DE2461770C3 - - Google Patents

Description

The present invention relates to an impeller blading of an axial flow machine, wherein the blading is made up of radially outer airfoils and radially inner airfoils consists, with a shroud that separates the outer and inner blades radially from each other, and a plurality of inner ones within the circumferential division defined by the outer airfoils Airfoils are arranged.

Such an impeller blading is known from FR-PS 31 273.

In this known design, which is used as a sheath flow fan for a two-circuit aircraft propulsion turbine serves, the point is that strong noise should be prevented, which then occur would, if using fairly long profile tendons to ensure adequate performance would have to find. Therefore, instead of a flow profile with a long profile chord, radially inside, where it comes mainly to the development of noise, two blades in a row within the shroud arranged, which converge with their heads in a common node at which a radially outer blade is attached. Each of the inner blades represents a complete Flow profile, so that basically there are two rotor blade rings arranged one behind the other.

Difficulty problems are not considered in the known training, and these would be for Solving such problems is also not suitable

The present invention is about the final stages of condensing steam turbines where the Steam has already reached large specific volumes and where, accordingly, large volume throughputs must be mastered. This means that the blades should be as long as possible in terms of strength Need to become.

The decisive stresses result from the centrifugal forces and the bending moments. In this way, the centrifugal forces reach each rotor blade, which is introduced into the disk from its root must, orders of magnitude from 100 to 200 t, which equates to a number of 70 to 140 blades Blade ring causes considerable loads on the disk for the absorption of such forces and The known construction would be completely unsuitable for the two blades consecutive inner rotor blade rings are attached to the same thin hub body.

This applies in particular to the bending moments that occur. The well-known construction with the inner blades converging radially outwards have a small section modulus in the circumferential direction especially with slightly curved blade profiles, which in view of the considerable forces how they act on the blades of the last stages of steam turbines would not be enough.

The aforementioned disadvantages are particularly noticeable when, in the case of a steam turbine, this is maintained the optimal heat gradient of the last stage increases the efficiency in a known manner should be that the heat gradient of the outer blades of the penultimate stage is reduced, which leads to Necessity leads to reduce the heat gradient on the inner blades, as already in the Monograph by A. Stodola, "Steam and Gas Turbines", Berlin 1924, is mentioned

A reduction in the heat gradient, however, results in a smaller curvature of the center line of the profile and thereby a reduction in its moment of inertia, so that a given bending moment is greater Brings stresses with it.

The object of the present invention is to provide a two-tier impeller blading of an axially flowed through To create turbomachine that is of particular strength, in particular with respect to the occurring bending moments is.

Based on the training described at the outset, this object is achieved according to the invention proposed that the shroud segmented according to the circumferential division of the outer blades and that the inner blades, corresponding to the shroud segments, are profile sections which between the shroud segment and the blade root to form at least one flow channel next to one another are arranged and with the profile sections of the neighboring blades which are in contact in the circumferential direction form complete flow profiles.

As a result of this design, a plurality of inner blades with the associated shroud form each time a frame-like rigid structural unit that is particularly resistant to the bending moments that occur is stiff and resilient, even if the complete airfoil to which its profile sections form join together, are only slightly curved. This reduces the heat vessels to the

Shoveling the inner tier.

The reduction in the heat gradient on the blades of the inner tier of the penultimate turbine stage also allows the heat gradient to be reduced on the blades of the outer tier of this stage, which means that the ratio of the circumferential speed U of the impeller to the speed C ₃ , which is equivalent to the heat gradient , i.e. the ratio U / Ca approaches the optimum, whereby the vector of the exit speed from the turbine approaches the axial direction. This means that the energy losses at the exit are lower and the efficiency of the turbine is better.

