CZ308256B6 - Precession liquid turbine - Google Patents

Abstract

The precession fluid turbine comprises a liquid reservoir (8) with a liquid inlet (3) and a liquid outlet (4). A nozzle (1) is in the base plate (13) in the liquid reservoir (8) between the liquid inlet (3) and the liquid outlet (4). In the nozzle (1) there is a bladeless rolling rotor (2) formed by a rotational body with a shaft (9). The rolling rotor (2) is mounted on a holding device (6) to allow the circular rotation of the rotor (2) over the inner wall of the nozzle (1). Above the rotor (2) there is an air chamber (10) which is open at its lower end. The shaft (9) of the rotor (2) extends into the air chamber (10). In the air chamber (10) an electric generator (7) is arranged, which is connected by a mechanism (5) to the shaft (9) of the rotor (2). The power generator (7) is in the air chamber (10) in a cage (12) attached to the base plate (13) of the nozzle (1).

Description

Precession fluid turbine

Field of technology

The invention relates to a precession fluid turbine comprising a fluid reservoir with a fluid inlet and a fluid outlet, and in the fluid reservoir a nozzle is arranged in the base plate between the fluid inlet and the fluid outlet and a bladeless rolling rotor is formed in the nozzle. shaft, the rolling rotor being mounted on a holding device to allow the rotor to rotate on the inner wall of the nozzle and an air chamber arranged above the rotor, which is open at the lower end, and the rotor shaft extending into the air chamber, an electric generator being arranged in the air chamber. current, which is connected by a mechanism to the rotor shaft.

Prior art

Fluid machines are known which have a stator with a liquid inlet and a liquid outlet, and a bladeless rolling rotor formed by a rotating-shaped body is mounted in the stator on a holding device. The holding device is adapted to allow the rotor to rotate in rotation along the inner wall of the stator. After the fluid is introduced into the stator, the flowing fluid causes the rotor to touch the inner wall of the stator and begins to roll in a circular motion along the inner wall of the stator. Thus, at least part of the rotor shaft performs a precessional movement. Such machines are therefore also sometimes called precession machines.

Czech patent CZ 284483 and European patent EP 1015760 B1 disclose a rolling fluid machine consisting of a fluid reservoir provided with an inlet and at least one outlet nozzle, wherein at least one rolling rotor formed by a rotating body is mounted on the holding device in the region of the outlet nozzle. The rolling rotor is mounted so that it can roll freely along the inner wall of the outlet nozzle.

Fluid machines according to the European patent EP 1082538 B1, according to the Czech patents CZ 294708 and CZ 302361 and according to the Czech utility models CZ 7606, CZ 17908 and CZ 18890 work on the same principle.

A Czech patent CZ 306587 discloses a precession fluid turbine, comprising a fluid reservoir with a fluid inlet and a fluid outlet. A stator nozzle is arranged in the liquid reservoir between the liquid inlet opening and the liquid outlet opening, and a bladeless rolling rotor formed by a rotating-shaped body is arranged in the stator nozzle. The rolling rotor is mounted on a holding device to allow the rotor to roll in rotation along the inner wall of the stator nozzle. The rolling rotor is connected by a mechanism to an electric current generator. An air chamber is arranged in the liquid reservoir above the rotor, which is open at the lower end, and the rotor shaft extends into the air chamber. An electric current generator is arranged in the air chamber, which mechanism is connected to the rotor shaft by a mechanism.

When connecting the electricity generator to the known rolling, resp. For a precession turbine, it is important for the correct function of such a set to correctly adjust the relative position of the rotor shaft and the generator shaft. None of the known constructions solves this problem.

The essence of the invention

This problem is solved by a precession fluid turbine, comprising a fluid reservoir with a fluid inlet and a fluid outlet, and in the fluid reservoir, a nozzle is arranged in the base plate between the fluid inlet and the fluid outlet and the nozzle is arranged in the base plate.

A bladeless rolling rotor is formed, formed by a rotating body with a shaft, the rolling rotor being mounted on a holding device for enabling the rotor to rotate in rotation along the inner wall of the nozzle and an air chamber arranged above the rotor, which is open at the lower end and the air chamber is connected to the rotor shaft, an electric current generator is arranged in the air chamber, which mechanism is connected to the rotor shaft by a mechanism, the essence of which consists in the electric current generator being stored in the air chamber in a cage fixed to the nozzle base plate. .

