GB2270543A - Turbines. - Google Patents

Abstract

The turbine comprises a pair of relatively movable working members 11, 12 having closely spaced opposed surfaces with depressions 13 therein acting to transer kinetic energy between a working fluid and the working members. A rotating surface may be conical or cylindrical (figures 5, 6) and the depressions may be formed by a rotary cutting tool (81, 91, figures 7 and 8) to form half-moon shaped depressions or crescent shaped depressions. <IMAGE>

Description

TURBINES This invention relates to turbines.

Turbines, whether used as motors or as pumps, are constructed by attaching vanes or blades to rotary and stationary members, the precise method of attachment and the configuration depending upon the type of turbine - steam, gas or water, axial or radial flow and so on.

The manner of construction and the shaping and disposition of the vanes or blades for maximum power output of efficiency combined with the need for reliability in high speed operation, often, especially in the case of gas turbines, at elevated temperatures means that the capital cost of a turbine is high.

The present invention provides turbines of which the capital cost will be low because of the design and construction and the reliability during high speed operation can be increased.

The invention comprises a turbine comprising a pair of relatively movable working members having closely spaced opposed surfaces with depressions therein acting to transer kinetic energy between a working fluid and the working members.

The depressions may be crescent shaped in face view, and may be formed or similar to depressions which are formed by an angled cylindrical rotary cutting tool, which may have a concave end face.

Both members may have depressions.

The depressions, which are easily produced by a machining operation or by a moulding technique, take the place of attached blades, and many different configurations can be envisaged corresponding to the many different configurations of conventional, bladed or vaned turbines.

While the general notion of a turbine is, of course, one involving rotation, it is also possible to conceive of linear turbines, in like manner to the concept of a linear electric motor. Usually, however, the turbine will be rotary.

The members may be relatively rotatable about an axis and the depressions arranged at different radii or axial positions or both on the two members, the depressions on one member overlapping those on the other.

At least one of the members may have depressions at more than one radius. The members may have opposed plane surfaces, or opposed surfaces of solids of revolution - the surfaces may be conical, for example.

Conveniently, one member is fixed while the other rotates.

Working fluid may flow outwardly from the axis of relative rotation. The working fluid may enter axially of one, fixed, member and leave at the outer edge of the space between the surfaces.

A turbine may have members with two or more pairs of opposed surfaces with depressions and may for example comprise a disc with depressions on both faces in a working chamber formed by members with cogenerating faces either side, and a turbine may have a plurality of such discs in such chambers.

The turbine may have a fixed axial delivery duct for working fluid and flow guide means fixed in said duct diverting the axial fluid flow into flow having a radial component.

Embodiments of turbines and methods for making them according to the invention will now be described with reference to the accompanying drawings, in which Figure 1 is a face view of a pair of disc members of a first turbine arrangement; Figure 2 is an axial section through the two discs and associated shafts when assembled in operative relationship; Figure 3 is a detail from Figure 2 to a larger scale; Figure 4 is a view in the direction of arrow 4 in Figure 3; Figure 5 is an axial section through a conical machine; Figure 6 is an axial section through an axial flow machine; Figure 7 is a diagrammatic illustration of a first method of cutting the depressions; Figure 8 is an illustration like Figure 7 of a second method; and Figure 9 is an axial part-sectional elevation of another multi-stage embodiment.

The drawings illustrate turbines comprising a pair of relatively movable working members 11,12 having closely spaced opposed surfaces lla,12a with depressions 13 therein acting to transfer kinetic energy between a working fluid 14 and the working members 11,12.

Figures 1 and 2 illustrate a simple arrangement in which the members 11,12 comprise a fixed disc 15 and a rotary disc 16. The discs 16,15 have on their opposed faces lla,12a concentric rings of depressions 13, those on disc 15 being at different radii from those on disc 16 and overlapping as more clearly shown in in Figures 3 and 4. In Figure 4, the depressions of face lia are shown in solid line while those of face 12a are shown in broken line.

Figures 7 and 8 illustrate how such depressions 13 may be formed in the discs 15,16 using rotary cutting tools. A cylindrical cutting tool 81 is sunk at an angle of say 450 a little way into the surface lla this actually produces a half-moon shape as seen face-on, the cutting tool 91 illustrated in Figure 8, with a concave end face 92 being used to produce the crescent shapes of Figure 4.

As shown in Figure 2, fixed disc 15 has a working fluid duct 17 and rotary disc 16 is mounted on a rotary shaft 18 with the faces lla,12a in closely spaced arrangement. The duct 17 has a flow diverter 19 attached to it which projects into a recess 21 of the disc 16 and diverts the axial flow of the working fluid into a radial flow between the discs 15,16 without imposing any axial thrust on the disc 16. There will still, of course, be axial thrust on disc 16, but less than if the disc received the full force of the axial flow of working fluid through the duct 17.

