DE393485C - Steam or gas turbine - Google Patents

Description

The invention relates to steam or gas turbines and more particularly to blading the low pressure parts of the same.

The size of a turbine unit is determined by the capacity or capability of the last blade ring limited to the passage of large amounts of low-pressure steam. This In turn, performance is primarily determined by the permissible blade height limited with regard to the centrifugal force and secondarily by the Efficiency of the last blade ring, for a given blade height with increasing Outlet angle decreases.

In the German patent specification 322io, 4 is on the one hand a steam turbine has been described in which low pressure parts of the steam are divided into a plurality is subdivided by ring layers, with special blades being provided for each layer and each layer is specially stretched and drained into the drain chamber. The low pressure part this turbine enables the construction of relatively large turbine units, because the low-pressure part can handle larger amounts of steam than was previously possible last blade rings without subdivision was possible.

The purpose of the present invention is now, by increasing its ability to Coping with large amounts of steam to increase the efficiency of a steam turbine. To achieve this goal, according to the invention, blade rings are inserted into the turbine, which have a ring of blades to be used for the steam energy, which show pressure parts which are used to accommodate the in serve one main direction of flowing steam, and for this purpose the steam in the same main direction or exit partially in this direction and partially in a different direction to leave, or else entirely in a direction different from the main direction. Furthermore, this section advantageously also shows a device for subdivision of the steam in individual streams and for conducting them in the pressure part and overpressure part the shovel. These devices are advantageous at the same time to the To expand steam that enters the pressure parts of the blades down to the exhaust steam pressure. If the overpressure parts of the blades serve to divert the * steam entirely or to let it exit partially in the same direction as it enters it is advantageous a

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second guide vane ring provided to the steam emerging from it in a second To lead the rotor blade ring, the steam either in one of the main direction Direction, partly in this and the main direction. This The second rotor blade ring can consist entirely of overpressure blades, or else its blades can have Druckteilejund overprint parts ίο, in the latter case the second Guide vane ring advantageously serves to split the steam into two streams and it on the one hand in the pressure parts, on the other hand in the overpressure parts of the blade ring and that part of the steam which gets into the pressure parts of the blades expand down the evaporation tension. When the low pressure section is a plurality comprised of rotor blade rings, a device is also taken to prevent the formation of Cross flows in the evaporation chamber and thus the creation of eddies and work losses to prevent.

The drawing shows various exemplary embodiments.

Figs. I, 2, 3 are longitudinal sections through the low-pressure part of a steam turbine according to FIG Invention.

Figs. 4, 5 and 6 are individual illustrations on an enlarged scale.

Fig. 7 is a section along the line VII-VII of Fig. 1, while

Figure 8 shows a detail of a modified embodiment.

In Fig. Ι a turbine is assumed! which has a rotor 10 and a cylinder 11 as well as a number of blade rings 12 and nozzle rings 13 of any suitable one Form, for example that of a positive pressure turbine. The last blade ring 12 leaves the steam for further expansion and energy release in the according to the invention formed low-pressure section 15, from which it enters an exhaust steam chamber 16, which is connected to a capacitor (not shown).

The low-pressure section 15 consists of a first guide vane ring 17, which is also suitable! shaped partitions 18 which ^: divide the entire mass of steam into a separate inner and outer layer. The septum is inclined transversely to the blades that, once, outer diverging expansion spaces and inner steam passage spaces are created. The guide blades 17 are followed by a rotor blade ring 20 with the outer ring parts 21, preferably for constant pressure operation, which take up the steam j from the guide blades 17. The show \ fine 20 also have inner parts 22, advantageously designed according to the overpressure form, which i the inner vapor layer from the blades 17 | take up. The inner cushioning layer goes from \ overpressure zz parts of the blades 20 by a further guide vane ring 2 ^ ₁ in which the steam direction and speed is changed accordingly and the from the steam passes into the relatively wide blades 24th These allow the steam either only radially outward or both radially outward and axially into the exhaust steam chamber 16 at the other blade edge. The vane ring 23 is secured by any suitable device, e.g. B. an annular web 25 of the exhaust steam housing held. This support extends advantageously at a suitable distance j beyond the outer edges of the blades 21 and 24 in order to avoid premature mixing of the various layers of vapor, thereby achieving a smooth exit and! To prevent eddies and losses that could otherwise occur due to cross currents. ! The outer expansion channels between the blades 17 for the outer vapor ring layer give a higher degree of expansion than! the inner channels for the inner ring layer, and the former stretch the steam down to practically the lowest tension, so transform! for the action on the outer parts 21 of the blades 20, the pressure in speed. The inner steam layer is only stretched to such an extent that its velocity is maintained at a height that is sufficient for the effect on the blade parts 22. These blade parts are, as can be seen from Fig. 7, advantageously provided with sharpened inlet edges 27 and bent '■ outlet edges 28 of a shape which depends on the type of propellant and the blade speed to the steam in the appropriate direction and with the correct Allowing speed to enter the wide blades 24. A part of the steam is taken up by the inner blade parts 22, which have such a shape that they serve as strong supports for the outer pressure parts 21. The steam reaching between the wide blades 24 is stretched and let out at the periphery.