The design of the precession fluid turbine according to the invention makes it possible to easily adjust the relative position of the nozzle, the rotor shaft and the generator shaft by moving the cage or by moving the generator in the cage.

To make positioning even easier, adjustable couplings are arranged between the cage and the base plate of the nozzle and / or the electric current generator is fixed in the cage by means of a centering mechanism.

According to preferred embodiments, the cage has a cylindrical shape and / or the diameter of the cage on the side facing the nozzle is larger than the diameter on the opposite side.

According to another preferred embodiment, the holding device is attached to the cage.

According to yet another preferred embodiment, the air chamber is mounted on a cage and / or attached to a liquid reservoir.

Explanation of drawings

Fig. 1 schematically shows a first embodiment of a precession fluid turbine according to the invention with a height-adjustable cage. Fig. 2 is an example of an embodiment of a cage. Fig. 3 is a second embodiment of a precession fluid turbine according to the invention with a graduated cage diameter. Fig. 4 is a third embodiment of a precession fluid turbine according to the invention with a rotor suspended from a cage. Fig. 5 is a fourth embodiment of a precession fluid turbine according to the invention with an air chamber suspended from a frame. Fig. 6 is a fifth embodiment of a precession fluid turbine according to the invention with a reduced fluid reservoir.

Examples of embodiments of the invention

The precession fluid turbine according to Fig. 1, comprising a fluid reservoir 8 with a fluid inlet 3 and with a fluid outlet 4. In the liquid reservoir 8, a base plate 13 is arranged between the liquid inlet opening 3 and the liquid outlet opening 4, and a nozzle L is arranged therein. A bladeless rolling rotor 2 with a shaft 9 is arranged in the nozzle 1. The rolling rotor 2 can have any rotational shape.

The rolling rotor 2 is mounted on a holding device 6. The holding device 6 can be formed by any known mechanism which allows the rotor 2 to be rolled on the inner wall of the nozzle 1. In the embodiment of Fig. 1 the holding device 6 is formed by a rod support which is firmly connected with the bottom of the rotor 2 and on the opposite side it is terminated by a ball joint mounted in a support (not shown).

Above the nozzle 1, a cage 12 is arranged on the base plate 13, which carries an electric current generator 7.

For the purposes of this application, cage 12 means any structure that allows the flow of liquid with as little loss as possible.

-2GB 308256 B6

An example of such a cage 12 is shown in Fig. 2. The cage 12 has a cylindrical shape and is welded from metal bars with a diameter of 10 mm. The vertical bars of the cage 12 are connected to the base plate 13 of the nozzle 11 via adjustable couplings 14 which allow the height of the cage 12 to be adjusted. At the top, the cage 12 has a centering mechanism 15 for connecting an electric current generator 7.

Any known height adjustment mechanism can be used as the adjustable couplings 14. Similarly, the centering mechanism 15 may be formed by any known mechanism for centering the electric current generator 7.

An air chamber 10 is mounted above the cage 12 by means of spacers 16, which is open at the lower end and is at least partially immersed in the liquid, so that it operates on the principle of a known diving bell or caisson.

The shaft 9 of the rotor 2 extends into the air chamber 10, which is connected by a mechanism 5 to the shaft 11 of the electric current generator 7. The electric current produced by the generator 7 is dissipated by electric current conductors (not shown).

The mechanism 5 connecting the rolling rotor 2 to the electric current generator 7 can be formed by any known mechanism for converting the precise movement of the shaft 9 of the rolling rotor 2 to the rotational movement of the shaft 11 of the electric current generator 7, for example by a schematically shown crank mechanism.

During assembly, the optimal mutual position of the nozzle 7, the shaft 9 of the rotor 2 and the shaft 11 of the generator 7 can be set thanks to the interaction of the adjustable couplings 14 and the centering mechanism 15.

A liquid flows into the liquid reservoir 8 through the inlet opening 3, which flows through the nozzle 1 and flows out through the outlet opening 4. The flowing liquid causes the rotor 2 to start rolling in a circular manner along the inner wall of the nozzle 1 and the axis 9 of the rotor 2

Since a substantial part of the shaft 9 of the rotor 2 and the complete mechanism 5 move in the air chamber 10, their movement is not inhibited by the flowing liquid. In addition, the electric power generator 7 is arranged outside the liquid and thus does not have to be too expensive to protect against the ingress of water, even if it is located below the water surface.

