NO843456L - TURBIN FOR SPECIAL WINDOW ENERGY TRANSLATION - Google Patents

Description

.Turbine for conversion of special wind energy.

The present invention relates to a turbine for converting wind energy in particular according to the preamble of claim 1.

Turbines of the aforementioned type are e.g. known from DE-PS 518 733

and from FR-PS 921 518. On such turbines, the flow arrester blades can be adjusted optimally according to the wind flow during their rotation with the help of rods from the center of the rotor, but the entire adjustment mechanism becomes relatively complicated and burdensome for the rotor.

In a similar way, a wind turbine according to US-PS 1 139 103 works, where the adjustment takes place by means of a double cord pull, one of which is spring-loaded at all times and the other must be guided along a correspondingly designed curve guide. If this turbine is to be functional at all, it will be expensive and complicated in its structure in order for the self-adjustment of the flow arrester blades to work.

When designing such turbines, the following must also be taken into account: Flow arrester blades with less slender, symmetrical droplet cross-sections (the degree of slenderness is defined by the ratio between the two main axes of the cross-section) are indeed self-starting (i.e. the entire rotor), but have a correspondingly large resistance that prevents the highest possible circulation speed. Very slim fan blade profiles, on the other hand, provide less resistance so that a rotor equipped with such can achieve very high rotational speeds which can be several times higher than the • actual wind speed, but such rotors cannot start by themselves, so that you have to resort to suitable precautions and to - laying equipment for such rotors (auxiliary operation). Apart from this, the use of self-starting profiles will naturally lead to a greater weight load.

The invention therefore intends to improve a turbine of the type mentioned at the outset in such a way that, despite the use of light flow arresting blades, which provide little resistance and a high rotational speed, it still starts by itself and without the need for any expensive and burdensome steering from the center of the rotor.

This task is solved by a turbine of the initially mentioned type as stated in the characteristics of claim 1., Beneficial further developments are stated in the sub-claims..

With the solution according to the invention, there is only to a certain extent a thick flow profile, which, however, is reduced on both wall surfaces of such a profile, i.e. that the flow-catching blade consists of two staggered arranged surfaces which in the circulation direction, respectively in relation to the inflow, have a certain displacement in relation to each other, as the two surfaces can in extreme cases be flat surfaces.

It has surprisingly turned out that such a designed turbine, obviously due to the above-mentioned profile (in the sense of pyro-felt cross-section) and the resulting resistance reduction, can achieve extremely high revolutions (naturally depending on the prevailing inflow velocity of the driving medium)

and without further ado starts by itself, even if there is basically no self-starting profile (i.e. with a smaller slim droplet profile).

As will be explained in more detail later, one thinks of further-developed, advantageous embodiments which contribute to the optimization of the energy turnover.

The turbine according to the invention will be described in more detail below with reference to the design examples shown in the drawings. Fig. 1 is a plan view of the turbine;

Fig. 2 shows the turbine in side view.

Fig. 3 shows another embodiment of the turbine.

Fig. 4 shows a flow arrester blade in side view.

Fig. 5-10 shows a plan view of different embodiments of the flow arrester blades; and

Fig. 11 shows a special embodiment of the rotor.

Initially, attention is drawn to the fact that the turbine's rotor can be equipped with a flow arrester blade (and then necessarily with a corresponding counterweight), but that it can also be equipped with several flow arrester blades. As is known, the rotor as a whole can also be arranged to be adjustable in the upward and downward direction on a turbine mast 8.

The basic principle for the design of the turbine or the flow arresting blade can be seen from fig. 1, where in the present case with flow arresting blades it is understood that these consist of two surfaces 2, 3.

The two surfaces 2, 3 can preferably, but not necessarily, be attached to a common rotor arm, as the rotor according to fig. 1

o'1

consists of three rotor arms 4 mutually offset 120, which rotor turns the rotor axis 5. In the shown mutual displacement of the surfaces 2, 3, the surface 2 acts as a front wing 2' to the surface 3, as both surfaces limit a flow channel 6. As denoted by 1' and indicated by a broken line in fig. 1,

the surfaces 2, 3 practically form the outer limiting surfaces of a wing cross-section.

The surfaces of the flow arresting blades 1 extend in the working position approximately vertically on the drawing plane, but can possibly also be rotatable, as shown by the arrow 9 in fig. 2 suggests, if e.g. to be able to be swung to the storm protection position 10. In fig. 2, only one flow arresting blade 1 is arranged in connection with a corresponding counterweight 11, which may also consist of two small surfaces with a corresponding weight.

By arranging two or more flow arresting blades 1, it can be ensured by the adjustability of the rotor arm 4 that the flow arresting blades 1 in working position rotate in separate circulation spaces (fig. 3) so as not to interfere with each other, i.e. to not

to take the "wind out of the sails" for each other.

