RU2212005C2 - Gas turbine combustion chamber - Google Patents

Abstract

FIELD: gas turbines. SUBSTANCE: proposed combustion chamber of gas chamber includes burner liners connected with circular gas receiver which is fastened with outer and inner casings. Each burner liner has front wall at outlet in direction lateral relative to flow; this wall is secured to wall of burner liner and is connected with gas receiver. Located above front wall in way of flow are branch pipes and prechamber with blades swirlers. Wall of burner liner is provided with several slots which are inclined to longitudinal axis of prechamber; lower edges of these slots are located between branch pipes in one meridian plane in way of flow. Upper edges of said slots are located above branch pipes in way of flow in other meridian plane. Angle of inclination of projection of longitudinal surfaces of inclined slots to longitudinal axis of prechamber ranges from 30 to 75 deg. Longitudinal surfaces of inclined slots are located across angles of swirler blades relative to longitudinal axis of prechamber and/or across direction of flow of combustion products twisted by bladed swirlers. EFFECT: reduction of toxicity of turbine exhaust gases. 2 cl, 3 dwg

Description

 The invention relates to combustion chambers of gas turbines, mainly ground-based power plants operating on natural gas with low toxicity of exhaust gases.

 A tubular-annular combustion chamber of a gas turbine power plant is known, comprising flame tubes connected to a gas collector bonded to external and internal bodies, the gas collector cavity is formed by its own annular walls, each of the flame tubes containing a frontal wall fastened to the wall at the outlet in the transverse flow direction the flame tube and connected to the gas collector, in the flame tube in the plane of the frontal wall facing the flow, channels are made along the perimeter of the flame tube wall [1].

 A disadvantage of the known design is the incomplete use of the possibilities of organizing the kinetic combustion of a re-enriched air-fuel mixture with the formation of circulation zones and with partial combustion of fuel with a significant excess of air, as well as the low reliability and resource of flame tubes when using natural gas.

A disadvantage of the known combustion chamber is also the low intensity of mixing fuel with air, which leads to the formation of long flares and a long stay of combustion products in the zone of maximum local temperatures due to the absence of flame stabilization elements in the flame tube and, as a consequence, to increased toxicity of turbine exhaust gases. In the exhaust gases of gas turbine power plants, NO _x nitrogen oxides account for up to 95% of the total level of harmful substances and are the main most toxic substance.

 Closest to the claimed one is a tubular-annular combustion chamber of a gas turbine containing flame tubes connected to a gas collector fastened to the outer and inner bodies, the gas collector cavity is formed by its own annular walls, while each of the flame tubes contains a frontal outlet in the transverse flow direction a wall bonded to the wall of the flame tube and connected to the gas collector, in the flame tube upstream of the frontal wall there are a number of nozzles from which the wall of the flame tube is continuous Single, wherein each of the nozzles has a triangular cross-sectional shape, one vertex of which is directed against the flow, and facing the downstream lateral surfaces of the pipes are made rows of holes and crevices [2].

A disadvantage of the known design adopted as a prototype is the incomplete use of the capabilities of the fuel combustion process and the high toxicity of NO _x , CO, and HC emissions in the exhaust gases during the operation of a gas turbine, mainly during two-stage combustion in a rich-poor air-fuel mixture. In the primary zone of the known flame tube, a rich air-fuel mixture is burned, a poor air-fuel mixture is burned in the secondary zone, and the formation of a “zone of rapid dilution” of the combustion products of the rich mixture is carried out between the primary and secondary zones, i.e. in the area of the nozzles 10, which serve as a mixer and flame stabilizer. The triangular cross-sectional shape of the nozzles 10 increases the degree of blockage of the flow, increases the pressure loss, reduces the effect of the air curtain on the rear wall of the nozzles, reduces the efficiency of mixing combustion products at high temperatures, and does not exclude the formation of local zones in the nozzle zone close to the stoichiometric composition of air-fuel mixtures , which contributes to higher temperatures, and also increases the residence time of the combustion products of the primary rich zone in the "fast bavleniya ", ie in the zone of maximum local temperatures.

 The technical problem to which the claimed invention is directed is to reduce the toxicity of turbine exhaust gases during two-stage combustion in a “rich-poor” air-fuel mixture by intensifying mixing processes in the “quick dilution zone”, increasing the completeness of combustion of the combustion products of the primary zone and prevent in the "zone of rapid dilution" of high-temperature combustion by supplying part of the secondary air into the "zone of rapid dilution" across the direction of the swirling blades By the flow swirls of the combustion products, and the nozzles are made with an aerodynamic shape and with the effect of lateral stabilization of combustion.

