COMBUSTION CHAMBER FOR A TURBINE, IN PARTICULAR A THERMODYNAMIC CYCLE TURBINE WITH RECUPERATOR, FOR

专利摘要:
The present invention relates to a combustion chamber (18) of a turbine, in particular a thermodynamic cycle turbine with recuperator, for the production of energy, in particular electrical energy, comprising a housing (56) housing a tube flame apparatus (64) with a perforated diffuser for the passage of hot compressed air, a primary zone (ZP), which receives a portion of the hot compressed air flow and in which combustion occurs, and a dilution zone (ZD) where there is mixing between the burnt gases from the primary zone and the remaining portion of the hot compressed air flow, said chamber further comprising a means (76) for injecting at least one fuel. According to the invention, the flame tube (64) carries a flame stabilizer (82) comprising the perforated diffuser (88), at least one recirculation passage (98) of combustion gas and a mixing tube (94).
公开号:FR3041742A1
申请号:FR1559314
申请日:2015-09-30
公开日:2017-03-31
发明作者:Toda Hubert Baya；Jean-Baptiste Michel；Julien Thiriot；Thomas Valin
申请人:IFP Energies Nouvelles IFPEN；
IPC主号:

专利说明:

The present invention relates to a combustion chamber of a turbine, in particular a turbine with a thermodynamic cycle with recuperator, for the production of energy, in particular electrical energy.
It relates more particularly to a microturbine with recuperator for the production of electricity from a liquid or gaseous fuel. Generally, it is understood by microturbine a small power turbine usually less than 200KW.
As better described in the application WO 2012/039611, a turbine with recuperator generally comprises at least one compression stage with at least one compressor, a combustion chamber (or burner), at least one expansion stage with at least one turbine of a heat exchange device (or recuperator) between the compressor and the burner for heating the compressed gases by the compressor to send them with a high temperature to the burner, this exchange device being traversed by the hot gases from of the turbine.
As described in the aforementioned application, the burner comprises an outer casing through which circulates the hot compressed air from the recuperator and a flame tube, located inside this casing, in which takes place combustion.
The flame tube comprises a primary zone that receives a portion of the total hot compressed air flow rate and in which combustion occurs and a dilution zone where mixing between the primary zone burned gases and the compressed gases occurs. from the dilution holes on the tube.
The primary zone further comprises a perforated diffuser allowing the passage of hot compressed air and fuel from a fuel injection system (liquid or gaseous) placed upstream of the diffuser. Generally, a turbine with recuperator has a low compression ratio (of the order of 3 to 5 bars of pressure) and low inlet temperatures of the turbine in comparison with high-power aeronautical or stationary gas turbines. One of the consequences of these operating characteristics is the overall richness in the combustion chamber, lower than 0.20 in general, that is to say below the flammability limits of the fuel.
In addition, there is the problem of the pre-vaporization of the fuel in the case of a liquid fuel. Generally, the combustion mode to achieve low emissions is premixed combustion with poor wealth.
However, this type of combustion poses significant problems in the stabilization of the flame. These problems are all the more reinforced by the action of the recuperator which increases the air temperature at the burner inlet by increasing the risk of instability of the flame.
In addition, the cost of design is also a lock. Indeed, this type of chamber is characterized by a strong interaction between the flame and the wall which requires the choice of expensive materials on a large volume and a cooling system of the walls of the burner generally consists of multiple holes used to create a cushion of air between the flame and the wall. This cooling system results in a significant additional cost in the manufacturing process and a complexity of implementation.
All these disadvantages make it difficult to achieve complete combustion and meet the low emission requirements in terms of nitrogen oxides (NOx), carbon monoxide (CO), unburned hydrocarbons (HC) and particulates (PM) .
The present invention proposes to overcome the aforementioned drawbacks with a low-emission and low-cost combustion chamber design. For this purpose, the present invention relates to a combustion chamber of a turbine, in particular a thermodynamic cycle turbine with recuperator, for the production of energy, in particular electrical energy, comprising a housing housing a flame tube. with a perforated diffuser for the passage of hot compressed air, a primary zone, which receives part of the flow of hot compressed air and in which combustion takes place, and a dilution zone where the mixing between the gases takes place burned from the primary zone and the remaining part of the flow of hot compressed air, said chamber further comprising means for injecting at least one fuel, characterized in that the flame tube carries a flame stabilizer comprising the perforated diffuser, at least one recirculation passage of flue gas and a mixing tube.
The perforated diffuser mixing tube can be carried by arms connected to the perforated diffuser while being away from the perforated diffuser.
The perforated diffuser mixing tube can be carried by arms connected to the flame tube while being away from the perforated diffuser.
The recirculation passage may be formed between the perforated diffuser and the mixing tube.
The housing may include a baffle wall for directing hot compressed air to the flame tube.
The deflecting wall may comprise a semi-toroid wall with a concavity directed towards the flame tube.
The combustion chamber may comprise a multi-fuel injection means. The invention also relates to a turbine, in particular a thermodynamic cycle turbine with recuperator, for the production of energy, in particular electrical energy, comprising at least one compression stage with at least one gas compressor, an exchanger of heat, a combustion chamber fed with fuel by at least one tank, at least one expansion stage with at least one expansion turbine connected by a shaft to the compressor, and a means for producing energy, characterized in that it comprises a combustion chamber as mentioned above.
The other features and advantages of the invention will now appear on reading the following description, given purely by way of illustration and not limitation, and to which are appended: FIG. 1 which is a diagram illustrating a turbine with a combustion chamber according to the invention for the production of energy, in particular electrical energy, - Figure 2 which is an axial sectional view showing the combustion chamber according to the invention, - Figure 3A which is a view of perspective of an element of the combustion chamber according to the invention with a front view (Figure 3B) and a sectional view (Figure 3C), and - Figure 4 which is a sectional view showing another element of the chamber of combustion according to the invention.
In FIG. 1, the turbine illustrated is more particularly a microturbine 10, operating from at least one fuel, such as a liquid fuel, for example of the diesel fuel type, or a gaseous fuel, such as natural gas.
The turbine comprises at least one compression stage 12 with at least one gas compressor 14, a heat exchanger 16 (or recuperator), a combustion chamber 18 (or burner) supplied with fuel by at least one tank 20, at least an expansion stage 22 with at least one expansion turbine 24 connected by a shaft 26 to the compressor. This turbine also comprises a power generation means, here electrical, which comprises an electric generator 28 advantageously placed on the shaft 26 between the compressor and the turbine.
