of the internal combustion engine (for example engine load). However, it is also possible to calculate the synthesis gas and purge gas compositions via the measured volumetric flows of the material streams and the known operating characteristic of the reformer.
Depending on the engine load, the purge gas must be brought to the appropriate boost pressure, for example 3 to 4.5 bar (g), ie 3 to 4.5 bar overpressure with respect to the atmospheric pressure of approximately 1 bar. However, the material streams (e.g., water, air, fuel-air mixture, water vapor, exhaust gas, fuel) for the hydrogen reforming process are not normally available at this pressure level. Therefore, it may be preferable to provide a purge gas compressor for compressing purge gas to generate the required purge pressure. It may be provided that a control or regulation of the purge gas pressure is effected as a function of an operating parameter of the internal combustion engine (for example engine load). This can be ensured that only one required for a specific operating point compression energy is spent.
Furthermore, it can be provided that at least one
Purge gas heating device is provided for heating the purge gas. In conjunction with a targeted re-cooling and condensate separation of the synthesis gas can thus an undesirable condensation of the purge gas
Ί1 and thus damage in the antechamber (eg, corrosion) can be avoided. Preheating of the purge gas may also be accomplished using engine waste heat (e.g.
Exhaust gas, engine cooling water) or using the synthesis gas heat.
Particularly advantageous is that embodiment of the invention in which a purge gas buffer is provided for temporarily storing the purge gas in the purge gas. As a result, the controllability of the required amount of purge gas can be improved.
According to a further embodiment, it can be provided that a partial flow of the purge gas can be supplied to the combustion chamber via a partial flow line which opens into the combustion chamber conduit. This is particularly advantageous if a regulation of the amount of purge gas is carried out via a bypass. Generally, it may be advantageous for stabilization and simpler or more reliable control and control of the thermochemical process in the reformer to produce a larger amount of syngas in the reformer, as is required for flushing the pre-chambers, and the excess amount together with a fuel-air mixture Supply combustion chambers of the internal combustion engine.
In a further embodiment, a desulfurization device for desulfurizing the fuel may be provided. This has a positive effect on the service life of the catalyst surface of the reformer.
Further details and advantages of the present invention will be explained with reference to the following description of the figures. It shows or show:
1 shows an embodiment of a proposed internal combustion engine with reformer and cooling device for the synthesis gas,
Fig 2a a further embodiment of a proposed
Internal combustion engine with air and water vapor streams for the reformer,
Fig. 2b is a schematic detail of a reformer with preheating of the entire mass flow mixture for the reformer and
Fig. 3 shows another embodiment of a proposed
Internal combustion engine with a steam generating device in an exhaust pipe of the internal combustion engine and supply of fuel-air mixture to the reformer.
1 shows an internal combustion engine 1 with a combustion chamber 2 and an antechamber 5, which is assigned to the combustion chamber 2 and serves as an ignition amplifier for the combustion chamber 2. The combustion chamber 2 is supplied via a combustion chamber line 3, a fuel B-ι from a first fuel source 4. The first fuel source 4 may be a natural gas supply (for example natural gas pipeline). The fuel Bi for the combustion chamber 2 is mixed in this example in a main flow mixer 29 with ambient air L to a fuel-air mixture and passed through an exhaust gas turbocharger 25. The exhaust-gas turbocharger may have one or two compressor stages 25a, 25b (indicated by dashed lines), which are connected via one shaft (indicated by dashed lines) to one or two exhaust-gas turbines 25a ', 25b' in the exhaust gas line 23 of the internal combustion engine 1. After compression in the compressor stage or stages 25a, 25b, the fuel-air mixture is passed through two main flow cooling stages 30a and 30b to cool the fuel-air mixture and thus improve the combustion characteristics in a known manner.
In the antechamber 5 of the internal combustion engine 1, a purge gas S is introduced via a purge gas line 6. This purge gas S comprises a fuel B2 and a synthesis gas R, which is generated in a reformer 11. In a purge gas mixer 7 via a synthesis gas line 9, the synthesis gas R and introduced via a fuel line 8 of the fuel B2 and mixed. The mixer outlet 10 opens into the purge gas line 6. The fuel B2, which is introduced via the fuel line 8 in the purge gas mixer 7, for example, from the first fuel source 4 and / or a separate second fuel source 4 'originate.
The reformer 11 is supplied with a fuel B3 via a reformer feed line 12 for the reforming process. In the concrete example, the reformer feed line 12 is.... *. *. *. * *. * I *. *. *. *. * * * * * ............. upstream of a reforming gas mixer 26 into which a plurality of material streams can be supplied and mixed via material flow lines 20a, 20e, 20f. The fuel B3 is thus supplied to the reformed gas mixer 26 via the material flow line 20f. Depending on the sulfur loading of the fuel B3, it may be advantageous for the component service life to desulfurize the fuel B3 before it is fed to the reforming process via a suitable desulfurization device 32. The desulfurization reduces the deactivation of the catalyst and thus increases the life of the catalyst. The optional desulfurization device 32 is indicated by dashed lines in the material flow line 20f. In the reformed gas mixer 26, the desulfurized fuel B3 with the other streams of water W and exhaust gas A, which can be supplied via the fabric flow lines 20a and 20e, are mixed. The reformer gas mixer outlet 27 then flows into the reformer feed line 12.
