CH655976A5 - COMPACT DIFFUSER FOR HIGH-POWER GAS TURBINES. - Google Patents

Description

The present invention relates to a compact diffuser for high-power gas turbines (over 10,000 kW), which allow extremely high diffusion efficiencies to be obtained with reduced axial dimensions and radial dimensions that do not exceed those admissible for current solutions which are dictated by reasons. of transport. Thanks to the remarkable diffusion efficiency that can be achieved and the consequent lower speed of the exhaust gases, a significant reduction in vibrations and the noise level is achieved in parallel, thus making it easier to manufacture the exhaust silencer with consequent lower costs and dimensions.

As known, the diffusers most frequently used in power gas turbines are derived from those studied and developed for aeronautical turbines in which a reduced radial dimension and the crossing of the diffusion duct with aerodynamic profiled double-walled nerve is imperative -mente and cooled in the cavity with fresh gas, to support the tree cushion otherwise unreachable.

Said diffusers consist of two conical coaxial walls with opening between the cones around the 7th. In fact, a diffuser of this type is of maximum efficiency when the best compromise between the friction losses on the two walls is reached which, depending on the same finish of the surfaces from the development in length, are lesser the shorter the diffuser, and the losses due to diffusion turbulence which are lesser the more gradual the diffusion, i.e. the longer the diffuser. However, it appears experimentally that the optimal compromise length, depending on the degree of finish, speed, etc., corresponds in the first approximation for diffusers with two conical walls and mainly axial development to an opening precisely between the cones of about 7 °.

On the other hand, at the outlet of the diffuser the gas still has a strong speed whose energy is lost but, being the axial exhaust and taking into account the aeronautical compromise between weight, dimensions and efficiency, this loss is accepted.

The terrestrial turbines, derived from aeronautical experiences, use similar diffusers with the only variant that at the end of the diffuser the gas is made to bend in a radial direction since the discharge in terrestrial turbines is provided for radial.

Then, in order to cause the gas to bend with less losses and with narrow radii, arrays of deflectors are often placed in the curve, consisting of cross-sectional arches in section. The gas diffusion is however considered exhausted at the end of the conical section and the deflectors serve only to reduce the pressure drop in the curve and not to diffuse.

This type of diffuser does not exploit the major alternatives offered by terrestrial accommodation with respect to aeronautics and precisely:

a) retains the support ribs of the cushion at the inlet of the diffuser where the gas has significant speeds, causing a discrete loss that becomes much higher if the turbine must work in conditions other than the design one because in this case to the losses caused by the reduction in section in the passage between the ribs must also be added the losses caused by the impact of the gas against the latter, an impact that occurs with incidences that are far from the optimal ones as far as you operate from the project point (with land turbines it is not rare the case in which it is necessary to operate at 50% of the initial project turns). In the aeronautical turbine, the nerve are indispensable for reasons of size and weight. In the terrestrial turbine, on the other hand, the cushion can also be supported from the outside provided that some mechanical problems are solved on the shaft line.

b) It does not minimize the speed of the exhaust gases at the expense of efficiency and noise level. A type of diffuser that begins to be adopted in the terrestrial field is precisely characterized by the elimination of these nerve and by the attempt to improve diffusion in the final curve. The nerve are eliminated by supporting the cushion from the outside, since the discharge is no longer axial, and the curve is made with a real curved diffuser that is much more complex than a straight diffuser but with an accurate stage and setting experimental point can lead to a discrete further recovery.

To further improve this type of diffuser, it is necessary either to increase the axial conical section so as to reach the curve with a greater diffusion ratio, but this causes an intolerable increase in the axial length of the turbine, or to interpose an intermediate wall in said section so as to double the angle of diffusion. This road was mainly followed by those manufacturers who maintain the support ribs of the cushion so as to also support the intermediate wall with them. However, this solution only leads to poor results for obvious reasons. In fact, by keeping the nerve all the losses already mentioned are maintained, above all at different regimes from that of the project and furthermore, due to the previously mentioned balance between friction losses and diffusion losses, the introduction of the double wall in the area where the gas is still fast, leading to a greater increase in friction and impact losses which greatly reduces the theoretical advantages of greater diffusion.

A second way would be to widen the curved diffuser section but this causes a greater radial footprint than in large turbines is even less tolerated (transport problems, etc.).

The object of the present invention is precisely to overcome these space problems and to obtain a significantly better diffusion and therefore better turbine efficiency and less noise at the exhaust.

This is substantially achieved with a diffuser constituted by the combination of elements which is given by claim 1. Advantageous developments are given by the dependent claims.

In this diffuser, the first stretch of diffuser without nerve and intermediate walls, which works in optimal conditions and realizes the most important part of the diffusion process, is followed by a double curved diffuser with three walls which allows an excellent final diffusion in the curve and in the available dimensions.

The intermediate wall that allows to create the double diffuser is cantilevered by a series of aerodynamically profiled nerve placed on the final part of the diffuser where the gas is now almost completely diffused at such low speed

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655 976

not to create appreciable losses. This arrangement which allows the initial part of the intermediate wall to be cantilevered is made possible thanks to the stiffness assumed by the intermediate wall following its curvature.

Said initial part of the intermediate wall can then be machined with an appropriate aerodynamic profile in order to divide the incoming current from the first diffusion part into two currents without impact and sudden section reductions taking place and furthermore a lighter part is obtained. "cantilever" according to a profile that is almost optimal for eliminating the "modes" of vibration at the various frequencies encountered in the different driving conditions.

At high speeds the losses due to impacts and frictions are very strong (they grow with quadratic law) and this has led to the elimination of the nerve and to choose a diffuser with only two walls in the first section.

