DE3526343A1 - Axial flow gas turbine - Google Patents

Abstract

The axial flow gas turbine has a device 12 for feeding a scrubbing liquid to the former, which contains an intermediate cover 13 with a duct 14, which is fitted on the inlet into a contraction nozzle 3, and a nozzle 15. The cross-sectional area and the length of the duct 14 are sufficiently large for coagulation of the dust particles with the droplets of scrubbing liquid in the moving gas flow. The nozzle 15 is situated in front of the intermediate cover 13 at a distance L from this: <IMAGE> in which: L = distance between the nozzle and the intermediate cover; d = diameter of the intermediate cover duct, measured from the outer edges of this; k = empirical coefficient equal to 0.2 - 0.7; alpha = nozzle atomisation angle The device 12 keeps the blading 7 free of dust deposits soiling these. <IMAGE>

Description

The invention relates to turbine construction and relates in particular to an axial gas turbine.

The axial gas turbine made in accordance with the present invention can be used in metallurgy to recover energy of the gas leaving the furnace is most effectively used will.

The axial gas turbine according to the invention can also in in the chemical, pharmaceutical industry, in the energy industry as well as in other branches of industry used to the printing energy of the dust-laden Gases, through the deposits on the surfaces of individual Axial gas turbine elements form, recycle can.

An axial gas turbine is known (see for example Artemov G.A., Boikov V.P., Gilmutdinov A.G. "Marine gas turbine plants", Leningrad, publishing house "Sudostrojenÿe", 1978, P. 248, Fig. 6.3, pp. 142-143), the one nozzle, one blading and contains a diffuser, which in turn are arranged in the gas flow direction and in one axis lie. The nozzle serves to contract the gas flow.

The blading of the known axial gas turbine is for Transformation of the gas energy into mechanical energy is determined.

The known axial gas turbine also contains a device for supplying a washing liquid for blading. The device for supplying the washing liquid provides a ring manifold with six attached to it Nozzles.

The ring manifold stands with the water liquid source in connection and lies in the housing along the axis the axial gas turbine before blading.

The device for supplying the washing liquid is used for cleaning the blades of the axial gas turbine from dust deposits (in the turbine mentioned - from salt deposits).

In the known turbine, however, it becomes uniform Distribution of drops of washing liquid at the entrance to the Blading not achieved. This is due to the fact that  the washing liquid is supplied by means of six nozzles, whose atomizing jets to exclude those from Wash liquid drop stream areas not covered each other overlap. As a result of the above-mentioned overlap of the atomizing jets however, zones with increased concentration arise the washing liquid drop.

The uneven distribution of the washing liquid drops, or more precisely, the increased concentration drops of washing liquid in the zones of the atomizing beam overlap can increase erosion wear the blading of the axial gas turbine lead to the lifespan the blading is considerably shortened.

In addition, because of this erosion wear the blading reduced the amount of washing liquid consumed be, which in turn becomes insufficient effective cleaning of the blading and to reduce performance the axial gas turbine leads.

In addition, in the known axial gas turbine Gas flow only within a short section of the contraction nozzle swirled. The dust particles don't have time get rid of their absorbed gas envelope which is a coagulation which prevents dust particles with the washing liquid drops, and still retain their adhesive properties, i.e. H., they are still capable of working on the surfaces of individual axial gas turbine elements to remain liable.

The present invention is based on the object to create an axial gas turbine in which the facility such a constructive to supply the washing liquid Execution that reduces erosion wear the blading guaranteed.

This object is achieved with the aid of an axial gas turbine in which a contraction nozzle and blading are arranged in succession in the gas flow direction and a device for supplying a washing liquid to the turbine is present and in which, according to the invention, the device for supplying the washing liquid attaches one at the entry into the contraction nozzle Intermediate cover with at least one channel which is sufficiently large in cross-sectional area and length to coagulate the dust particles with the wash liquid drops in the gas stream, and has a nozzle which is arranged along the axis of the axial gas turbine in front of the intermediate cover at a distance from the same: where it means:
L - distance between the nozzle and the intermediate cover;
D - diameter of the intermediate cover channel, measured on the outer edges thereof;
k - empirical coefficient, 0.2-0.7 equal;
α - nozzle atomization angle.

