RU2661221C1 - Double action orthogonal power unit - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to the field of power machines building. Double-acting orthogonal power unit comprises an orthogonal turbine with one or more airfoil blades installed by means of a cross-beams on the end half-shafts, and an electric generator, which shaft is connected to one of the orthogonal turbine half-shafts, at that, the half-shafts are located coaxially, and the half-shafts blades and axes are oriented transversely to the flow incident on the orthogonal turbine, at that, each blade made with an aerodynamic profile is symmetrically relative to the said blade axis of rotation provided with a blade with the active turbine blade profile, also oriented across the flow incident on the orthogonal turbine and located from the blade, made with the aerodynamic profile axis of rotation at a distance of 0.35 to 0.5 from the distance, on which the blade with an aerodynamic profile is located from the axis of rotation,wherein all blades are made with projecting above the blades outer surface baffles, oriented perpendicular to the orthogonal turbine axis of rotation.

EFFECT: invention is aimed at increasing the double action orthogonal power unit performance and preventing the turbine from stopping with the blade speed of rotation decrease below the optimum one.

4 cl, 2 dwg

Description

The invention relates to the field of power engineering and can be used in the construction of power plants on the flow of water or air.

A power unit is known comprising an orthogonal turbine with hydrodynamic profile blades mounted by means of a traverse around the shaft along it, and an electric generator whose shaft is connected to the orthogonal turbine shaft, and the turbine shaft and blades are oriented transversely to the air flow incident on the orthogonal turbine (see US patent No. 7586209, class F03B 13/00, published 08.09.2009).

However, the design of this energy generator involves the use of auxiliary energy equipment to generate electricity in the absence of flow or its slight pressure.

The closest to the invention in technical essence and the achieved result is an orthogonal power unit containing an orthogonal turbine with one or more aerodynamic profile vanes mounted by traverses on the end shafts, and an electric generator, the shaft of which is connected to one of the half shafts of the orthogonal turbine, with the half shafts located coaxially, and the blades and axles of the half-shafts are oriented across the flow running onto the orthogonal turbine (see patent RU No. 2616334, class F03D 3/06, publ. 14.04.2 017).

However, the turbine design described above does not allow for high energy efficiency, due to the fact that the maximum pulling force of the blades of such turbines is observed in the region where the blades intersect the flow path. However, instability of the turbine operation described above is possible in the modes when the turbine power is below the maximum value, i.e. when the speed of rotation of the blades is below optimal, and the braking moment of the generator is weakly dependent on the speed of rotation. This causes difficulties with acceleration of the turbine from a standstill and can cause the turbine to stop when it is overloaded.

The technical problem to which the present invention is directed is the elimination of the above disadvantages.

The technical result consists in the fact that an increase in the performance of a double-acting orthogonal power unit is achieved by more efficiently converting the kinetic energy of the medium flow incident on the blades of the orthogonal turbine into the mechanical rotational energy of the shaft of the orthogonal turbine and thus preventing the turbine from stopping when the rotational speed of the blade is reduced lower than optimal.

The indicated technical problem is solved, and the technical result is achieved due to the fact that the double-acting orthogonal power unit contains an orthogonal turbine with one or more aerodynamic profile blades mounted by means of traverses on the end shafts, and an electric generator whose shaft is connected to one of the half-shafts of the orthogonal turbine, in this case, the half-shafts are aligned, and the blades and axes of the half-shafts are oriented across the flow running on the orthogonal turbine, with each a part made with an aerodynamic profile is provided symmetrically with respect to the axis of rotation of the specified blade with a blade with the profile of the blade of an active turbine, also oriented transverse to the flow running onto the orthogonal turbine, and located from the axis of rotation of the blade made with the aerodynamic profile at a distance of 0.35 up to 0.5 from the distance at which the blade with the aerodynamic profile is located from the axis of rotation, and all the blades are made with partitions protruding above the outer surface of the blades and oriented perpendicular to the axis of rotation of the orthogonal turbine.

The blades are preferably made in a helical line.

The blades are preferably made with a straight or arcuate chord, curved along the path of motion of the blades around the axis of rotation.

An orthogonal turbine may be provided with at least one additional blade made with an aerodynamic profile and provided symmetrically with respect to the axis of rotation of the said blade with an additional blade with the profile of the blade of the active turbine.

It was found that it is possible to use the pulling force of a stream smoothly flowing around the nose of a well streamlined aerodynamic profile in the areas of its flow at a relatively high speed, and to use the pushing force of the stream, overtaking another blade, made with the profile of the blade of an active turbine, also oriented across the stream, and flowing around it with a separation of jets. Thus, on symmetrically located streamlined blades installed with a different distance from the total for the blades made with different profiles, the axis of rotation of the phase of the maximum action of the force of the medium flowing on the blades and the rotation times are different, which improves the energy characteristic of the turbine and extends the frequency range of the stable turbine rotation.