The fluid simply flows in a sinuous path, generally radially outwardly from each concentric circle of depressions in one disc to the next in the other.

Of course, the depth, shape and spacing of the depressions can be designed to be different depending on the radius of the circle to optimise performance of the turbine in similar fashion to the way turbine blades and vanes are conventionally arranged from stage to stage of a multi-stage arrangement.

Figure 9 illustrates a multi-stage machine in which discs 101 are mounted on a hollow, stationary shaft 103 and annuli 102 are supported in a rotary casing 104. Working fluid supplied to the hollow shaft 103 flows through apertures 133 between the discs 101 and annuli 102 and exits the casing 104 through further apertures 134. The casing 104 is supported on bearings 132 on the hollow shaft 103 for rotation therabout. The casing 104 is surrounded by an enclosure 135 with an outlet 136 for spent working fluid.

To assemble the arrangement, a disc 101 is pushed along the shaft 103 to a locating position, then an annulus 102 is put in place, followed by another disc 101 and so on until the assembly is complete as illustrated.

Another arrangement is illustrated in Figure 5, in which the working members 11,12 are shown as having cooperating conical surfaces lla,12a with depressions 13 machined or otherwise formed in them. Here, the inner cone 61 is the rotor, and the outer cone 62 is a stator supplying working fluid to the arrangement via a conduit 63.

The arrangement of Figure 6 is basically similar to that of Figure 5, except that instead of the configuration being that of a cone, a cylinder arrangement is provided with circumferential rows of depressions in the cylindrical surfaces lla,12a.

The dimensions of the arrangements will depend upon the required power (or, as the case may be, pumping output, it being understood that while the description has been primarily concerned with motors, the devices described and illustrated can also operate, in reverse, as pumps or compressors) but in a typical arrangement with discs 2 cm thick and 40 cm in diameter, the depressions can have a depth of, say, 1 cm.

The spacing of the relatively rotatable members is desirably as close as possible having regard to the fact that actual contact is to be avoided. In the case of purely disc-like members the usual problems of creep and extension under centrifugal stress will be largely avoided since they will not, or not substantially, affect leakage of working fluid nor need large tolerances be required to avoid the risk of high-speed collision.

The principal attraction of the invention is the fact that turbine components can be machined out of solid by a simple technique - once a design has been established even quite rudimentary workshop metalworking tools can be used to make precision components.

Of course, once a design has been established a prototype disc can be used as a form to produce a mould for the mass production of further discs (or, indeed, cones or cylinders or other design of component).

Claims (20)

1. A turbine comprising a pair of relatively movable working members having closely spaced opposed surfaces with depressions therein acting to transer kinetic energy between a working fluid and the working members.

2. A turbine according to claim 1, in which the depressions are crescent-shaped in face view.

3. A turbine according to claim 2, in which the depressions are formed or are similar to depressions formed by an angled cylindrical rotary cutting tool.

4. A turbine according to claim 3, in which the tool has a concave end face.

5. A turbine according to any one of claims 1 to 4, in which both members have depressions.

6. A turbine according to claim 5, in which the members are relatively rotatable about an axis and the depressions are arranged at different radii on the two members, the depressions on one member overlapping radially those on the other.

7. A turbine according to claim 6, in which at least one of the members has depressions at more than one radius.

8. A turbine according to any one of claims 1 to 7, in which the members have opposed plane surfaces.

9. A turbine according to any one of claims 1 to 7, in which the members have opposed surfaces of solids of revolution.

10. A turbine according to claim 9, in which the surfaces are conical.

11. A turbine according to any one of claims 1 to 10, in which one member is fixed.

12. A turbine according to any one of claims 1 to 11, in which working fluid flows outwardly from the axis of relative rotation of relatively rotatable members.

13. A turbine according to any one of claims 1 to 12, in which working fluid enters axially of one, fixed member and leaves at the outer edge of the space between the surfaces.

14. A turbine according to any one of claims 1 to 13, having members with two or more pairs of opposed surfaces with depressions.

15. A turbine according to claim 14, comprising a disc with depressions on both faces in a working chamber formed by members with cooperating faces either side.

16. A turbine according to claim 15, having a plurality of such discs in such chambers.

17. A turbine according to any one of claims 1 to 16, having a fixed axial delivery duct for working fluid and flow guide means fixed in said duct diverting the axial fluid flow into flow having a radial component.

18. A method for making a turbine member comprising making crescent shaped depressions in a surface.

19. A method according to claim 18, in which the depressions are made by an angled cylindrical cutting tool.

20. A method according to claim 19, in which the cutting tool has a concave end face.