The material streams which can be fed to the reform gas mixer 26 in addition to the fuel B3 are in this embodiment water W which can be supplied to the reformed gas mixer 26 via the material flow line 20a and a partial flow of the exhaust gas A of the internal combustion engine 1 which is filtered by an optional (dashed line) filtering in an exhaust gas filter 31 can be supplied to the reformed gas mixer 26 via the material flow line 20e. By supplying a partial flow of the exhaust gas A, which may rest for example at a pressure of 4 bar (g) and a temperature of 500 ° C to the material flow line 20e, both the favorable for a reforming chemical composition of the exhaust gas A and its pressure - And temperature level for the reforming process can be used advantageously. For the removal of the exhaust gas A is provided that the material flow line branches off 20e for the exhaust gas A from the exhaust pipe 23, preferably in front of an exhaust gas turbocharger 25 or between exhaust gas turbines 25a ', 25b' of an exhaust gas turbocharger 25 of the internal combustion engine 1. It can also be provided that the exhaust gas A is diverted to the exhaust gas turbines 25a ', 25b' of the exhaust gas turbocharger 25. In the example shown, the exhaust gas A is removed in front of the exhaust gas turbocharger 25 and thus at a pressure level of, for example, 4 bar (g), the alternative options are indicated by dashed lines.
When using a single fuel source 4 for the fuel Bi for the combustion chambers 2 of the internal combustion engine 1, the fuel B2 for the purge gas S and the fuel B3 for the reformer 11, a division of the fuel may preferably be such that 99% of the fuel of the fuel source for the fuel Bi and 1% of the fuel for the fuel B2 and the fuel B3 are used. The fuel source 4 may be a natural gas source providing a natural gas with a pressure greater than 4 bar (g), and the distribution of this natural gas flow may be accomplished with the aid of suitable dosing or control valves 39a, 39b known in the art.
In the example shown, the reformer 11 is an autothermal reformer which provides a hydrogen-enriched synthesis gas R at its reformer outlet 14. This synthesis gas R has at the reformer exit 14 typically at a temperature of 500 ° C to 900 ° C. A arranged in the synthesis gas line 9 heat exchanger 13 can be used to use this high temperature of the synthesis gas R. For example, the heat exchanger 13 can be used to heat the feed streams fed to the reform gas mixer 26 or the entire mass flow mixture which is fed to the reformer 11 via the reformer feed line 12 after the reform gas mixer 26. Characterized in that the synthesis gas R heat energy is removed in the heat exchanger 13, the heat exchanger 13 can also be regarded as a cooling device according to the invention. However, the material flows supplied to the reform gas mixer 26 can also be preheated via other heat exchange devices of the internal combustion engine 1. For example, the engine waste heat (e.g., exhaust heat) can be used to preheat the streams.
The synthesis gas R is guided in the embodiment shown after the heat exchanger 13 by a cooling device 15, which in this example comprises a first cooling stage 15a and a second cooling stage 15b. As part of an integrated reformer gas engine concept, the cooling device 15 in this embodiment part of a cooling circuit 16, which also serves to cool other components of the internal combustion engine 1. In this example, the syntax is also ·····························································. »· I ·» 4 · $ 4 1.1 • II · ** Τ5 ·! * · - ·········· ·
Main flow cooling stages 30a and 30b part of the cooling circuit 16. Alternatively or in addition to the use of a present in the internal combustion engine 1 cooling circuit 16, it may be advantageous to perform a cooling of the synthesis gas R via an independent of the internal combustion engine 1 cooling circuit. The cooling energy required for this purpose can be provided, for example, via cooling water (for example well water cooling) or a refrigerating machine.
From the reforming process and via the introduced material streams, the synthesis gas R contains a considerable amount of water vapor. In order to prevent that when the synthesis gas R is cooled below the dew point, an undesirable condensate is formed, which could lead to an impairment of the engine operation, in this example the cooling device 15 is a
Condensate separation device 17 downstream in the controlled condensate K from the synthesis gas R can be deposited. The resulting condensate K in the Kondensatabscheidevorrichtung 17 can be recycled via a condensate line 18 back to the reformer 11. In the example shown, the condensate line 18 opens into the material flow line 20a through which water W can be introduced into the reformed gas mixer 26. The condensate K in the form of water is injected after an increase in pressure in a condensate pump 35 via the material flow line 20a directly or via an optional evaporator 36 (dashed lines indicated) in the reformed gas mixer 26 or the material flow line 20e for the exhaust gas A of the internal combustion engine 1. In this case, heat from the exhaust gas A or the synthesis gas R can be used for the evaporation.
In order to bring the purge gas S depending on the engine load to the corresponding boost pressure of about 3 to 4.5 bar (g), a purge gas compressor 19 is provided in the purge gas line 6. About arranged in the purge gas line 6