Execution of the device for supplying the washing liquid with a nozzle that runs along the axis of the axial gas turbine is arranged, closes zones of increased concentration drops of washing liquid, which is an intense Avoid erosion wear of the blading allowed.

Eliminating zones of increased concentration the drops of washing liquid, in which intensive erosion wear blading is permitted the amount of washing liquid used for rinsing enlarge, which improves the cleaning effectiveness of the blading from the resulting dust deposits is increased.

The one in the device for supplying the washing liquid provided, attached at the entrance to the contraction nozzle Intermediate cover permitted with at least one channel it, the adhesiveness of the particles, i.e. that is, you Stick to the surface of individual elements of the axial gas turbine thanks to the coagulation of the dust particles with the Reduce washer fluid drops.

The increase in the speed of the washing liquid drops raised in the intermediate cover with at least one channel also the ability of the drops to remove the dust deposits on the blades of the axial gas turbine.  

The arrangement of the nozzle in front of the intermediate cover at a distance L from it produces an effect, the explanation of which is as follows.

The washing liquid drops have at the outlet from the Nozzle a radial and an axial speed components. The radial speed component increases with the Locomotion of the drops in the gas flow thanks to the braking of the Wash liquid drops in the gas stream because the gas stream has no radial speed component. The axial velocity component of the drop movement differs in the general case of the axial gas flow velocity Likewise.

Therefore the direction of movement of the drops changes while moving in the stream.

The arrangement of the nozzle in front of the intermediate cover at a distance L from the same makes it possible to ensure movement paths of drops of washing liquid which, as the experiments have shown, cut the intermediate cover predominantly within a section of the intermediate cover surface which is delimited by the outer edge of the channel. As a result, the further droplet movement after the intermediate cover in the contraction nozzle ensures a uniform distribution of the washing liquid droplets as they enter the blading.

At k values of 0.2, the washing liquid drops are deposited on the walls, which can lead to erosion wear on the blades. At k values of 0.7, the peripheral zone of the blading is not covered by the wash liquid drop stream.

A swirl nozzle is expediently used as the nozzle.

The use of a swirl nozzle allows an atomizing jet to produce a ring in cross section represents. Since the entrance to the blading is usually ring-shaped is formed, then reaches such an atomizing jet the entire washing liquid in the blading, without depositing on the inner wall of the contraction nozzle.  

This ensures that according to the present invention Executed axial gas turbine thanks to the cleaning of the blades from the dust deposits caused by that in the gas stream contained dust have been formed, an effective Utilization of the energy of the gas flow supplied to the turbine.

The axial gas turbine according to the invention is simple in that Operation, reliable in operation and has a long service life.

Below is a description of an example Implementation of the present invention with reference to FIG the accompanying drawing cited, in which the invention Axial gas turbine shown schematically in longitudinal section is.

The axial gas turbine designed according to the present invention has a housing 1 , to the (not designated) inlet part of which a gas line 2 is connected, which is intended for supplying a gas flow, in the present case the flow of the gas leaving a blast furnace (not shown).

The axial gas turbine has a contraction nozzle 3 , which is arranged along an axis 4 of the axial gas turbine. The outer surface 3a of Kontraktionsdüse 3 is formed by the housing 1 of the turbine, in other cases, this may also be a tapered shot. The inner surface of the contraction nozzle 3 is formed by a conical section 5 , it lies coaxially with the axial gas turbine and is designated by the same reference number 5 . The shaft 6 of the axial gas turbine lies in one axis with the contraction nozzle 3 and is kinematically connected to a power generator (not shown).

Blading 7 of the axial gas turbine is arranged behind the contraction nozzle in the gas flow direction. The blades 7 contain fixed guide vanes 8 , which are attached at one end to the section 5 , but with the other ends to the housing 1 , and rotor blades 9 , which are attached to the shaft 6 .