The embodiment according to FIG. 3 differs from the embodiment according to FIG. 1 in that the diameter of the cylindrical cage 12 is larger on the side facing the nozzle 1 than the diameter on the opposite side and the air chamber 10 rests with its lower end on the cage 12. In this simpler embodiment it does not have a cage at the lower end of the adjustable coupling 14, but even this embodiment allows a substantially simpler positioning of the electric power generator 7 than hitherto known embodiments.

It will be apparent to those skilled in the art that in addition to the circular cross-section described, the cage 12 may have substantially any cross-section, such as square, triangular, and the like.

The other functions of this embodiment and all the embodiments described below are analogous to the function described with reference to the embodiment according to Fig. 1.

The embodiment according to FIG. 4 differs from the embodiment according to FIG. 1 by the type of holding device 6. This is because the rotor 2 is not supported but is suspended on a holding device 6 which is fixed to the cage 12. The specific type of holding device 6 is not described because use any known mechanism which will allow the rotor 2 to rotate on the inner wall of the nozzle 1.

The embodiment according to FIG. 5 differs from the embodiment according to FIG. 3 only in that the air chamber 10 is not supported on the cage 12, but is suspended by hinges 18 on the frame 17 on the upper side of the liquid container 8.

-3 CZ 308256 B6

The embodiment according to Fig. 6 is a so-called "pressure turbine", i.e. the liquid is supplied to the liquid reservoir 8 under pressure through the inlet opening 3, the turbine being vertically situated below the water surface and the outlet opening 4 located above the inlet opening 3. is substantially the same as in the embodiments described above. They differ only in the location of the holding device 6 and in the design of the liquid reservoir 8, which is substantially smaller and is sometimes referred to as a distributor. The liquid reservoir 8 is installed on the underside of the turbine and the water from it advances upwards to the rotor 2. Both the cage 12 and the air chamber 10 are arranged outside the liquid reservoir 8. The holding device 6, which allows the rotor 2 to rotate on the inner wall of the nozzle 1, is in this case the articulation of the shaft 9 of the rotor 2 and the shaft 11 of the generator 7. The stabilizing baffle 19 serves to prevent swirling of the liquid behind the rotor version ”still has considerable energy and could enter the air chamber 10. The stabilizing baffle 19 is installed inside the cage 12 at the level of the lower edge of the air chamber 10 and closes the entire inner space of the cage 12 with its surface. a bore 20 is formed in the partition 19, the diameter of which is at most twice as large as the diameter of the shaft 9 of the rotor 2.

Claims (6)

PATENT CLAIMS A precession fluid turbine, comprising a fluid reservoir (8) with a fluid inlet (3) and a fluid outlet (4) and in the fluid reservoir (8), is arranged between the fluid inlet (3) and the fluid outlet (4) in a nozzle (1) is arranged in the base plate (13) and a bladeless rolling rotor (2) is arranged in the nozzle (1), formed by a rotating body with a shaft (9), the rolling rotor (2) being mounted on a holding device (6) to allow In the circular rolling of the rotor (2) along the inner wall of the nozzle (1) and above the rotor (2), an air chamber (10) is arranged, which is open at the lower end and the shaft (9) of the rotor (2) extends into the air chamber (10). , wherein an electric current generator (7) is arranged in the air chamber (10), which mechanism is connected by a mechanism (5) to the shaft (9) of the rotor (2), characterized in that the electric current generator (7) is in the air chamber ( 10) stored in cage (12) fixed to the base plate (13) of the nozzle (1). Precession fluid turbine according to claim 1, characterized in that adjustable couplings (14) are arranged between the cage (12) and the base plate (13) of the nozzle (1). Precession fluid turbine according to claim 1 or 2, characterized in that the electric current generator (7) is mounted in the cage (12) by means of a centering mechanism (15). Precession fluid turbine according to any one of the preceding claims, characterized in that the cage (12) has a cylindrical shape. Precession fluid turbine according to any one of the preceding claims, characterized in that the diameter of the cage (12) on the side facing the nozzle (1) is larger than the diameter on the opposite side. Precession fluid turbine according to any one of the preceding claims, characterized in that the holding device (6) is attached to the cage (12). Precession fluid turbine according to any one of the preceding claims, characterized in that the air chamber (10) is mounted on a cage (12) and / or is attached to a fluid reservoir (8). 6 drawings