Spülgaserwärmungseinrichtungen 24 may also be the purge gas S are heated prior to introduction into the pre-chamber 5. To improve the controllability of the amount of purge gas, a purge gas buffer 28 is arranged in the purge gas line 6 in this example. • ♦ «· * ·« ··· «« ······
In the example shown, it is also provided that a partial flow of the purge gas S via a partial flow line 37, which opens into the combustion chamber conduit 3, the combustion chamber 2 can be fed. This is particularly advantageous if a regulation of the amount of purge gas is to take place via a bypass, which is formed by the partial flow line 37. For controlling this bypass purge gas amount, a corresponding flow control device 38 can be used.
In addition or as an alternative to exhaust gas recirculation in the reform gas mixer 26, air and water vapor can also be supplied to the reform gas mixer 26 as separate material streams. This variant is shown schematically in FIG. 2a. In this case, ambient air L is compressed in a compressor 21 and fed to the reformed gas mixer 26 via the material flow line 20c. Water W is converted into steam D in a steam generating device 22 and this water vapor D is supplied to the reformed gas mixer 26 via the material flow line 20b.
FIG. 2b schematically shows a detailed illustration of a reformer 11 according to FIG. 2a. Here, a heat utilization of the synthesis gas heat takes place in such a way that the heat removed from the synthesis gas R by a heat exchanger 13 is used to preheat the entire mass flow mixture which is present at the reformed gas mixer outlet 27. For this purpose, the reformer feed line 12 is guided through the heat exchanger 13 and thus heats the material flow mixture flowing through the reformer feed line 12. The heat exchanger 13 thus experiences a double use, since on the one hand, the synthesis gas R cooled and on the other hand, the entire mass flow mixture for the reformer 11 is preheated.
Instead of compressing the air L via a separate compressor 21, the compressed fuel-air mixture G, which bears against the combustion chamber conduit 3 for the combustion chamber 2 of the internal combustion engine 1, can also be supplied to the reform gas mixer 26. This example is shown schematically in FIG. Here, a partial flow of the compressed for the combustion chamber 2 of the internal combustion engine 1 fuel-air mixture G is supplied to the reformed gas mixer 26 via the material flow line 20d. 17
In addition, in this example, a steam generating device 22 is arranged in the exhaust pipe 23 of the internal combustion engine 1 and thus makes use of the exhaust heat of the internal combustion engine 1 use. For steam generation in the steam generating device 22 but also the high temperature of the synthesis gas R after the reformer 11 using the heat exchanger 13 could be used.
The waste heat of the heat exchanger 13 can generally also be used for preheating the material flows to be fed to the reformer 11 or the reformed gas mixer 26, for preheating the purge gas S to reduce the relative humidity, or for integration into heat utilization of the gas engine plant (e.g., district heating integration).
In principle, an integration of the sensible heat and the heat of condensation from the synthesis gas cooling by means of heat exchanger 13 and / or cooling device 15 into the engine cooling water circuits can take place in the sense of an economic waste heat utilization of the entire system. This can be done in several stages, for example, by integration into the engine cooling water system for waste heat utilization and / or additional integration into the cooling water circuit of the mixture cooling. If necessary, further cooling and condensation of the synthesis gas R can be additionally carried out by means of external refrigeration (for example well water cooling or refrigeration machine).
In general, the amounts of the material flow lines W, D, L, G, A, B3 to be supplied to the reformer 11 or the reform gas mixer 26 via the material flow lines 20a-20f can be controlled via corresponding material flow valves 33a-33f provided with metering devices and the purge gas S or the fuel to be supplied to the purge gas mixer 7 B2 are adjusted via a purge gas fuel valve 34, for example, via a corresponding control or regulating device. A change in the corresponding mass flow and Spülgastreibstoffmengen can also be made by a motor control or regulation.
Thereby, an adjustment and regulation of the composition of the purge gas S as a function of at least one engine operating parameter by controlling the reformer 11 via the material flow amounts of the streams W, D, L, G, A, B3 and thus reforming the respective optimum amount of the fuel B3 and subsequent mixture of the synthesis gas R produced in the reformer 11 with non-reformed fuel B2. Such adjustment and regulation of a suitable composition of the purge gas S depending on an operating parameter of the internal combustion engine 1 (e.g., engine load) enables, among other things, optimization of engine operation in terms of efficiency, optimization of engine operation for emissions, and minimization of energy losses. In particular, this makes it possible to achieve minimal nitrogen oxide (NOx) emissions while simultaneously minimizing soot and total hydrocarbon emissions (THC).
By using material and energy flows of the gas engine system (exhaust gas, fuel, fuel-air mixture, cooling water) can also be achieved an integrated gas engine-reformer unit. By using existing plant components and appropriate process engineering interconnection, an efficient overall system can be achieved. By an optimized interconnection of the material and energy flows of the internal combustion engine and the reformer unit as economical as possible operation of the entire system can be made possible.
Innsbruck, 18 October 2011