Of course, this generator can be alternately connected to the expansion turbine or to the compressor by a shaft other than that connecting the turbine and the compressor.
Preferably, the heat exchanger 16 may be a cross-flow exchanger, for example of tube-shell or alternating plate with two inputs and two outputs.
The compressor 14 comprises a fresh gas inlet 30 containing oxygen, in this case outside air generally at ambient temperature, and a compressed air outlet 32 leading to a compressed air inlet 34 of the exchanger 16 via a line 36. The hot compressed air outlet 38 of this exchanger is connected by a line 40 to an inlet of hot compressed air 42 of the burner 18. The superheated gas outlet 44 of the burner is connected by a line 45 to the inlet 46 of the turbine whose outlet 48 is connected to another inlet 50 of the exchanger by a line of superheated gas expanded 52. The exchanger 16 also includes a cooled gas outlet 54 to be directed to any means of evacuation and treatment, such as a chimney (not shown).
Referring to Figure 2, the burner 18 comprises an outer casing 56, of cylindrical shape of diameter D1, closed at one of its ends by an injector wall 58 and at the other end thereof by a partition annular 60 with an opening 62 of inner diameter D2. This burner also comprises a flame tube 64, also of substantially cylindrical shape, housed coaxially in the housing being of smaller diameter than the housing but of identical diameter to that of the opening 62 of the annular partition 60. This tube comprises one end closed by a diffusion partition 66 opposite and away from the injector partition 58 and an open end 67 which passes through the annular partition cooperating sealingly with the inner diameter of the annular partition to form the outlet 44 of the burner.
The housing carries, on its periphery 68 and near the annular partition 60, the hot compressed air inlet 42 for introducing this air into the space 70 formed between the housing and the flame tube as well as in the space 72 formed between the injector partition and the diffusion partition.
As best illustrated in FIG. 2, the injector partition comprises a plate 74, through which is mounted a means for injecting at least one fuel 76, here in the form of an injector coaxial with the flame tube. . This plate is surrounded by an air deflecting wall 78, here semi-toroid whose concavity is directed towards the flame tube and which is connected to the periphery 68 of the housing.
The flame tube comprises circumferential rows of radial dilution orifices 80 spaced apart from the diffusion partition and close to the annular partition of the housing, being distributed advantageously advantageously opposite the inlet 42. This flame tube comprises also a flame stabilizer 82 which is placed on the diffusion partition 66 and inside the tube being housed in an orifice 84 provided in this diffusion partition.
This flame stabilizer makes it possible to generate burnt gas recirculation zones facilitating the ignition of the fuel and bringing inertes locally into the reaction zone. It also allows the physicochemical stabilization of the flame as well as the confinement of combustion.
The burner also includes an ignition device 86 for a fuel mixture. By way of example, this device can be a spark plug of the type for internal combustion engine with spark ignition, a glow plug, ignition electrodes, ....
In any case, the position of the ignition device must be in an area of the burner that is not directly exposed to the flame in order to preserve it.
Preferably, as illustrated in FIG. 2, the active end of this ignition device is located just after the flame stabilizer.
The burner thus constituted comprises a flame tube with a zone of injection / mixture ZM where the mixing of the hot compressed air with the fuel and the beginning of the combustion is carried out, a primary zone ZP in which the combustion takes place, a ZD dilution zone where the mixing between the burnt gases from the primary zone and the hot compressed air coming from the dilution holes takes place. This dilution zone has as main aims to reduce the temperature of the gases leaving the dilution zone and to allow a good spatial homogenization thereof before entering the expansion turbine.
Referring now to FIGS. 3A to 3C which illustrate an exemplary embodiment of a flame stabilizer.
This stabilizer comprises a perforated diffuser in the form of a flat circular soleplate 88 designed to be housed in the orifice 84 of the diffusion partition 66 and comprising a multiplicity of axial holes 90 regularly distributed circumferentially on the sole and a central axial hole 91. This sole continues in an axial direction and opposite the wall by axial arms 92, here three arms arranged at 120 ° each other, and carrying at their ends a mixing tube 94 of limited axial extent to arrive at the beginning of the primary zone ZP and of outside diameter less than the inside diameter of the flame tube 64.
A free axial passage 96 is thus created between the outer periphery of the mixing tube and the inner periphery of the flame tube (see FIG. 2) as well as at least one radial recirculation passage 98, here three, between the sole and the tube. mixer and arms.
In operation, the fuel, here in liquid form, is injected by the injector 76 in the direction of the perforated soleplate 88 to pass through the central hole 91. The hot compressed air coming from the inlet 42 enters the space 72 between the partitions, is then deflected by the deflecting wall 78 to pass through the holes 90 of the sole and is directed into the mixing tube 94 in which takes place the evaporation of the liquid fuel, then the combustion.
This stabilizer thus makes it possible to facilitate the vaporization of the fuel by bringing part of the burned gases from the primary zone ZP, which are inert and hot, to the jet of fuel coming from the injector through the recirculation passages 98 situated between the sole 88 and the mixing tube 94 (arrows in broken lines in FIG. 2). Improved fuel vaporization combined with a supply of inert gases in the reaction zone thus makes it possible to obtain low emissions of polluting species (NOx, HC, CO and PM).
Of course, the mixing tube must be placed at a distance from the soleplate so that a portion of the burnt gases from the primary zone ZP can be directed towards the fuel jet through the space between the soleplate and the mixing tube.
It can therefore be expected that the mixing tube is connected by radial arms to the flame tube instead of being connected to the soleplate.
In the example of Figure 2, the air from the inlet 42 is against the current with the burnt gases of the combustion chamber, but it can be envisaged that this air is co-current with these burnt gases.
It may also be envisaged to place a valve means, such as a valve (not shown) on the air intake 42 to allow control of the amount of air in the primary zone and in the dilution zone.
FIG. 4 shows a variant of the injector as illustrated for the burner of FIG. 2.
As previously mentioned, the injector may be a multi-fuel gas-liquid injector.
Indeed, for applications whose choice of fuel depends on its nature (gas or liquid), its availability, or its cost, the burner injector could be adapted.
For this the injector comprises a body 100 and an injection head 102 with an injection nozzle 104 for a fuel and another injection nozzle 106 for another fuel.
The body is composed of two concentric tubes 108, 110 with a central portion 108 provided with a passage 112 for injecting a fuel, for example in liquid form, through the injection nozzles 104 and with a peripheral passage 114 between the two tubes for injecting a fuel of another kind (gas) through nozzles 106.
Of course, this injector is associated with a fuel injection circuit with two reservoirs and the various control and / or control devices for performing the injection of one or the other fuel.