Further in the gas flow direction behind the blading 7 , a diffuser 10 is arranged along the axis 4 , the outer surface of which is formed by the housing 1 , in other cases this can also be a conical weft. The inner surface of the diffuser 10 is formed by a conical weft 11 , which is also arranged along the axis 4 .

The axial gas turbine according to the invention has a device 12 for supplying a washing liquid to the same. This device 12 is intended to keep the blades 7 free of the dust deposits which form on the surfaces of the rotor blades 9 and on further elements of the axial gas turbine.

The device 12 for supplying the washing liquid contains an intermediate cover 13 , in the present case with twelve channels 14 , which are evenly distributed on the circumference and are symmetrical relative to the axis 4 .

In other embodiments of the present invention, the intermediate cover has a channel, for example an annular channel with the center lying along the axis 4 .

The intermediate cover 13 is shown for the sake of greater clarity than above the housing 1 .

The intermediate cover 13 serves to swirl the gas flow and as a result for the intensive coagulation of the dust particles with the washing liquid drops.

The channels 14 are designed in the intermediate cover 13 so that their outer edges, ie the edges furthest away from the axis 4 are at the level of the outer surface of the diffuser 10 , while their inner edges, ie the edges closest to the axis 4 , lie at the level of the inner surface of the diffuser 10 . The ribs (not shown) of the intermediate cover 13 , which are formed between the channels 14 , have gentle curves, which ensure a continuous (uniform) entry and exit of the gas flow in the channels 14 .

The total cross-sectional area of the channels 14 is selected so that the gas flow velocity in the channels 14 increases to a value of approximately 80 m / sec. In further embodiments of the present invention, other gas flow rate values are also conceivable.

The increase in gas flow rate to one A value of approximately 80 m / sec ensures intensive swirling of the gas flow and therefore also destruction the gas envelope absorbed around each dust particle, the stands in the way of coagulation, and intensive coagulation the dust particles with the washing liquid drops.

The length of the channel 14 is 600 mm. In other embodiments of the present invention, a different channel length is also conceivable. The channel length of 600 mm at the gas flow speed of about 80 m / sec ensures such a dwell time of the dust particles and washing liquid drops in each channel 14 that it is sufficient to coagulate them with one another. The length of the channels 14 - 600 mm - in view of the fact that the selected generated in the channels 14 of the swirling gas flow is maintained even after the exit from the channels fourteenth

In other embodiments of the present invention, a plurality of intermediate covers are used, one of which is arranged in a fixed manner, but the other is arranged to be movable and rotatable relative to the axis 4 . Thanks to the rotation of the movable intermediate cover, the channels are partially or completely closed.

The channels can be shut off to regulate the throughput the axial gas turbine, to change its operating state and used to shut down the turbine will.

The device 12 has a nozzle 15 which is arranged along the axis 4 of the axial gas turbine in front of the intermediate cover 13 at a distance L. The distance L is understood to mean the distance from the outlet cross section of the nozzle 15 to the front surface of the intermediate cover 13 in the gas flow direction.

The distance where it means:
L - distance between the nozzle 15 and the intermediate cover 13 , in the present case L = 3500 mm;
D - diameter on the outer edges of the channels 14 of the intermediate cover 13 , in the present case D = = 1300 mm;
k - empirical coefficient, 0.2-0.7 equal, in the present case k = 0.4;
α - atomizing jet angle of the nozzle in the present case α = 50 °.

The arrangement of the nozzle 15 at a distance L from the intermediate cover 13 makes it possible to ensure the atomization of the washing liquid in the form of a jet, in which the jet diameter on the front surface of the intermediate cover 13 , as the experiments have shown, the diameter on the outer edges of the channels 14 of the intermediate cover 13 is practically the same relative to the axis 4 .

This arrangement of the nozzle 15 with respect to the intermediate cover 13 allows deposition of the washing liquid drops on the walls of the housing 1 of the axial gas turbine, and further ensures a uniform washing liquid drop concentration in the channels 14 of the intermediate cover 13 over the entire area of each cross section Channels 14 .