In the curved section, the sufficiently slowed down gas has a greater need for driving (the diffusion in curves is extremely more complex). For this reason the introduction of the intermediate wall without nerve in the initial section allows to work as with two curved diffusers in parallel with almost double diffusion angles and therefore allows to exit into the discharge chamber with speeds almost half of those obtainable with a curved final diffuser traditional.

The final ribs that support the intermediate wall can also be studied and arranged angularly so as to also perform a beneficial function aerodynamically. In fact, by creating a controlled final friction (when the gas has almost completed the expansion), its uniformity of output speed in a circumferential direction is decisively improved.

In fact, due to the radial exit of the gas from the exhaust duct, there is a strong unevenness of the paths of the outgoing threads which, in the absence of ribs, can lead to exit speed from the curved section of the diffuser in the exhaust chamber a few times higher in the part near the discharge mouth than the diametrically opposite part and if you think about the fact that the phenomena of pressure drop and noise vary with a quadratic law with respect to the speed, you understand that negative influence can create this recall of the discharge mouth .

This explains the apparent contradiction of the fact that by introducing the ribs (i.e. obstacles) an improvement in performance can be obtained.

In fact, the ribs, creating a friction at the exit from the curved sections, bring the gas to distribute itself evenly over the circumference of the outlet, masking the call, dissimetric with respect to the axis, of the radial discharge mouth. The gas comes out almost perfectly circumferentially distributed and thanks to an appropriate preferred shape of a duct inside the exhaust chamber which accompanies it in an orderly manner towards the outlet it reaches the final silencer with very low speeds, with pulsation of practically zero pressures and therefore with the minimum aerodynamic noise.

This final arrangement is not negligible since in many diffusers often in the discharge chamber a large part of the pressure recovery laboriously achieved in the diffuser is destroyed in pressure drops. The effect is therefore an increase in turbine efficiency and a considerable decrease in the degree of noise of the exhaust gases which, as known, represents one of the most difficult drawbacks for terrestrial applications (cumbersome, expensive and short-lived silencers as they work at temperatures above 450 ° C).

Experimental tests have fully confirmed this phenomenon and indeed the reduction of final noise is an indirect and immediate measure of the improved performance as the various parameters vary (nerve number, initial profile, differentiation of curvatures and ratios). Also in the experimental field, it has also been pointed out that in the available dimensions, the concept of multiplying the walls in the curved diffusion section cannot be further extended since by adding a 2nd intermediate wall, the friction losses that follow balance the improvements; adding even more it starts to worsen the efficiency.

The invention is now better clarified with reference to the enclosed drawings which illustrate a preferential form of practical embodiment given only by way of non-limiting example since technical and construction variants can always be made without departing from the scope of the present invention.

In these drawings:

fig. 1 shows a partial longitudinal section view of a power gas turbine adopting the diffuser according to the invention;

fig. 2 shows a partial view in longitudinal section and on an enlarged scale of the diffuser of fig. 1;

fig. 3 shows a partial view in longitudinal section and on a strongly enlarged scale of a detail of the diffuser 25 according to the invention.

With reference to the figures, 1 indicates the gas generator of the gas turbine, which supplies the power turbine

2 whose exhaust gases are conveyed to the exhaust tank

3 through the diffuser 4.

30 Said diffuser 4 consists of a first diffusion section 5 with a substantially axial path delimited by two mainly conical coaxial walls 6 and 7. Said section 5, which is provided inclined at a certain angle (see fig. 2) with respect to the horizontal to better present the flow of gas to the curve, it creates 35 the most important part of the diffusion and realizes it in an optimal way since it is free of ribs or intermediate walls.

This section 5 is then followed by a double curved diffuser with three walls 8, 9 and 10 which completes the diffusion of the separated gas in two independent currents and at the same time curves it 40 radially.

The intermediate curved wall 9 which allows the double diffuser to be made, is cantilevered by a series of aerodynamically profiled ribs 11 which have generators parallel to the horizontal axis of the machine and are arranged almost at the end 45 of the double curved diffuser. These ribs 11 are also sized so as to create in the double diffuser a controlled friction at the exit from the curved sections which allows to obtain a uniform circumferential distribution of the gas outlet speed in the exhaust box 3 and therefore to significantly attenuate the dissymmetrical recall of the gas from the mouth 12 of the exhaust box 3. In order not to disturb the uniformity of the circumferential flow of the gas from the diffuser and therefore favor an orderly flow of gas towards the discharge mouth 12, the diffuser 4 is connected to the case drain 3 through 55 a casing 7 with profiles connected to the diffuser and contained in the same drain box.

Finally, the said intermediate curved wall 9 begins with a section 9 'worked and aerodynamically profiled (see specifically Fig. 3) so as to divide the gaseous current from the first section of the diffuser at a speed already reduced, in two currents without impact or sudden section changes.

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2 drawings sheets

Claims (4)

655 976 1. Compact diffuser (4) for high power gas turbines (2), characterized in that it consists of a first diffusion section (5) without ribs and / or intermediate walls and with a substantially axial path, delimited by two mainly conical coaxial walls (6, 7) which is followed by a double curved diffuser with three walls (8, 9, 10) whose intermediate curved wall (9) is cantilevered supported by a series of ribs (11) having generators parallel to the horizontal axis of the turbine and located almost at the end of the said double curved diffuser. Diffuser according to claim 1, characterized in that the said intermediate curved wall (9) of the said double curved diffuser begins with a section (9 ') worked and profiled aerodynamically so as to divide the current without shocks and sudden section variations . 2 Diffuser according to claim 1, characterized in that the said ribs (11) are aerodynamically profiled and sized so as to create a controlled friction at the exit from the curved sections of the diffuser. Diffuser according to claim 1, characterized in that it is connected to the discharge casing (3) of the turbine by means of a casing (7) with profiles connected to the diffuser and contained in the same discharge casing.