权利要求:
Claims (8)
[1" id="c-fr-0001]
1) combustion chamber (18) of a turbine, including a thermodynamic cycle turbine with recuperator, for the production of energy, in particular electrical energy, comprising a housing (56) housing a flame tube (64) with a perforated diffuser for the passage of hot compressed air, a primary zone (ZP), which receives a portion of the flow of hot compressed air and in which combustion occurs, and a dilution zone (ZD ) where the mixture of the burnt gases from the primary zone and the remaining portion of the hot compressed air flow takes place, said chamber further comprising means (76) for injecting at least one fuel, characterized in that the flame tube (64) carries a flame stabilizer (82) comprising the perforated diffuser (88), at least one recirculation passage (98) of the combustion gas and a mixing tube (94).
[0002]
2) Combustion chamber according to claim 1, characterized in that the mixing tube (94) of the perforated diffuser is carried by arms (92) connected to the perforated diffuser (88) being away from the perforated diffuser.
[0003]
3) Combustion chamber according to claim 1, characterized in that the mixing tube (94) of the perforated diffuser is carried by arms (92) connected to the flame tube (64) being away from the perforated diffuser.
[0004]
4) Combustion chamber according to one of claims 1 to 3, characterized in that the recirculation passage (98) is formed between the perforated diffuser (88) and the mixing tube (94).
[0005]
5) Combustion chamber according to one of the preceding claims, characterized in that the housing (56) comprises a baffle wall (78) for directing the hot compressed air to the flame tube.
[0006]
6) Combustion chamber according to claim 5, characterized in that the deflecting wall (78) comprises a semi-toroid wall with a concavity directed towards the flame tube.
[0007]
7) Combustion chamber according to claim 1, characterized in that it comprises a multi-fuel injection means.
[0008]
8) Turbine, in particular a thermodynamic cycle turbine with recuperator, for the production of energy, in particular electrical energy, comprising at least one compression stage (12) with at least one gas compressor (14), a heat exchanger (16), a combustion chamber (18) supplied with fuel by at least one reservoir (20), at least one expansion stage (22) with at least one expansion turbine (24) connected by a shaft (26) compressor, and energy generating means (28), characterized in that it comprises a combustion chamber (18) according to one of the preceding claims.

