(57) Abstract:Usage: for spraying and subsequent combustion. The inventive housing 1 has two coaxially installed bushings 2, 3, with the formation of internal and peripheral channels for supplying the atomizer and the intermediate channel for the fluid. On the collet ring rows made the slits 5, directed towards each other and offset in the circumferential direction in adjacent rows, the outer of which 6 are longitudinal axis of the slots 5 overlap with the axis of the nozzle at its output cutoff and internal 7 - in front of her weekends cut inside the housing 1. The side walls of a larger area of the slots 5 on the sleeves 2 and 3 are located in planes intersecting the axis of the nozzle at a single point located at or beyond its output slice, and the longitudinal axis of the slots 5 of the outer and inner rows 6 and 7, respectively, inclined to each other at an angle not exceeding 90 degrees. 5 Il. The invention relates to a technique of sputtering, in particular, liquids slurries, solutions, liquid fuel, suspensions) compressed air or steam. The nozzle can be used in energy fuel combustion.The analysis of the selected parocchi modern injectors is to increase the efficiency and quality of spraying, for example, by redistributing the total flow of the atomizer with the help of special devices inside the nozzle.Known injector, in which the efficiency and quality of atomization is solved by fuel and spray in independent flow paths at the entrance of the nozzle, when the output of which flows interact. The closest technical solution is a nozzle, comprising a housing, sleeve, coaxially installed with the formation of the annular fuel cracks and internal and peripheral channels for supplying the sprayer with the appropriate output nozzles in the form of an annular series of narrow slots that are offset in the circumferential direction in adjacent rows, wherein the longitudinal axis of the slots of the outer row are oriented towards the axis of the nozzle, and an internal number from the axis of the nozzle (see USSR Author's certificate N 876179, M CL F 23 D 11/12, 1977).The above-described nozzle allows you to split sprayed liquid into two separate streams, one of which is directed towards the axis of the nozzle, and the other from her. These streams provide a wide torch, in which a less pronounced effect coagulation of the droplets due more to the developed surface of contact with the environment is Oh and reduces the concentration of droplets in the stream.A disadvantage of the known nozzle is that the two independent flow atomizer have a twist in different directions around the axis of the nozzle, which leads to the collapse of the spray in the axial zone of the flow, the appearance of built-up edge on the end face of the nozzle, reducing the reliability of the injector.The problem to which the invention is directed, is to improve the efficiency and quality of spraying, the improvement of mixing, i.e., obtaining a homogeneous mixture of the liquid with air or other gaseous substance, and improving reliability through the elimination of the water drops sprayed liquid on the outer surface of the nozzle.This object is achieved in that the nozzle includes a housing and a sleeve coaxially mounted therein with the formation of internal and peripheral channels for supplying the atomizer and the intermediate channel for the fluid connected to Solovay apparatus, made in the form of an annular series of narrow slots that are offset in the circumferential direction in adjacent rows( in the outer longitudinal axis of the slots is oriented towards the axis of the nozzle, and inland from the axis of the nozzle); the longitudinal axis of the slots na area of these slots are located in the planes, intersect the axis of the nozzle at a single point located at or above its output slice.From the prototype of the claimed invention differs in that the longitudinal axis of the slots of the outer and inner rows inclined to each other at an angle not exceeding 90oand side walls of a larger area of these slots are located in planes intersecting the axis of the nozzle at a single point located at or above the output of the slicer. Each of these features is significant, and collectively solves the problem, namely, the location of the coaxial sleeves of the slots so that the longitudinal axis and at the outer and inner rows of inclined to each other at an angle not exceeding 90ohelps to reduce energy losses of the opposing jets to interact, increasing the intensity of the twist of the thread atomizer, the reduction in static pressure along the perimeter of the fuel (liquid) cracks, reduction of vortex formation in the zone of interaction of the liquid with sprayer. Execution of the slots so that the side walls with their larger area are located in planes intersecting the axis of the nozzle at a single point located at or above the output of the slicer provides after Stylites this increases that eliminates the possibility of a collapse of the spray in the axial zone of the flow, since the increased centrifugal effect of intensive gas flow along the axis of the nozzle from space, remote from the nozzle toward its center. This thread, not containing droplets of liquid washes the end of the nozzle, keeps it clean and prevents the built-up edge.In addition, the increase in the intensity of the twist of the thread and the reduction of the angle between the jets, weaken the effect of their collision, reduce static pressure along the perimeter of the fuel gap and, thereby, increase ejection. On the one hand, increases the atomization quality, and, on the other hand, enhances the effect of washing the outer surfaces of the nozzles in the vicinity of the outlet flow of gas drawn in the radial direction from the surrounding space and not containing liquid droplets. Thus the outer surfaces of the nozzle are also stored clean and the reliability of its work increases. In all of the above symptoms, we offer the nozzle efficiency and quality of spraying, improves mixing and increases reliability.In Fig. 1 shows a General Vitale made the slot; in Fig. 3 view of the spray head from the top and the direction