权利要求:
Claims (19)
[1]
* • • · · * III III III III III III III III III III III III III III III III III III III III III III III III III III III III....... ............... 70814 30/30 Claims: 1. Internal combustion engine (1), in particular stationary gas engine, comprising a combustion chamber (2), via a combustion chamber line (3) a fuel (Β 1), a pre-chamber (5), via a purge gas line (6) a purge gas (S) can be fed, wherein a purge gas mixer (7) is provided, in which a via a fuel line ( 8) feedable fuel (B2) from the first fuel source (4) or from a second fuel source {4 ') and a synthetic gas (R) which can be supplied via a synthesis gas line (9) are mixable and a mixer outlet (10) is introduced into the purge gas line (6). wherein the synthesis gas (R) can be produced by a reformer (11) to which a fuel (B3) from a fuel source (4, 4) is fed via a reformer feed line (12) ) Can be fed and whose output reformer (14) opens into the synthesis gas line (9), characterized in that a cooling device (13, 15) for cooling the synthesis gas (R) is provided.
[2]
2. Internal combustion engine according to claim 1, characterized in that the cooling device (13, 15) has a first cooling stage (15a) and one of the first cooling stage (15a) downstream of the second cooling stage (15b).
[3]
3. Internal combustion engine according to claim 1 or 2, characterized in that the cooling device (13, 15) is part of a Kühlkreisiaia (16), which also serves to cool other components of the internal combustion engine (1), preferably the cylinder liners and / or cylinder heads.
[4]
4. Internal combustion engine according to one of claims 1 to 3, characterized in that the cooling device (13, 15) is followed by a Kondensatabscheidevorrichtung (17).
[5]
5. Internal combustion engine according to claim 4, characterized in that in the Kondensatabscheidevorrichtung (17) resulting condensate (K), preferably water, via a condensate line (18) the reformer (11) is traceable. 2


