RU2148183C1 - Hydraulic set working wheel - Google Patents

Abstract

FIELD: power engineering; conversion of energy of hydraulic flow and with into electric energy. SUBSTANCE: wheel has hub and folding blades with spaces secured on hub. Blades are made of elastic material in form of cup- shaped lobes in section. External part of blade is thickened, and internal part is made in form of diaphragm. Spaces in blades are formed by channels connected by flexible collector. Collector of one blade is connected with collector of blade occupying diametrically opposite position by means of channels in hub. Channels are filled with liquid. Summary volume of channel spaces correspond to volume of two blades one of which is in folded-down position. EFFECT: increased efficiency, reliability and longevity. 4 dwg

Description

 The invention relates to hydropower, and in particular to impellers that convert the energy of hydraulic flows into electricity, and can also be used as a rotor of a wind turbine and a pump.

 Known impeller used in the damless hydroelectric G. Ozerova [1], made in the form of a drum mounted on a support with the possibility of rotation, equipped with rotary stepwise opening blades, internal and external, the axis of rotation of which are offset relative to each other by the same angle, while the outer blades are installed to ensure that the inner blades overlap inoperative position and their earlier entry into work.

 The disadvantage of this impeller is its low reliability and low efficiency, because the change in the position of the blades from a passive state to an active state occurs due to their rotation on the axes and kinematically rigid connection with the radially opposite blade. In the process of interaction of the blades with the flow, the latter perceive alternating loads, which leads to the formation of torque when the position of the blades changes, while the frequency of change in the state of the blades and their positions, as a rule, is 1 s, or even less than a second; It is known that alternating loads in combination with an aggressive environment - water lead to accelerated wear of the axis-hub system and, as a result, subsequent jamming of the blade and failure of two kinematically connected blades simultaneously with subsequent failure of the unit.

 The impeller [2] is also known, which contains a hub and radial hollow spokes attached to it with hemispherical blades equipped with elastic conical shells attached to their base with the formation of closed cavities, interconnected and filled with gas.

 The disadvantage of this impeller is the low efficiency when used in low-pressure and submerged hydroelectric power units, since the torque depends largely on the coefficient of resistance of the different sides of the blades and, due to this, creates vacuum zones in front of the blades.

 The technical result of the claimed invention is to increase reliability, durability and efficiency, as well as simplifying the design and reducing metal consumption.

 The technical result is achieved by the fact that the impeller blades are made of elastic material (for example, polyurethane) in the form of cup-shaped petals in cross section, the outer part of which is thickened and the inner part is in the form of a diaphragm, while the cavities in the blades are formed by channels interconnected elastic collector, and the collector of one blade is connected to the collector of another, occupying a diametrically opposite position, through channels made in the hub, and, in addition, the channels of the blades are filled liquid total volume of cavities corresponding to the volume of two blades, one of which is in a folded position.

The execution of the blades from an elastic material (for example, polyurethane) in the form of cup-shaped petals in cross section, the outer part of which is thickened, and the inner part in the form of a diaphragm, allows you to:
- to obtain a blade of variable elasticity with predetermined elastic characteristics, and using the flow hydrodynamics, change the profile of the blade in the process of its operation;
- change the center of mass of the rotating impeller, reduce the torque and, as a result, increase the efficiency;
- to exclude the mechanical elements of rotation of the blades: axles, bushings, levers, which in turn greatly simplifies the design of the hydraulic unit as a whole and increases the efficiency of use of the impeller;
- the implementation of the impeller of an elastic material also reduces the metal consumption of the hydraulic unit, its weight, and accordingly reduces the cost of the unit as a whole.