of twist of the threads of the atomizer relative to the axis of the nozzle; Fig. 4 is the same view in a perspective view with a cut made in an enlarged scale on the outer sleeve of Fig. 5 scheme of the spray, side view.The nozzle includes a housing 1, which is coaxially aligned with a gap between them, set the outer 2 and inner 3 sleeve forming to allow the apparatus with the ring slit 4 for the fluid. On the outer 2 and inner 3 bushings nozzle of the device is made slits 5, directed towards each other at an angle (Fig. 4), not exceeding 90oand offset in the circumferential direction in adjacent rows: 6 outer longitudinal axis is oriented towards the axis of the nozzle and the inner 7 from the axis of the nozzle. The side walls of a larger area of the slits 5 are located in planes intersecting the axis of the nozzle at a single point located at or above the output of the slice (Fig. 2, 4). This embodiment and arrangement of the slits 5 contributes to the fact that each pair streckeisen slots of the outer 2 and inner 3 sleeves lying in planes that are close to parallel. In free space the rows of jets arising out of the holes 6 and 7, form scrutineering to the same side of the Central vortex flow 10. At the rear of the nozzle holes 11 and 12 for the supply of spray in the internal and peripheral channels, respectively, and a hole 13 for supplying a fluid (such as oil) in the intermediate channel. The Central part of the nozzle is closed by the cover 14.The nozzle operates as follows. The holes 11 and 12 are served under the pressure of the air or steam which enters through the peripheral and internal channels, respectively, in the slots 5 of the outer 2 and inner 3 sleeves and flows through a series of outlet openings 6 and 7, the fuel is fed through a hole 13 through the intermediate channel. The jet of steam flowing out of the outlet openings 6 and 7 are directed towards each other with an offset in a staggered manner and are close to parallel planes, which provides mutual penetration of the jets emanating from the exhaust holes 6 external number between the streams flowing from the outlet 7 of the inner row. Propagating thus the rows of jets share the sprayed fuel (liquid) into two separate streams, one of which 8 are directed towards the axis of the nozzle, and the other 9 (see Fig. 5). These threads allow to obtain a wide torch, which reduces the coagulation liquid droplets and increasing the Ooty their independent movement. The location of the slots 5 in planes intersecting the axis of the nozzle at the point Of being at or above the output of the slicer allows you to spin in one direction of the jet resulting from these holes (Fig. 3, 4). In free space the rows of jets arising out of the holes 6 and 7, form twisted to one side of the inner 8 and outer 9 streams of atomized liquid (Fig. 5).Twisting in one direction around the axis of the rows of jets flowing out of the outlet openings 6 and 7, improves ejection properties of the spray reduces the static pressure along the perimeter of the ring slit 4 for the fluid and improves the quality of its dispersion. Twisting in one direction around the axis of the nozzle threads 8 and 9 increases the centrifugal force, thus preventing the possibility of a collapse of the spray, i.e., tightening of threads to the axis of the nozzle. This provides conditions for the formation of the end surface of the nozzle Central vortex flow 10 associated with free space (Fig. 5). He intensifies the mixing of the spray with the environment due to the axial return flow of gas trailing vortex flow. Return gas stream is formed by the and or dried material). Washing in the radial direction from the center to the periphery of the end surface of the nozzle in a stream of gas containing liquid droplets, prevents built-up edge on the lid 14.The location of the longitudinal axes of the slots 5 at an angle not exceeding 90oto each other, reduces the angle between the streams flowing from the exhaust holes on both sleeves, weakening the effect of their collision. This further improves ejection properties of the spray reduces the static pressure along the perimeter of the liquid gap and, together with the spin in one side of the rows of jets flowing out of the outlet holes, creates conditions for the formation of the end surface of the nozzle Central vortex flow 10 associated with free space (Fig. 5), thereby providing a high atomization quality and efficient mixing of the spray with the environment and prevent built-up edge on the lid 14 of the nozzle. In this case, the outer surfaces of the nozzle, as well as its end, remain clean, which further increases the reliability of the injector.If there is another effect is almost complete elimination of abrasive wear. This is ramkah these films due to the viscous forces of the fluid is decelerated on the walls of the annular gap and cannot purchase high-speed, sufficient for the occurrence of abrasive wear in the presence of liquid abrasive particles, which also increases the service life.The use of the proposed nozzles can reduce the number of burners, significantly reduce the consumption of spray to stabilize the combustion, and virtually eliminate the noise accompanying the operation of pneumatic and steam atomizers, and to minimize harmful emissions into the atmosphere. Nozzle, comprising a housing and a sleeve coaxially mounted therein with the formation of internal and peripheral channels for supplying the atomizer and the intermediate channel for the fluid connected to Solovay apparatus, made in the form of an annular series of narrow slots that are offset in the circumferential direction in adjacent rows and the slits of the outer series are made with a longitudinal axis intersecting with the axis of the nozzle at its output slice, and the slits of the inner series with a longitudinal axis intersecting with the axis of the nozzle before it is output slice inside the housing, characterized in that that the longitudinal axis of the slots of the outer and inner rows inclined to each other at an angle not exceeding 90oand the side wall b is th at the level of its output slice or behind them.