FIG. 2 shows a modified low-pressure section 30 with guide vanes 31 and rotor blades 32, which correspond to the rings 17 and 20 of FIG. Here, however, the rotor blade ring 32 is followed by a further guide vane ring ^ with an inclined guide wall 34 in order to again form separate passage channels for two damping layers, of which the inner one absorbs the steam from the inner parts of the blades 32 and in which the guide wall serves to which emerges from the blades 32, to be broken down again into an inner and an outer ring layer. The outer vapor ring layer is stretched and its pressure energy is converted into velocity energy.

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converted to act on the pressure parts 35 of the following wide blade ring, while the inner vapor ring layer in the appropriate direction and at a suitable speed is passed into the overpressure parts 36 of the wide blades. The inner vapor ring layer, which emerges from the inner part 33, passes between the wide blades below the inlet edges of the pressure parts 35, is stretched, releases its energy and occurs either radially or partly radially, partly axially the end.

Fig. 3 shows a simplified embodiment of a low-pressure section 40 according to of the invention, in which the first guide vane ring 41 the outer vapor ring layer into the pressure corners 42 of the wide blades can occur while the inner vapor ring layer in the overpressure parts 43 of the broad Shovels. The parts 42 and 43 receive the steam in the main direction one side and let it emerge radially. The pressure parts 21, 35, 42 of Figs. 1, 2 and 3 are of the same shape, as can be seen more clearly from Figs. 4, 5 and 6. Fig. 4 shows the pressure part as a cup with a steam inlet edge 45 and an outlet edge 46 for the radial exit of the steam. This cup is shaped to hold the speed energy of the pressure medium entering between the inlet edges and at the same time the direction of the same from the main direction, in the present case the axial one changes to an approximately radial one.

The cup may be shaped so that parts thereof are above and below the inner parts the blades protrude, as can be seen most clearly from Fig. 4 can be seen. this causes a better distribution of the mass of each cup on the scoop that supports it and also results in a strong cohesion of the cups of all the blades among themselves.

Each cup has an internal cutout 47 on the front and a rib 48 on the Back, which according to the composition of the shovel in the relevant section of the next shovel fits, whereby a rigid connection of the bucket of the shovel is achieved will. As can be seen from Figs. 5 and 6, the buckets of the blades are tightly nested and thus form the steam channels described. To within the cup vortex formations To prevent it, rounded flaps 49 are provided, which guide the steam.

Fig. 4 shows such a guide tab, which extends diagonally from the outer inlet corner of the Mug extends. These guide tabs prevent cross-flow in the most effective way of the steam at the peripheral edges, which otherwise go together with the radial flow Vortices were forming.

It should be noted that the details of the cup shapes can be modified to to adapt to the individual places, provided only that the axial entry of the Propellant is achieved with radial leakage.

j -Further note that the last broad [Blade ring in Fig. 1, 2 and 3 as wide

can be made that a sufficient i exit cross-section for the steam and small 1 outlet angle can be achieved, so that the efficiency has a high value. Since the : Steam escapes at the circumference, it is clear that the back pressure force of the same exits at one point.

■ is practiced at high absolute speed emotional.

While Fig. 1, 2 and 3 show wide blades, the parts 24, 36 and 43 of which allow the steam to escape only at the ^{periphery, blades of a shape 1} can also be used in their place so that the steam is partly also discharged axially as shown in Fig. 8; is interpreted.