A vortex nozzle of any known type is used as the nozzle 15 . When using a swirl nozzle, an atomizing jet is formed, the cross-sections of which lie transversely to the axis 4 , making it possible to capture the channels 14 of the intermediate cover 13 from the atomizing jet in such a way that the area of the intermediate cover 13 outside the outer edges of the channels 14 and the area of the same with the diameter measured by the inner edges of the channels 14 is as good as outside the atomizing jet.

The means 12 for supplying the washing liquid includes a washing liquid inlet main line 16, which is of a known type, which is indicated in the drawing by a thin double line and connected to a washing liquid source 17 a container designated with the same reference numeral 17th

In the lid 18 of the container 17 , a tube 19 of a known type is installed, which connects the cavity above the washing liquid level in the container 17 with the atmosphere. A pump 20 with an electric drive (not shown) is arranged in the main line 16 . The pump 20 and the electric drive have any known appropriate design.

In the main line 16 in the vicinity of their connection is located at the nozzle 15, a device 21 of any known type for measuring and monitoring of the washing liquid pressure in the main line sixteenth

In the direction of movement of the washing liquid flow, which flows from the washing liquid source to the nozzle 15 , a T-piece with three slides 22 , 22, 23 is arranged behind the pump 20 , two of which are electrically driven slides 22 of any known, suitable type for opening and opening Shutting off the main line 16 are determined. The third electrically driven slider 23, also of any known type, is attached to a pipe 24 which connects the section of the main line 16 enclosed between the slides 22 to the atmosphere. The slider 23 serves to open and shut off the tube 24 .

There is also an overflow pipe 25 with a manually operated valve 26 of any known, appropriate type. The overflow pipe 25 connects the section of the main line 16 between the slide valve 22 and the pump 20 to the washing liquid source 17 .

The overflow pipe 25 is intended to regulate the washing liquid pressure in the main line 16 .

In the washing liquid flow direction, a check valve 27 of any known, appropriate type is attached behind the slides 22 towards the nozzle 15 . The check valve 27 is intended to shut off the main line 16 when the washing liquid pressure drops therein below the pressure value of the gas flow in the housing 1 of the axial gas turbine.

The device 12 for supplying the washing liquid has a control unit 28 which is connected via electrical circuits to the electrically driven slides 22, 23 , the pump 20 , the device 21 . There is also a control unit 29 of the axial gas turbine, which is also connected to the control unit 28 via an electrical circuit (not designated).

The control units 28, 29 have any suitable design and are intended for controlling the slide 22, 23 , the pump 20 , the device 21 connected to them by means of electrical circuits, and for controlling the axial gas turbine.

The electrical circuits are in the drawing indicated by a thin line.

The slide 22, 23 , the check valve 27 , the control unit 28 prevent the toxic blast furnace gas from entering the operating zone of the axial gas turbine.

The axial gas turbine has a condensate collection container 30 of any known construction, which is intended for collecting and removing the condenser formed from the washing liquid.

The axial gas turbine made in accordance with the present invention works as follows.

During the operation of the axial gas turbine, the gases leaving the blast furnace enter the housing 1 along the axis 4 . The gas flow flows through the channels 14 of the intermediate cover 13 , in which the gas flow speed increases. After the intermediate cover 13 , the gas flow passes into the contraction nozzle 3 and then into the blading 7 of the axial gas turbine.

When the gas flow interacts with the guide vanes 8 and the rotor blades 9 , the electricity energy is converted into the mechanical energy of the rotating shaft 6 . For its part, the mechanical rotational energy of shaft 6 is converted into electrical energy in a power generator.

The device 12 for supplying the washing liquid is switched on by the operator by actuating a pushbutton (not shown) in the control unit 28 .

In other embodiments, the device 12 for supplying the washing liquid can be switched on at a command that comes from the control unit 29 of the axial gas turbine. The command to switch on the device 12 only comes through when the axial gas turbine is in the operating state. Information about the presence of the operating state of the axial gas turbine reaches control unit 28 from unit 29 via the electrical circuit.

When the device 12 for supplying the washing liquid is switched on, the operations take place in such a sequence.