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同族专利:

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US10948190B2|2021-03-16|

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CN108027144A|2018-05-11|

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法律状态:
2016-09-22| PLFP| Fee payment|Year of fee payment: 2 |

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2017-03-31| PLSC| Publication of the preliminary search report|Effective date: 20170331 |

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2017-09-14| PLFP| Fee payment|Year of fee payment: 3 |

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2018-09-17| PLFP| Fee payment|Year of fee payment: 4 |

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2019-09-25| PLFP| Fee payment|Year of fee payment: 5 |

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2020-09-28| PLFP| Fee payment|Year of fee payment: 6 |

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2021-09-27| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1559314A|FR3041742B1|2015-09-30|2015-09-30|COMBUSTION CHAMBER FOR A TURBINE, IN PARTICULAR A THERMODYNAMIC CYCLE TURBINE WITH RECUPERATOR, FOR THE PRODUCTION OF ENERGY, ESPECIALLY ELECTRICAL ENERGY.|FR1559314A| FR3041742B1|2015-09-30|2015-09-30|COMBUSTION CHAMBER FOR A TURBINE, IN PARTICULAR A THERMODYNAMIC CYCLE TURBINE WITH RECUPERATOR, FOR THE PRODUCTION OF ENERGY, ESPECIALLY ELECTRICAL ENERGY.|

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US15/762,679| US10948190B2|2015-09-30|2016-09-13|Combustion chamber of a turbine, in particular a thermodynamic cycle turbine with recuperator, for producing energy, in particular electrical energy|

---

EP16770706.6A| EP3356737A1|2015-09-30|2016-09-13|Combustion chamber of a turbine, in particular a thermodynamic cycle turbine with recuperator, for producing energy, in particular electrical energy|

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CN201680055581.6A| CN108027144A|2015-09-30|2016-09-13|The combustion chamber of turbine, especially with thermodynamic cycle turbine recuperative, for producing electricl energy|

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PCT/EP2016/071533| WO2017055074A1|2015-09-30|2016-09-13|Combustion chamber of a turbine, in particular a thermodynamic cycle turbine with recuperator, for producing energy, in particular electrical energy|