The present invention relates to a combustion system with low polluting emissions, in particular a combustion system for a gas turbine.
It is known that gas turbines are machines consisting of a compressor and a turbine with one or more phases, which are connected to each other by at least one combustion chamber.
Air from the outside environment is fed to the compressor to bring it under pressure.
The pressurized air passes through a premixing chamber, terminating with a nozzle or convergent portion. In said chamber, at least one injector feeds fuel which is mixed with the air to form an air-fuel mixture to be burnt.
The fuel necessary for producing combustion is therefore introduced into the combustion chamber by means of a pressurized network. The purpose of said combustion is to cause an increase in the temperature and enthalpy of the gas.
In order to improve the flame stability characteristics, a parallel fuel feeding system, suitable for generating a pilot flame, is also generally envisaged.
U.S. Pat. No. 5,381,652 indicates a combustion system for gaseous fuels in which a main flame is stabilized by means of a pilot device.
In this case, the pilot device injects pilot fuel gas into the combustion chamber, with which the combustion system is equipped.
A duct is present in the combustion system, for premixed air which flows to a first central duct in which there is a first series of radial holes for the fuel gas which feeds the main flame.
In the main duct, the air is premixed with the gaseous fuel fed by injection through a second series of holes, which are situated on cylinders positioned on a section of the main air duct, at the same distance along the perimeter of the section itself.
In this case, the injection of the pilot fuel is effected by means of a first series of radial holes situated at the outlet of the premixing duct, surrounding the main flame.
As this pilot fuel has not been previously mixed with comburent air, it burns in flames mainly controlled by the diffusion process of the fuel in the comburent air, which are consequently called diffusion flames.
Diffusion flames are characterized by the presence of areas in which the temperature is extremely high, therefore causing high polluting emissions.
The emission of nitrogen oxides is, in fact, proportional to the maximum flame temperature and flames of the diffusion type having high temperatures are consequently most responsible for polluting emissions, in particular emission of nitrogen oxides.
One of the disadvantages of the present system is that it has moderate polluting emissions due to the presence of diffusion-type flames.
U.S. Pat. No. 5,666,044 describes the use of pilot devices for stabilizing the main flame, which inject fuel gas through nozzles into the combustion chamber.
Air, necessary for the combustion of the fuel gas injected by means of the pilot device is contemporaneously injected into the combustion chamber, in an area adjacent to each pilot device. Also in this case, the mixing takes place in the combustion chamber, and the flames are consequently of the diffusive type, even if the presence of the high quantity of air in the area adjacent to the injection, reduces the extension of high temperature areas.
A combustion system is also known from the patent application EP 1321715A2, which can be used with liquid or gaseous fuel, in which there are devices which inject the pilot fuel directly into the combustion chamber.
One of the disadvantages of this solution is that it generates significant emissions of polluting agents, also in this case due to the presence of flames of the diffusion type used for stabilizing the main premixed flame.
An objective of the present invention is to provide a combustion system with low polluting emissions which allows a reduction in the polluting emissions of gas turbines.
Another objective is to provide a combustion system with low polluting emissions which allows reduced oscillations of the pressure inside the combustion chamber and at the same time allows the flame to be stabilized.
A further objective is to avail of a combustion system with low polluting emissions which allows a high duration of the components subject to high temperatures.
Yet another objective is to avail of a combustion system with low polluting emissions which allows a high combustion efficiency and at the same time has low polluting emissions.
These objectives according to the present invention are achieved by providing a combustion system with low polluting emissions as specified in claim 1.
Further characteristics of the invention are described in the subsequent claims.
The characteristics and advantages of a combustion system with low polluting emissions according to the present invention will appear more evident from the following illustrative and non-limiting description, referring to the enclosed schematic drawings, in which:
With reference to the figures, these illustrate a combustion system with low polluting emissions, indicated as a whole with 10, which comprises a combustion chamber containing a “liner” or flame tube 14 suitable for containing a main flame.