The pump 20 is automatically switched on, the slide 23 is closed and the slide 23 is opened upon a command coming from the control unit 28 . The washing liquid arrives at the nozzle 15 , in which the washing liquid is atomized. Because a vortex is applied 15 in the axial flow, which is located at a distance L from the intermediate cover 13, the trajectories of the washing liquid drops cut the intermediate cover 13 substantially within a surface portion of the diameter to the outer edges of the channels 14 and the diameter at the lower Edges of the channels 14 is limited.

These trajectories of the washing liquid drops practically preclude them from being deposited on the walls of the housing 1 of the axial gas turbine and within a surface part of the intermediate cover 13 , which is limited by the diameter of the position of the inner edges of the channels 14 . At the same time, zones with a reduced concentration of the washing liquid drops in the channels 14 are not present.

In the channels 14 , the gas flow speed increases to a value of approximately 80 m / sec, ie there is an intensive swirling of the gas flow. As a result of the swirling, the dust particles contained in the gas stream lose their absorbed gas envelope, which prevents the dust particles from coagulating with the drops of washing liquid.

As a result, there is intensive coagulation of the dust particles with the washing liquid drops. Here, the dust particles enclosed in a drop of washing liquid lose their adhesive properties to a significant extent, ie their ability to adhere to the surface of the guide vanes 8 and the rotor blades 9 is lost.

Overall, the drop speed when entering the contraction nozzle 3 is higher than when entering the intermediate cover 13 . The increase in the drop speed in and of itself increases its ability to destroy the dust deposits on the surfaces of individual elements of the blading 7 .

After passing through the contraction nozzle 3 , the washing liquid drops uniformly distributed in the gas stream, the dust particles, of which a considerable proportion, as the experiments carried out have shown, coagulated with the washing liquid drops, reach the blading 7 .

The even distribution of the washing liquid drops in the gas stream before blading, the coagulation of the dust particles with the washing liquid drops and the thereby conditional loss of their adhesiveness, the guarantee washer fluid droplet velocities close to the gas flow velocity, what the ability of Drops of washing liquid, the dust deposits in the axial gas turbine to destroy, increases by eliminating causing erosion wear on the blading elements Zones with increased concentration of washing liquid drops Increase made possible at the entrance to the blading the amount of washing liquid - all this allows the Dust deposits on the blading elements, in particular on the fixed guide vane on which the formation of Dust deposits occur most intensely, effectively preventing them.  

The condensate formed in the axial gas turbine is collected in the condensate collection container 30 , from where it is discharged in any known manner.

The washing liquid supply is switched off automatically when the operating state of the axial gas turbine stops. Information about the cessation of the operating state of the axial gas turbine passes from the unit 29 into the unit 28 . Upon a command from the unit 28 , which is fed to the spools 22, 23 and the pump 20 , it operates in the reverse order to that described above.

The supply of the washing liquid for cleaning the Blading from the dust deposits can not only be continuous, as described above is, but also periodically. The need for one periodic washing liquid supply is due to properties of dust deposits.

The test samples made according to the present invention of the axial gas turbine have been successfully tested. The trials proved their reliable work during the Operation.

The axial gas turbine according to the invention has high technical economic parameters, is simple and reliable in Business.

Claims (2)

1. axial gas turbine, in which a contraction nozzle ( 3 ) and a blading ( 7 ) are arranged in succession in the gas flow direction and a device ( 12 ) for supplying a washing liquid to the turbine is present, characterized in that the device ( 12 ) for supply the washer fluid has an intermediate cover ( 13 ) attached to the entry into the contraction nozzle ( 3 ) with at least one channel, the cross-sectional area and length of which is sufficiently large for the coagulation of dust particles with the washer fluid droplets in the gas stream, and has a nozzle ( 15 ) which is longitudinal an axis ( 4 ) of the axial gas turbine is arranged in front of the intermediate cover ( 13 ) at a distance from it: where it means:
L - distance between the nozzle and the intermediate cover;
D - intermediate cover duct diameter on the outer edges of the intermediate cover duct;
k - empirical coefficient, 0.2-0.7 equal;
α - nozzle atomization angle. 2. Axial gas turbine according to claim 1, characterized in that a swirl nozzle is used as the nozzle ( 15 ).