The essence of the technical solution lies in the fact that in the combustion chamber of a gas turbine including flame tubes connected to an annular gas collector fastened to the outer and inner bodies, each of the flame tubes contains a frontal wall fastened to the wall of the flame tube at the outlet in the transverse flow direction and connected to the gas collector, upstream of the frontal wall there are a number of nozzles, as well as a frontal device with scapular swirls, according to the invention, the flame tube wall is made with a number of inclined x to the longitudinal axis of the front device of the slots, the downstream edges of which are located between the nozzles in one meridian plane, and the upper edges of the slots are located upstream of the nozzles in the other meridian plane, while the angle of inclination of the projection of the longitudinal surfaces of the inclined slots to the longitudinal axis of the front device is 30.. . 75 ^o , and the longitudinal surfaces of the inclined slots are located across the angles of installation of the blades of the swirls relative to the longitudinal axis of the front device and (or) across the direction of the flow of combustion products swirled by the blade swirls. The number of inclined slots is equal to at least the number of nozzles, and the total passage area of the inclined slots is 0.8 ... 1.2 of the total passage area of the nozzles.

The execution of the wall of the flame tube with a number of slots inclined towards the longitudinal axis of the frontal device, the downstream edges of the slots located between the nozzles in one meridian plane, the upper edges of the slits located upstream of the nozzles in another meridian plane, the angle of the projection of the longitudinal surfaces of the inclined slots to the longitudinal axis of the front device, comprising 30. ..75 ^o , and the longitudinal surfaces of the inclined slots - located across the angles of installation of the blades of swirlers relative to the longitudinal the axis of the front device and (or) across the direction of the flow of combustion products swirled by the blade swirls, together intensifies the mixing process in the “quick dilution zone” (in the nozzle area) by supplying part of the secondary air through inclined slots across the direction of the rich primary flow of combustion products swirl by the blade swirls zone, as well as due to the implementation of nozzles with aerodynamically streamlined shape, with reduced resistance and with the effect of lateral stabilization of combustion. At the same time, nozzles and inclined slots act as mechanical turbulators of the “quick dilution zone”, and the effect of stabilization of combustion in the “fast dilution zone” is achieved by aerodynamic turbulization and mixing of at least three streams: the flow of products of combustion of the primary rich zone swirled by the blade swirlers, the stream of secondary air blown by the pressure drop across the walls of the flame tubes through the inclined slots, and a stream of secondary air blown by the pressure drop across the walls of the flame tubes through connections. This increases the effect of turbulization and mixing, the resulting flow behind the side of each of the nozzles and in the wake downstream of the nozzles becomes three-dimensional, which greatly increases the mixing efficiency of gas components, reducing the residence time of the combustion products at maximum local temperatures. With such execution of the flame tubes and the interaction of the mixing and combustion processes, the number of local zones (stratified flows) of poor and close to stoichiometric mixtures with an increased local temperature in the combustion zone decreases many times, and the level of nitrogen oxides NO _x and the increased toxicity of combustion products. At the same time, the air cooling the pipes through its own slots on the leading edges does not participate in the combustion process near its walls.

 Performing the number of inclined slots equal to at least the number of nozzles, and the total passage area of inclined slots, amounting to 0.8 ... 1.2 - the total area of the passage section of the nozzles allows the most efficient use of the cooling air coolant to increase the fuel economy of a gas turbine.

 The set of essential features of the inventive combustion chamber as a whole allows to reduce the toxicity of exhaust gases with more effective protection of the pipes and walls of the flame tubes from burnout and increase its reliability and resource.

 In FIG. 1 shows the upper part of a longitudinal section of the combustion chamber along the longitudinal axis of one of the flame tubes.

 Figure 2 - element I in figure 1.

 Figure 3 is a view A in figure 1.

The combustion chamber of a gas turbine includes flame tubes 1 connected to an annular gas collector 2, fastened to the outer casing 3 and the inner case 4. Each of the flame tubes 1 contains at the outlet 5 in the transverse flow P direction a frontal wall 6 of thickness t bonded to the flame wall 7 pipe 1 by a weld seam F and connected to the gas collector 2 along the bands D1 and D2. Upstream P from the frontal wall 6 there are a number of nozzles 8, as well as a frontal device 9 with scapular swirlers 10 (see figure 1). The wall 7 of the flame tube 1 is made with a number of slots 11 inclined towards the longitudinal axis O of the frontal device O. 11. The downstream edges of the 12 slots 11 are located upstream of P from the nozzles 8 in another meridian plane M, and the angle of inclination Y of the projection of the longitudinal surfaces T of the inclined slots 11 to the longitudinal axis O of the front device 9 is 30 ... 75 ^o . The longitudinal surfaces T of the inclined slots 11 are located across the angles S (not shown) of the installation of the blades of the swirlers 10 relative to the longitudinal axis O of the front device 9 and (or) across the direction Z of the flow of combustion products K swirled by the blade swirls 10 (see Figs. 1, 2). The number of inclined slots 11 is equal to at least the number of nozzles 8, and the total passage area of the inclined slots 11 is 0.8 ... 1.2 of the total passage area of the nozzles 8 (see Fig. 2, 3). In addition, figure 1 shows the connection of the flame tubes 1 with an annular gas collector 2, consisting of an outer annular shell 14 and an inner annular shell 15, a spark plug 16, a diffuser 17 with a sudden expansion, and also pos. 18 - injection device and the supply of compressed natural gas to the front-end device 9 and pos. 19 - the first stage of the nozzle apparatus of the turbine.