In fig. 4, 5 shows a flow arresting blade 1 where the body 12 practically has no length perpendicular to the drawing plane, but this only has the surfaces 2, 3, respectively. the forewing 2'. The front wing 2' can be adjusted using adjustment elements 13 which are arranged at the body 12 and the rotor arm 4

and works due to centrifugal force.

On. fig. 6 - 8 also show two staggered arranged surfaces 2, 3 which sit on the body 12, which in turn is attached to the end of the rotor arm 4. The body is in fig. 6 is limited rotatable about the axis 14, as centrifugal force-regulated end limiting elements 15 ensure that the entire flow trap blade 1 is held firmly in an optimal working position (the hatched position of the end limiting elements 15).

In the embodiment according to fig. 7, this end position is achieved by means of a leaf spring device 16 which, to start the rotor, spreads the two surfaces 2, 3 to the rear and presses them together in the direction of the arrow at the front. At a sufficiently high number of revolutions, the centrifugal force will act on the surfaces 2, 3 (it will be greatest at the front of 2 and at the back of 3), whereby the two surfaces are pressed to the position shown by rotation about the axes 14'.

The embodiment according to fig. 10 follows the basic principle described above, but otherwise deviates in that the surface 3 is divided in two and its rear part 3' is limitedly pivotable together with the front wing 2', the front part of the surface 3 being firmly connected to the rotor arm.

As regards the setting elements 13 in Fig. 5 for the front wing 2', their setting can be effected by providing the cylinder space for the small setting piston 13'

with a back-up nozzle 13" facing the inflow direction.

As regards fig. 7-9, the setting of the two ..surfaces 2, 3 can also take place with the help of a centrifugal force regulator 17, as shown in fig. 8 shows, as what fig. 9 applies, reference should be made to the fact that the two surfaces 2, 3 can only be displaced radially in relation to the rotor axis 5. 12 is thereby only a flow body, which only sits on the rotor arm and which carries the surfaces 2, 3, and which practically has no longitudinal extent perpendicular to the drawing plane.

To fig. 10 it is further to be noted that here too a stowing pressure nozzle (not shown) impinges on the end limiting elements 15 ..

As soon as the ppp stiffening pressure is large enough, the piston rod is located with its end at the apex of the triangular recess shown, whereby the front wing 2' and the rear part 3', which in this case together form a setting unit, are in the optimal working position at the highest rpm..

Fig. 11 is a special embodiment of the rotor which must. seen

in connection with fig. 3, i.e. that the rotor arm 4 for the surfaces' 2, 3 (on which the rotor arms are seated - not shown - a pair of the surfaces 2, 3) is assigned to a short rotor arm 4' which is arranged in a scissor-like manner for pivoting of counterweights. i'11. depending on the number of revolutions.

In summary, the basic idea of the invention is realized by the described design of the turbine, namely to replace a thick, self-starting profile with two mutually offset thin profiles or surfaces 2, 3, which in themselves ■ alone do not enable self-starting or which only enable this by a corresponding setting from the center of the rotor, and which only gives minimal resistance at high rpm.

Finally, it should be said in connection with fig...3 that the rotor is provided with a flywheel 8" and is stored to a greater or lesser extent on the mast 8 and can possibly be connected to a generator on the ground via one articulated shaft 8' .

Claims (9)

1. Turbine for conversion of wind energy in particular to other forms of energy, consisting of a horizontal rotor rotatably mounted on a mast on which at least one flow arrester blade is arranged vertically, characterized in that the at least one flow arrester blade. (1) is formed by two surfaces (2, 3)-, and that one of the two surfaces on at least one rotor arm (4), in relation to the other surface, is arranged radially offset and/or at least partly behind this. 2. Turbine according to claim 1, characterized in that the surface (2) acting as a vane (2 <1>) has a smaller radial distance from the rotor axis (5) than the other surface (3). 3. Turbine according to claim 1 and/or 2, characterized in that at least one of the two surfaces (2, 3) is adjustable in relation to its longitudinal axis on the rotor arm (4). 4. Turbine according to claims 1-3, characterized in that the front wing (2') with its surface (2) and the second surface (3) form a flow channel (6). 5. Turbine according to claim 3 and/or 4, characterized in that the at least one adjustable surface (2, 3) is provided with adjustment limiting elements., 6. Turbine according to one of the claims 1-5, characterized in that with the arrangement of at least two flow arrester blades (1) on the rotor (4-), each blade on the rotor is arranged so that it passes through a separate space that is not disturbed by others flow sheets.,' 7.. Turbine according to claim 6, characterized in that the rotor arm (4) is adjustably arranged on its rotor axis (.5). 8. Turbine according to one of the claims 1 - 7, characterized in that the flow arrester blade (1) formed by two surfaces (2, 3) is arranged to be rotatable in relation to its longitudinal extent on the end of the rotor arm (4). 9.. Turbine according to claim 1, especially for water, characterized in that the front wing (2') and the downstream part (3') of the second surface (3), in relation to the upstream part of the second surface (3) are arranged together on the rotor arm (4) .