\ The steam radially discharging super-I of the wide blades 1 pressure parts in Figs. J, 2 and 3 can also mif curved ribs, i such as the ribs 45 of Fig. 1,

■ be provided, which is not just the blades

j amplify, but also the steam under I avoid eddies better according to the: circumference. The connection of the ribs with! the blades can be carried out in any suitable \ manner, the opposing ribs of adjacent blades abut ι aneinanderi to form guide channels.
I The mode of operation of a steam turbine with; a low pressure section according to the invention! manure is the following:

The steam expands with the release of energy i in the blade rings 12 and 13 in the usual manner and passes from the last blade ring 12 into the low-pressure section. . In Figure 1 this vapor is then the guide vanes 17 j in two annular layers by the transverse walls 18 split and the outer ί ring layer is up to the exhaust steam ^{manufacturer:} underexpanded and arrives at high speed in the pressing parts or cup 21,: from which they on the circumference in the exhaust steam; chamber 16 arrives. The inner ring layer occurs under the partitions 18 from the inner part of the blades 17 in the desired direction! tion and at the appropriate speed I in the inner overpressure parts 22 of the show-I fine 20, where it is a part of the steam energy is drawn. The inner ring layer vapor enters'<at its exit from the pressure parts 22 in the guide vane 23, where the vapor is deflected and its speed is changed. Then the inner layer gets into the; wide blades 24 and radial or according to

Fig. 8 flowing radially and axially into the exhaust steam chamber 16.

In Fig. 2 the mode of operation is similar, only that the subdivision of the steam is increased by a further stage in that the guide vanes 33 are provided with transverse walls 34 in order to subdivide the inner ring layer from the blades 32 again into an inner and outer ring layer . The outer one is stretched and passed at high speed out of the channels of the blades 3s ^m ^ partition walls 34 into the pressure parts 35 of the wide blades, while the inner ring layer gets into the overpressure part 36 of the wide blades and out of this either only radially or radially and axially according to Fig. 8 flows into the evaporation chamber.

In Fig. 3, the steam supply is simplified and the mode of operation without further explanations understandable.

As can be seen from the present description, according to the present invention a turbine section is provided, in which the propellant in at least two conaxial Ring layers are subdivided, each of which transfers the energy to differently shaped special ones Releases blade parts into which the propellant enters axially and either only radially or radial and axial exit. This allows large amounts of low-pressure steam to be handled and build large turbine units that also work economically.

Claims (11)

Patent Claims: i. Steam or gas turbine, characterized in that blade rings are provided to cope with large amounts of steam, which have both constant pressure parts that take up the steam in the main direction and release it in a different direction, as well as overpressure parts j that have the steam in the main direction. j tion and either in this direction or partly in this and partly \ wise in a different direction I or also completely in a direction different from the main I direction. ] 2. Turbine according to claim 1, characterized in that a guide device So it is provided to ring the steam in | layers and subdivide it into the constant pressure parts and positive pressure parts of the | Guide blades. 3. Turbine according to claims 1 and 2, characterized in that the device to subdivide the steam into ring layers at the same time serves to those Part of the steam that gets into the pressure parts of the blades, on exhaust steam voltage expand down. 4. Turbine according to claims 1 or 2, characterized in that the overpressure parts The blades release the steam in whole or in part in the direction of entry and behind them a second guide blade ring is provided, which directs the steam into a second blade ring, which in turn, the steam either in a direction different from the direction of entry or partially in the direction of entry and partly in the different gives. 5. Turbine according to claims 1 and 4, characterized in that the second rotor blade ring consists only of overpressure parts consists. 6. Turbine according to claims 1 and 4, characterized in that the blades of the second blade ring show both pressure parts and overpressure parts and in the second vane ring the steam is divided into annular layers in order to one part into the pressure parts of the rotor blades, the other part into the overpressure parts to direct. 7. Turbine according to claims 1 and f>, characterized in that the second Blade ring that steam that enters the pressure parts of the blades on Evaporation voltage expanded down. 8. Turbine according to claims 1 and 4 to 7, characterized by the arrangement of guide surfaces, which cause the formation of cross-currents in the one from the two rotor blade rings Prevent escaping steam. 9. turbine blade for turbines according to claim 1, characterized in that the scoop contains a pressure part or cup in addition to an overpressure part, which the deflects steam entering in one main direction and exiting in another direction leaves. 10. turbine blade according to claim 9, characterized in that the cup on the outer edge of the shovel is seated. 11. Turbine blade according to claim 9, characterized in that the cup has a rounded corner tab, which serves to prevent the entering in the main direction and to guide steam emerging in a different direction on its diagonal path and thereby avoid the formation of eddies. 1 sheet of drawings.