The flame tube 14 has a tapered connection end 15 to a premixing chamber 12 of the air, in correspondence with a terminal section 13 of the premixing chamber 12.
The air premixing chamber 12 is substantially a duct in the form of a circular crown which has a tapered section, or narrower section, towards a connecting end to the combustion chamber, to accelerate the air after this has been premixed using fuel gas fed by a series of holes 11 preferably situated on cylindrical elements positioned in the perimeter of the premixing chamber 12.
Said series of holes 11 is situated along a section which precedes the tapered end of the air premixing chamber 12.
The tapered end of the air premixing chamber 12 has a circular section in which there is a central body 17 which extends into said tapered end for the injection of air suitable for preventing the flame from touching the surface of the central duct 17.
The combustion system 10 preferably comprises a series of thermocouples 19, outside the central duct 17.
The flame is normally formed in the combustion chamber downstream of the premixing chamber 12.
If, as a result of some abnormal functioning, the flame rises into the premixing chamber 12, the thermocouples 19 detect the increase in temperature and the flow of gas is interrupted to protect the premixing chamber 12 from excessive temperatures.
The tapered end 15 of the flame tube 14 has a surface in the form of a circular crown on which there are a series of pass-through holes 18 for housing a respective series of premixed fuel gas injection pilot devices 20 in order to stabilize the main central flame and at the same time maintain low levels of polluting emissions.
This is achieved by using a series of fuel gas premixing pilot devices 20, in which the fuel gas is mixed with a turbulent stream of air, obtaining a homogeneous mixture of fuel gas/air, before the injection of the mixture itself into the combustion chamber.
This allows a reduction in the polluting emissions of NOx as diffusion-type flames are avoided.
The combustion system 10 has a series of pilot devices 20 with premixing of the fuel gas which allow the main central flame to be stabilized, at the same time reducing the polluting emissions through a corresponding series of external flames.
Each pilot device of the series of pilot devices 20 comprises a premixing duct 29, a series of holes 28, inside the premixing duct 29, for the feeding of the fuel and a unit 24 acting as a swirler; said unit 24 has the function of creating a turbulent and whirling flow of air capable of uniformly mixing with the fuel gas fed through the series of holes 28 inside the device itself.
The turbulent flow of air is mixed with the fuel gas fed through the series of ducts 28, forming a homogeneous mixture of air and fuel gas inside the premixing duct 29, before the introduction of the combustion system 10 into the combustion chamber.
In this way, for each pilot device 20 a corresponding flame is obtained, having a maximum temperature lower than that of diffusion flames.
Consequently, as the maximum flame temperature is lower, the polluting emissions, among which NOx emissions, are correspondingly reduced.
The combustion system 10 comprises a series of pilot devices 20 each arranged in a respective hole of the series of ducts 18 which are distributed at an equal distance on a circumference lying on the surface of the end 15 of the flame tube 14 and coaxial with its axis.
The unit 24 of each pilot device 20 comprises at least one shaped element capable of increasing the turbulence of the flow of air in the premixing duct 29.
The air flow for each premixing pilot device 20 is preferably fed directly from the air flow coming from a compressor.
Furthermore, the flame of each pilot device 20 is stabilized.
The stabilization of the flame of premixed pilot burners 20 is effected by the injection of pilot fuel gas (therefore a sub-pilot) which stabilizes the premixed pilot flame which in turn stabilizes the main premixed flame.
The sub-pilot fuel gas produces diffusion flames but as only the premixed pilot fuel gas has to be stabilized, only a small quantity of fuel is used, thus producing lower polluting emissions of NOx.
According to an aspect of the present invention, a first preferred embodiment is provided, shown in
The pilot device 20 comprises a central element 42 inside the premixing duct 29 which internally comprises a central duct 43 in turn inside and coaxial to an annular duct 34.
The annular duct 34 has the function of feeding the fuel gas which, through the series of holes 28, is premixed with the air inside the premixing duct 29.
In this case, the flame relating to the pilot device 20 is centrally stabilized by the injection of combustible fluid through the duct 43.