Thus, the use of two types of blades with a different profile in the same orthogonal turbine made it possible to essentially combine two orthogonal turbines different in interaction with the flow running onto the turbine in one orthogonal turbine and thus create a double-acting orthogonal power unit.

In addition, the implementation of an orthogonal turbine with two semi-shafts made it possible to reduce the hydraulic resistance of the flow incident on the orthogonal turbine, which also helped to improve the energy characteristics of the orthogonal turbine.

In addition, protruding above the outer surface of the baffle blades, oriented perpendicular to the axis of rotation of the orthogonal turbine, prevent the medium, in particular liquid or gaseous medium, incident on the blades of the orthogonal turbine from flowing over the surface of the blade in directions parallel to the axis of rotation of the orthogonal turbine. As a result, an increase in the performance of the orthogonal energy unit is achieved due to a more efficient conversion of the kinetic energy of the medium flow incident on the blades of the orthogonal turbine into the mechanical rotational energy of the shaft of the orthogonal turbine, and, accordingly, an increase in the amount of electric energy generated by the electric generator.

In FIG. 1 shows an orthogonal dual-energy power unit.

In FIG. 2 schematically shows a cross section of the described orthogonal turbine.

The double-acting orthogonal power unit contains an orthogonal turbine 1 with one or more aerodynamic profile blades 2 (one aerodynamic profile blade is shown in FIG. 1) installed by means of a traverse 3 on the end half shafts 4, and an electric generator 5, the shaft of which is connected to one of the half shafts 4 orthogonal turbine.

The half-shafts 4 are coaxial, and the blade or blades of the aerodynamic profile 2 and the axis of the half-shafts 4 are oriented across the stream running onto the orthogonal turbine 1.

Each blade 2, made with an aerodynamic profile, is equipped symmetrically with respect to the axis of rotation 6 of said blade 2, a blade 7 with a profile of a blade of an active turbine, also oriented transverse to the flow running on the orthogonal turbine 1, and located from the axis of rotation 6 of the blade 2, made with an aerodynamic profile at a distance (R / 3 in Figs. 1 and 2) of 0.35 to 0.5 from the distance (R in Figs. 1 and 2) at which a blade with an aerodynamic profile 2 is located from the axis of rotation 6 all blades 2 and 7 are made with protruding and over the outer surface of the blade 2 and 7 partitions 8 oriented perpendicular to the rotational axis 6 orthogonal to the turbine 1.

The blades 2 and 7 are preferably made on a helical line.

The blades 2 and 7 are preferably made with a straight or arcuate chord, curved along the path of the blades 2 and 7 around the axis of rotation 6 (Fig. 2 shows the blades 2 and 7 with an arcuate chord).

An orthogonal turbine may be provided with at least one additional blade (not shown in the drawings) made with an aerodynamic profile and provided symmetrically with respect to the axis of rotation of the said blade with an additional blade (not shown in the drawings) with a blade profile of the active turbine.

Orthogonal energy unit of double action works as follows.

Under the action of a flow of a medium running on the blades 2 and 7 of the orthogonal turbine 1, for example, a stream of water, the blades 2 and 7 begin to rotate. As a result of the rotation of the blades 2 of the orthogonal turbine 1, its rotation is transmitted to the half-shafts 4 and, at least, from one of the half-shafts 4 to the shaft of the electric generator 5 and the latter begins to generate electrical energy, which is transmitted via a cable (not shown) from the electric generator 5a to the consumer.

The present invention can be used to create environmentally friendly power plants.

Claims (4)

1. Double-acting orthogonal power unit, comprising an orthogonal turbine with one or more aerodynamic profile vanes mounted by traverses on the end half shafts, and an electric generator, the shaft of which is connected to one of the half-shafts of the orthogonal turbine, the half shafts being aligned and the blades and axes of the half shafts oriented transversely to the flow running onto the orthogonal turbine, characterized in that each blade made with an aerodynamic profile is provided symmetrically with flax axis of said blade with a blade profile of the active turbine blade, also oriented transverse to the flow running on the orthogonal turbine, and located from the rotation axis of the blade made with the aerodynamic profile at a distance of 0.35 to 0.5 from the distance at which located from the axis of rotation of the blade with an aerodynamic profile, and all the blades are made with protruding baffles above the outer surface of the blades, oriented perpendicular to the axis of rotation of the orthogonal turbine. 2. Orthogonal power unit according to claim 1, characterized in that the blades are made along a helical line. 3. The orthogonal energy unit according to claim 1, characterized in that the blades are made with a straight or arcuate chord, curved along the path of movement of the blades around the axis of rotation. 4. The orthogonal power unit according to claim 1, characterized in that the orthogonal turbine is provided with at least one additional blade made with an aerodynamic profile and provided symmetrically with respect to the axis of rotation of the said blade with an additional blade with the profile of the blade of the active turbine.

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