Another consequence of the reduction in the heat gradient on the blades of the outer tier is that the Mach numbers in the guide vane ring and in the rotor blade Jiranz become lower. This will make the with Losses associated with compression shocks and dilution waves are lower, which is also in the sense of a Increasing the efficiency of the turbine acts

Another consequence of the reduction in the heat gradient on the blades of the upper tier there is a reduction in the steam parameters at the entrance to them Shovels, which for a given steam throughput increases the blade channel cross-sectional area of the means outer tier of the guide vane ring at the narrowest point. Associated with this is an enlargement the vane angle of the outer tier of the vane ring, d. H. an approximation of the optimal values. This also reduces energy losses and improves efficiency.

In addition, the reduction in the heat gradient on the blades of the outer tier allows the Increase in the heat gradient of the last turbine stage, so that there is an increase in the steam parameters in the transition nozzle between the blades of the inner tier of the penultimate stage and the Last stage vanes comes in, which means lower steam flow velocity. These lower steam flow speed means, in turn, a reduction in energy losses.

By reducing the energy losses at the outer vanes of the vane ring and the rotor blade ring as a result of reducing the thermal gradient in these blades it is convenient to ta increase the vapor flow rate through the blades of the outer floor, through enlargement of the outlet cross-sectional area of the outer blades, ie by a Shifting the shroud to a smaller diameter.

As the heat gradient on the blades of the outer tier becomes smaller, the optimum length increases of these blades and reaches about 65 to 75% of the total length of the outer and inner blades.

Such a displacement of the shroud inwards can reduce the exit cross-sectional area of the Turbine increased, the steam throughput increased and the turbine output increased.

In a special embodiment of the present invention, the center of gravity axis of the outer Airfoil radially above the center of gravity axis of one of the inner profile sections. With such a training there is no significant bending stress on the associated shroud segment by the Centrifugal force acting on the outer blade.

It is also useful if the center of gravity axis of the outer blade is opposite to the center of gravity axis at least one of the profile sections is offset so that the centrifugal force Bending moment due to the gas forces on the swing acting bending moment counteracts Through such a training it can succeed, the total to make acting bending moments almost completely disappear.

Embodiments of the invention are explained in more detail below with reference to the drawings. FIG. 1 shows the front view of part of the impeller blading of an axially flow-through flow machine according to the invention,
F i g. 2 shows the section along line U-II in F i g. 1,
F i g. 3 the development of the cut along line M-Hl inFig. 2,

F i g. 4 another version of the blading of the inner floor,

F i g. 5 shows the development of the section along line V-V in FIG. 4,

F i g. 6 a third embodiment of the blading of the inner tier,

F i g. 7 the development of the section according to line VII-VII in F ig. 6,

8 shows a two-tier blading, in which the center of gravity axis of a profile section of the inner Floor coincides with the center of gravity axis of the profiles of the outer blade,

F i g. 9 the development of the section along line IX-IX in F i g. 8th,

F i g. 10 an embodiment in which the axes of gravity the inner and outer blading are offset in a certain way,

F i g. 11 the development of the cut according to the line XI-XI in Fig. 10.

The impeller of a turbomachine shown in FIG. 1 has a disk wheel 1 to which blades 2 of the inner tier are attached with a shroud 3. The shroud 3 is divided into segments, and each segment carries an outer airfoil 4. Each inner one The blade has a blade root 5 with which it is attached to the disk wheel 1.

Each inner blade 2 does not constitute a complete section in the section taken normal to its longitudinal extension Flow profile, but consists of profile sections 6 and 7, which are at a distance from each other are arranged, which is equal to the size of the blade channel

Each shroud segment 3 forms with at least two such profile sections 6 and 7 a frame-like rigid one Construction. As shown in FIG. 3, each profile section 6 forms with the profile section 7 of the adjacent blade a reasonable flow profile.

The increase in the stiffness of the inner blading improves the absorption of the bending moments that are generated by the forces of the steam flow. This makes it possible to reduce the curvature of the skeleton line bb of the complete flow profiles, that is, to enlarge the angles β \ at the inlet of the steam flow and O2 at the outlet. The enlargement of the angles β \ and β ₂ brings about a reduction in the heat gradient on the blades 2 of the inner tier. This in turn reduces the heat gradient at the outer blades 4.