Each pilot device of the series of fuel gas premixing pilot devices 20, also comprises two ducts 32 inside the premixing duct 29 to detect the flow-rate of the fluid inside the pilot device itself.
According to another aspect of the present invention, a second embodiment is provided, shown in
This embodiment is analogous to the first, except for the stabilization of the flame.
In this case, in fact, the flame relating to the pilot device 20 is centrally stabilized by the injection of combustible fluid by means of a central mini-burner 45 inside the premixing chamber 29.
Said mini-burner 45 is connected downstream of a central element inside the premixing duct 29, also present in the second embodiment, which internally comprises a central duct 43, in turn inside and coaxial to an annular duct 34.
The annular duct 34 has the function of feeding the fuel gas which, through the series of holes 28, is premixed with the air inside the premixing duct 29.
The duct 43 feeds the sub-pilot fuel gas for the mini-burner 45, whereas the air flow for the mini-burner 45 is fed by a series of holes 35 situated therein and is made turbulent by means of a further swirler present inside the mini-burner 45 itself.
According to another aspect of the present invention, a third preferred embodiment of a pilot device 20 is provided, shown in
Each premixing pilot device 20 comprises a duct 36 for the fuel gas connected to a series of holes 28 inside the premixing duct 29.
The fuel gas of the duct 36 is injected into the premixing duct 29, through the series of holes 28, for premixing with the turbulent air flow.
The flame of each pilot device 20 in this embodiment is also stabilized by the injection, into the combustion chamber, of fuel gas of a duct 37 fed through a series of holes 30 outside the premixing duct 29, situated on a base surface 31 of an end of the pilot device 20.
The duct 37 is therefore connected to the series of outer holes 30 to fed fuel gas in order to stabilize the flame of the pilot device 20 itself.
Each pilot device of the series of fuel gas premixing pilot devices 20, also comprises at least one thermocouple 33 and two ducts 32 inside the premixing duct 29 to detect the flow-rate of the fluid inside the pilot device 20.
It can be observed that a further fuel feeding duct 70, which surrounds the central duct 17, is also present in the combustion system 10.
Furthermore, said duct 70 is close to the tapered end 15 of the flame tube 14 where this is connected to the premixing chamber 12.
The duct 70 serves to feed the diffusion pilot fuel which surrounds the main flame, which can also be used for ignition or for stabilizing the flame under transitory conditions, when the emissions are not significant.
With reference to
The air coming from the compressor is mixed inside the premixing chamber 12 with the fuel fed from the series of holes 11.
The premixed air is subsequently accelerated and optionally mixed by diffusion with fuel gas fed from the duct 70.
The main flame is stabilized by means of a series of pilot flames functioning with premixed fuel gas.
With reference to
Furthermore, the pilot devices of the series of fuel gas premixing pilot devices 20 are preferably situated in the tapered end 15 of the flame tube 14, but a different arrangement can also be adopted.
The combustion system 10 comprises preferably a duct 60 for feeding air to the series of premixing pilot devices 20.
In conclusion, it can be summarized that a combustion system 10 for a gas turbine comprises a series of pilot devices 20 with premixing of the fuel gas, situated outside the main flame, or in a tapered connection end 15 to the premixing chamber 12, which create a series of corresponding pilot flames suitable for stabilizing the main central flame itself, at the same time reducing polluting emissions.
It can thus be seen that the combustion system with low polluting emissions according to the present invention achieves the objectives specified above.
Numerous modifications and variants can be applied to the combustion system with low polluting emissions of the present invention thus conceived, all included within the same inventive concept.
Furthermore, in practice, the materials used, as also the dimensions and components, can vary according to technical demands.
Number | Date | Country | Kind |
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MI2003A2621 | Dec 2003 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2004/014773 | 12/22/2004 | WO | 00 | 6/29/2006 |
Publishing Document | Publishing Date | Country | Kind |
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WO2005/064239 | 7/14/2005 | WO | A |
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