The combustion chamber operates as follows. Air in the amount of 15 ... 25% enters through the frontal device 9 with bladed swirlers 10 into the flame tubes 1. Fuel through the injection devices 18 is fed into the flame tubes 1. The air-fuel mixture formed in the flame tubes 1 when 100% fuel and 15 are mixed .. .25% of air contains an excess of fuel (natural gas) and is, in relation to the stoichiometric composition of the mixture, a “rich" air-fuel mixture. The resulting products of incomplete combustion of a “rich” air-fuel mixture enter swirling blade swirls 10 in the core of the flow Z of combustion products into the “zone of rapid dilution”. Through the slots 11 and nozzles 8, air is supplied in an amount of 50 ... 65%. This air is mixed with the products of combustion of a “rich” air-fuel mixture by flows K and Z of combustion products, creating the effect of lateral stabilization of combustion. The resulting flow behind the side walls of the nozzles 8 and in the wake downstream Z behind the nozzles 8 becomes three-dimensional, and when mixed, an air-fuel mixture is formed that contains excess air - "poor mixture", α _r = 1.8 .... 2.2 where α _r is the excess coefficient of the oxidizing agent. Moreover, in the flows of combustion products Z and K, the centers of kinetic combustion of fuel microparticles are initiated, which contributes to the avalanche activation of combustion (LAG process). This mixture burns in the annular gas collector 2. “Rich” (α _r = 0.5 ... 0.7) and “poor” (α _r = 1.8 ... 2.2) air-fuel mixtures are characterized by a low combustion temperature T _r <1950K and, accordingly, low toxicity of exhaust gases. The transition from the state with excess fuel to the state with excess air is carried out downstream of the Z and K streams from the slots 11 and nozzles 8, the combustion of products of incomplete combustion in the flame tubes 1 is completed in the annular gas collector 2 with α _r = 1.8 ... 2, 2. The air cooling the nozzles 8 through its own cooling slotted channels at the leading edges is blown away by the flows of combustion products K and Z and does not participate in the combustion process near the walls of the nozzles 8, reliably protecting them from burnout. Pipes 8 and inclined slots 11 act as mechanical turbulators of the “quick dilution zone” I and prevent the formation of stoichiometric mixtures in it, reducing emissions of nitrogen oxides NO _x , increasing the completeness of fuel combustion with reliable protection against burns and cracks in the walls of flame tubes and pipes, and increase reliability and resource of flame tubes.

Sources of information
1. FR, application 2695460, cl. F 23 R 3/28, 1994

 2. RU, patent 2138739, cl. F 23 R 3/16, 1997 - prototype.

Claims (2)

1. The combustion chamber of a gas turbine, including flame tubes, connected to an annular gas collector, bonded to the outer and inner bodies, each of the flame tubes contains a frontal wall attached to the wall of the flame tube and connected to the gas collector, upstream, in the transverse flow direction from the frontal wall there are a number of nozzles, as well as a frontal device with scapular swirlers, characterized in that the flame tube wall is made with a number of slots inclined to the longitudinal axis of the frontal device, lower e the downstream edges of which are located between the nozzles in one meridian plane, and the upper edges of the slots are located upstream of the nozzles in the other meridian plane, while the projection angle of the longitudinal surfaces of the inclined slots to the longitudinal axis of the front device is 30.. . 75 ^o , and the longitudinal surfaces of the inclined slots are located across the angles of installation of the blades of the swirls relative to the longitudinal axis of the front device and (or) across the direction of the flow of combustion products swirled by the blade swirls.  2. The combustion chamber of a gas turbine according to claim 1, characterized in that the number of inclined slots is equal to at least the number of nozzles, and the total passage area of the inclined slots is 0.8. . . 1.2 total area of the passage section of the nozzles.

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