The reduction in the heat gradient at the outer blades 4 leads to the ratio of the circumferential speed (J of the impeller to the speed C ₀ , which is equivalent to the heat gradient,

so the ratio - = -, approaches the optimal and

consequently the vector of the exit velocity of the The turbine approaches the axial direction as a result, the energy losses increase with the exit speed lower, and the efficiency of the turbine gets better.

Another consequence of the reduction in the heat gradient on the outer blades 4 is that the Mach numbers on the blade of the guide vane ring (not shown) and the outer blades 4 of the impeller become smaller. This leads to Reduction of energy losses due to shock waves and thinning waves.

The reduction of the energy losses on the outer blades 4 of the impeller allows to move the shroud 3 to a smaller diameter. This increases the length of the outer Blade 4 of the impeller, whereby the steam consumption and the turbine power can be increased.

The flow channel 10 has a confuser-diffuser profile along the direction of the velocity vector w of the steam flow, that is, the dimension 20 of the blade channel at the steam inlet is greater than the dimension at inside the channel 10, and this is smaller than the dimension ar at the steam outlet .

In the confuser section of the blade channel 10, the steam flow is accelerated up to one Velocity required to pass the required amount of steam through the diffuser section a part of the kinetic energy is converted into potential energy Heat gradient at the inner blades 2 of the impeller to reduce and consequently to increase the efficiency and power of the turbine.

In the variant shown in Fig. 4/5 orders each inner blade 11 in the normal section taken from its extension from three profile sections 12, 13 and 14 so that there is a complete flow profile over three adjacent blades extends away

In the variant embodiment shown in FIG. 6/7, each inner blade 16 consists of three profile sections 17, 18 and 19, of which only the profile sections 17 and 18 Hill are connected to the shroud segment 20.

In the embodiment variant shown in Fig. 8/9 of the inner blades 35, which are each composed of profile sections 3S and 39, falls the axis of the center of gravity of the profile sections 36 with the center of gravity axis of the profiles 37 of the associated outer airfoil 38 together or represents the extension of the same. In this case, the centrifugal force of the outer one engages Blade 38 mainly on the profile section 36 of the inner blade 35. The remaining profile section 39 of the inner blade 35 takes the bending moment from the shroud segment 40 Forces that are exerted on the blades by the steam flow.

In the embodiment variant shown in Fig. 10/11 of the inner blades 44, each of which consists of two Profile sections 45 and 46 consist, the center of gravity of the system is from the two Sections 45 and 46 of each inner blade 44 not in extension of the center of gravity axis of the profiles 37 of the associated outer blade 38, but offset from this by the size <5 by the centrifugal force of the outer airfoil 38 generated bending moment, which is the product of the Centrifugal force F times the size ό is the opposite the bending moment directed by the force of the steam flow acting on the blades as a result the profile sections 45 and 46 are relieved of bending forces

For this purpose 4 sheets of drawings

Claims (3)

Patent claims: 1. Impeller blading of an axial flow machine, the blading consists of radially outer blades and radially inner blades, with a shroud, which radially separates the outer and inner airfoils from one another, and wherein within the determined by the outer blades circumferential division several inner blades are arranged, characterized in that the shroud according to the circumferential division the outer blades (4) is segmented and that the inner blades (2) accordingly of the shroud segments (3) are profile sections (6, 7) between the shroud segment (3) and Blade root (5) arranged next to one another to form at least one flow channel (10) and with the profile sections of the neighboring blades which are in contact in the circumferential direction form complete flow profiles. 2. impeller blading according to claim 1, characterized in that the center of gravity axis of the outer airfoil (38) radially above the center of gravity axis of one of the inner profile sections (35) lies. 3. impeller blading according to claims 1 and 2, characterized in that the center of gravity axis of the outer blade (38) relative to the center of gravity axis of at least one of the profile sections (45,46) is offset in such a way that the bending moment produced by the centrifugal force (F) counteracts the bending moment acting on the blade by the gas forces.