SUBSTANCE: nozzle has mixing chamber whose section arranged downstream of the radial nozzles of the first sprayer is conical. The nozzles of the third sprayer are arranged over the periphery at the outlet of the conical section of the chamber. The nozzles of the third sprayer are connected with the ring row of the passages of the first sprayer. The nozzles of the third sprayer are mounted at an angle of to the vertical axis of the nozzle and under an angle of to its plane.
EFFECT: enhanced efficiency.
1 cl, 2 dwg
SUBSTANCE: burner is made of well of specified length (up to 650 mm). The fuel flowing through stabilizer of fuel supply enters the fuel supply pipe and then through fuel nozzles to the mixing chamber of the nozzle. The fuel jet impacts on the conical hollow in the working face of the deflector, thus enhancing the spraying of fuel. The compressed steam enters the ring passage defined by the fuel and steam supply pipes. The steam then enters the first (hydraulic) spraing stage of the mixing chamber through the steam nozzles drilled in the swirler radially and tangentially. The mixing chamber is interposed between the hydraulic deflector and exit section of the fuel nozzle. The steam entrains the fuel jet broken down with the deflector and then continues to break it in the second (gas) spraying stage, in the zone around the rod of the hydraulic deflector.
EFFECT: improved quality of spraying.
3 cl, 4 dwg
FIELD: mechanical engineering; gas-turbine engines.
SUBSTANCE: proposed gas-turbine engine has central stage arranged in gas duct of engine from its part arranged higher relative to direction of main gas flow to part lower in direction of main gas flow and provided with exhaust gas cone forming device in direction of main gas flow, and guide arrangement. Gas-turbine engine has group of blades, group of fuel nozzles and group of igniters. Guide arrangement is located in zone of edge of exhaust gas cone-forming device arranged higher relative to direction of main gas flow. Group of blades is located in gas duct out of the limits of central stage. Blades are provided with atomizing guides extending through blades. Fuel nozzles are installed on inner ends of corresponding atomizing guides. Each nozzle is provided with input, output and passage between input and output. Passage has part arranged to direct fuel flow to first part of passage surface located across and widening downwards in direction of flow with subsequent deflection fuel flow by first part of surface and its outlet from nozzle. Igniters are arranged in corresponding atomizing guides for igniting fuel from corresponding fuel nozzle.
EFFECT: provision of reliable lighting up in afterburner, improved recirculation of fuel in flow.
13 cl, 8 dwg
FIELD: power engineering.
SUBSTANCE: coaxial jet nozzle comprises hollow tip that connects the space of one of the fuel components with the combustion zone and bushing that embraces the tip to define a ring space and connects the space of the other fuel component with the combustion zone. The exit section of the tip is provided with the radial grooves so that the periphery of the central jet bounded by the generatrices of the beams is no more than 3s, and the beam length is 2.3-2.5s, where s is the beam thickness.
EFFECT: enhanced completeness of combustion.
1 cl, 3 dwg
FIELD: machine building.
SUBSTANCE: module of burner for gas generator consists of two-step spreader of two-component mixture flow, of two component supplying tubes running from two-step two component mixture spreader, and of face plate of burner, where there pass tubes for supply of two-component mixture. The face plate contains a cooling system designed for plate cooling. Further, the module of the gas generator burner consists of circular nozzles built in the face plate of the burner; also each circular nozzle envelops a corresponding tube supplying two-component mixture. The two-step flow spreader of two component mixture flow contains a main cavity consisting of spreaders of flow of the first step and of secondary cavities diverging from the main cavity on further ends of the spreaders of the first step. Also each secondary cavity comprises the spreaders of flow of the second step. Tubes for supply of two-component mixture run from each secondary cavity on the further ends of the spreaders of the second step flow. The face plate of the burner contains a porous metal partition with nozzles passing through it; the cooling system has a porous metal partition cooled with reagents infiltrating through the porous metal face plate. The face plate of the burner contains a back plate, a front plate and a channel of cooling medium between the back and front plates. The cooling system contains the cooling medium channel. In the cooling system cooling medium flows through this channel to cool the front plate. The front plate contains transition metal. The burner module additionally contains conic elements running through the back plate and the front plate; also each conic element is installed on the end of each tube for supply of two component mixture. Each conic element contains a circular nozzle.