[6]
6. Internal combustion engine according to one of claims 1 to 5, characterized in that a purge gas compressor (19) for compressing the purge gas (S) is provided,
[7]
7. Internal combustion engine according to one of claims 1 to 6, characterized in that the fuel source for the reformer (11) is the first fuel source (4) or the second fuel source (4 ').
[8]
8. Internal combustion engine according to one of claims 1 to 7, characterized in that the reformer (11) via at least one material flow line (20a, 20b, 20c, 20d, 20e, 20f) at least one of the following material flows can be fed: water (W) and / or water vapor (D) and / or air (L) and / or a fuel-air mixture (G) and / or an exhaust gas (A) of the internal combustion engine (1) and / or the fuel (B3).
[9]
9. Internal combustion engine according to claim 8, characterized in that a reformed gas mixer (26) is provided, in which the material flow lines (20a-20f) open, wherein in the reformed gas mixer (26) the reformer (11) feedable streams are miscible and wherein a Reformgasmischerausgang (27) flows into the reformer supply line (12).
[10]
10. Internal combustion engine according to claim 8 or 9, characterized in that a compressor (21) is provided, through which the reformer (11) supplied air (L) and / or the reformer (11) supplied fuel-air mixture ( G) is compressible.
[11]
11. Internal combustion engine according to one of claims 8 to 10, characterized in that the reformer (11) supplied air (L) and / or the reformer (11) supplied fuel-air mixture (G) is a partial flow of the air or of the fuel-air mixture for the combustion chamber (2).
[12]
12. Internal combustion engine according to one of claims 8 to 11, characterized in that the Stoffstrom leitu ng (20e) for the exhaust gas (A) of the * * ··· * · I • * · · · · · Μ * «* · ♦ * • * * * * * · exhaust pipe (23) branches off, preferably in front of an exhaust gas turbocharger (25) or between exhaust gas turbines (25a ', 25b') of an exhaust gas turbocharger (25) of the internal combustion engine (1).
[13]
13. Internal combustion engine according to claim 12, characterized in that in the material flow line (20e) for the exhaust gas (A) an exhaust gas filter (31) is arranged.
[14]
14. Internal combustion engine according to any one of claims 8 to 13, characterized in that a steam generating device (22) for generating the reformer (11) can be supplied with water vapor (D) is provided.
[15]
15. Internal combustion engine according to claim 14, characterized in that the steam generating device (22) for generating the water vapor (D) uses exhaust heat of the internal combustion engine (1) or the heat generated during the generation of the synthesis gas (R) by the steam generating device (22) in an exhaust pipe (23) or in the synthesis gas line (9) is arranged.
[16]
16. Internal combustion engine according to one of claims 1 to 15, characterized in that at least one purge gas heating device (24) for heating the purge gas (S) is provided.
[17]
17. Internal combustion engine according to one of claims 1 to 16, characterized in that in the purge gas line (6) a purge gas buffer (28) for temporarily storing the purge gas (S) is provided.
[18]
18. Internal combustion engine according to one of claims 1 to 17, characterized in that a partial flow of the purge gas (S) via a partial flow line (37) which opens into the combustion chamber line (3), the combustion chamber (2) can be fed.
[19]
19. Internal combustion engine according to one of claims 1 to 18, characterized in that a desulfurization device (32) for desulfurizing the fuel (B3) is provided. Innsbruck, 18 October 2011

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同族专利:

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US20140216029A1|2014-08-07|

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CN103975139A|2014-08-06|

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US9926837B2|2018-03-27|

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WO2013056283A1|2013-04-25|

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EP2769066A1|2014-08-27|

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AT511338B1|2012-11-15|

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATA1529/2011A|AT511338B1|2011-10-19|2011-10-19|Combustion engine, in particular a stationary gas engine, comprising a combustion chamber|ATA1529/2011A| AT511338B1|2011-10-19|2011-10-19|Combustion engine, in particular a stationary gas engine, comprising a combustion chamber|

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PCT/AT2012/000246| WO2013056283A1|2011-10-19|2012-10-02|Internal combustion engine, in particular a stationary gas engine, comprising a combustion chamber|

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EP12778196.1A| EP2769066A1|2011-10-19|2012-10-02|Internal combustion engine, in particular a stationary gas engine, comprising a combustion chamber|

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CN201280060078.1A| CN103975139A|2011-10-19|2012-10-02|Internal combustion engine, in particular a stationary gas engine, comprising a combustion chamber|

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US14/247,590| US9926837B2|2011-10-19|2014-04-08|Internal combustion engine, in particular a stationary gas engine, comprising a combustion chamber|