EFFECT: raised efficiency of installation for gasification of carbon containing materials.
20 cl, 8 dwg
FIELD: machine building.
SUBSTANCE: pneumatic burner consists of gas and fuel supplying pipes, fuel nozzle, hollow case and flange. The fuel nozzle consists of two cylinder sections and one conic section. A circular diaphragm with profiled elliptic orifices is installed in the hollow case. The orifices are inclined relative to axis of the fuel nozzle at angle equal to angle of taper of a coaxial conic channel. The fuel nozzle can additionally contain a guiding tip with diffusion hole. The gas supplying pipe is preferably set tangentially to the hollow case. The burner can additionally have the coaxial conic channel formed with the hollow case and the guiding tip with the diffusion hole. Geometry of the coaxial conic channel is preferably made controlled.
EFFECT: reduced operational pressure fall of fuel; increased radial and circumferential uniformity of fuel distribution in spray; control of distribution of drops around diameters.
5 cl, 1 dwg
FIELD: machine building.
SUBSTANCE: atomiser of, primarily, liquid-propellant rocket engine comprises casing with fuel feed adapter. Note here that the latter is arranged inside said case at pylons while its channel is connected with fuel chamber via bores made in said pylons. In includes the sleeve arranged with ring clearance at said case to make circular gaseous oxidiser channel connected with oxidiser chamber via channels in the casing between its wall and fuel feed pylons. Adapter channel is closed at its inlet while its inner chamber communicates with ring gap between adapter and said sleeve via radial bores made at outlet. Note here that sleeve outlet has stepped expansion with its chamber connected with fuel chamber via tangential channels made in sleeve wall. In compliance with one version, sleeve outlet expansion accommodated hollow cylinder making an extension of sleeve inner channel to make ring gap with ring expansion outlet cylindrical surface. Chamber of said dap communicates via tangential bores with fuel chamber. Axial bore is made at adapter end. Stepped expansion is made at adapter outlet. Note here that bores equally spaced in circle and at angle to adapter axis are made at adapter end. Stepped expansion is made at adapter outlet. Note here that bores equally spaced in circle and at angle to adapter axis are made at adapter end located in the plane of sleeve tangential bores.
EFFECT: higher completeness combustion and better mix formation.
5 cl, 11 dwg
SUBSTANCE: fuel tube for a burner, and namely for a gas turbine burner, includes an end that has a surface for nozzles, as well as at least two fuel nozzles. The surface for the nozzles is equipped with splines between the fuel nozzles and is made in the form of an annular conical surface. The splines pass through the above surface perpendicular to the circumferential direction of the annular surface. The end is made in the form of a flattened cone. The side surface of the flattened cone forms the surface for the nozzles.
EFFECT: invention is aimed at increasing the nozzle service life.
7 cl, 3 dwg
FIELD: energy engineering.
SUBSTANCE: device comprises a shell with a shaped inlet and outlet, mounted on the frame, a pilot burner located inside the shell, a mixing head representing two toroid-shaped collectors located on the same axis, in which the pneumatic nozzles connecting them are set, at that one collector is connected to the system of feeding compressed air or steam and the other collector is connected to the hydrocarbon fluid feeding system.
EFFECT: increase in efficiency and completeness of combustion process of hydrocarbon fluid.
2 cl, 4 dwg
FIELD: fire safety.
SUBSTANCE: pneumatic nozzle comprises the fluid and the gas supply systems and the nozzle, the liquid supply system is carried out in two directions comprising the axial liquid supply through the inlet pipe and the confuser and the cylindrical nozzle, connected in series and coaxial with it, and the tangential liquid supply is carried out through the housing in the form of a cylindrical-conical sleeve, coaxial with the cylindrical nozzle, on the cylindrical part thereof the annular vortex chamber with the liquid supply pipe is fixed. Along the annular chamber edges, two rows of inlet fluid tangential channels are provided, each row comprising at least three tangential channels connecting the annular chamber with the cylindrical cavity of the housing, to which the circular plate is coaxially fixed, located perpendicularly to the axis of the annular vortex chamber and rigidly connected to the cylindrical cavity of the housing in its end section, and a slotted nozzle is attached perpendicularly to the circular plate. The slot nozzle is made combined and consisting of two mutually perpendicular rectangular parallelepipeds with throttle through openings of a rectangular cross section, connected with the housing cavity, and the divider of the two-phase flow is attached coaxially to the circular plate, to its peripheral portion, formed as a perforated conical surface surrounding the slotted nozzle with throttle through openings of a rectangular cross section connected to the housing cavity.
EFFECT: increased efficiency of the gas-drop jet formation and expanding its supply area.
2 cl, 2 dwg