 The implementation of the cavities through the channels allows you to give the blade design a variable stiffness depending on the magnitude of the impact of the flow on the working surface of the blade, which is the diaphragm, while connecting with an elastic collector allows you to distribute elastic deformation over the entire surface of the blade, as well as the connection of the collectors of the blades occupying diametrically opposite positions , allows to ensure the flow of fluid from the cavity of the blade, which is under the action of the maximum distributed the flow load on the diaphragm of the blade, which leads to its flow from a stressed - unfolded blade through the channels into a rolled one, resulting in increased pressure in the cavity of the other blade, which leads to the stress state of the passive blade and as a result of its opening and subsequent storage in the open form, but already under the influence of an ever-increasing distributed load from the flow and forces that counteract spontaneous folding arising from the decomposition of forces acting on the open blade, but whose axis ditsya in parallel flow plane (decomposition diagram of forces is shown in Fig. 1).

 Filling the channels with liquid with the total volume of cavities corresponding to the volume of two cavity of the blades, one of which is in a folded position, allows automatic pressure redistribution in the cavities under the action of the pressure of the diaphragm of the loaded blade depending on the position relative to the flow axis.

 The set of design features of the blades provides a variable nature of their interaction with a change in hydraulic resistance and hydraulic radius, because the blade in the expanded state with a contact area two or more times larger than the conjugated folded blade exhibits predominantly inductive resistance due to the span of the blade and a cup-shaped surface in contact with the flow, excluding friction resistance; the total effect is local lifting force, which gives a non-zero projection on the direction of the total incoming flow, while the diametrically opposite blade, in a folded position, with a profile of a cylindrical surface and provides the flow with minimal inductive resistance combined with friction resistance, which in total significantly less forces acting on the opposite side relative to the axis of rotation. The difference in the resistance forces acting relative to the axis of rotation leads to the appearance of a torque. These technical solutions can improve the efficiency of power take-off from the stream, especially at low speeds, without the formative elements of the stream.

 Thus, a comparative analysis with the prototypes of the claimed invention allows us to conclude that the latter meets the criterion of "novelty."

 In addition, a comparison of the claimed invention with other technical solutions shows that it follows from them in an unobvious manner, which provides it with the criterion of "inventive step".

 The application of this invention in the field of energy conversion of hydraulic air and gas flows into electrical energy allows us to conclude that it meets the criterion of "industrial applicability".

The invention is illustrated by the following drawings, where:
in FIG. 1 - impeller;
in FIG. 2 is a section AA of FIG. 1;
in FIG. 3 is a section BB of FIG. 2;
in FIG. 4 is a section BB of FIG. 3.

 The impeller consists of a hub 1 mounted stationary on the shaft 2; on the hub, blades 3 are also fixedly mounted, made of a cup-shaped shape, the outer part of which is thickened and the inner part is in the form of a diaphragm, while through the channels cavities 4 are formed, connected by an elastic collector 5, in the hub there is a channel 6 closed by a sealed lid 7, and the collector of one cavity is connected to another collector of the blade, which occupies a diametrically opposite position.

 The impeller operates as follows.

In the initial position, all the blades have an intermediate state, since the fluid pressure in the cavities is averaged equal and the same, then their shape is half-closed. When a fluid or gas flow is applied, large loads on the blades in a plane perpendicular to the flow are perceived as cup-shaped to the flow, since the flow does not flow around it as opposed and does not bend it at an angle α, but, on the contrary, the flow forces lead to the opening of the blade and increasing the distributed load on the diaphragm surface of the bowl, and the result is a torque, and maximum fluid pressure in the swivel position of the blade 90 ^o lead to displace fluid from the cavity 4 to the cavity Lop STI which occupies a diametrically opposite position, through passage of the hub 6 and hence the vane disclosure the time of its entrance to the active zone of interaction with the flow.

 The rotational moment is transmitted to the shaft and then to the electric generator.

 The interaction pattern of the blades with the flow and their relative position can be represented by a table that takes into account the position of the blades in accordance with FIG. 1 and the designation of the quarters, marked with numbers with asterisks, while the closed position of the blade corresponds to the sign “-”, and the open “+”, the arrows show the direction of fluid movement from the cavity of one blade to the cavity of the other in accordance with the nature of the interaction with the flow and the magnitude of the perceived load .

 The folded position of one blade and the unfolded position of the other leads to a change in the center of mass, and the wheel, under the action of the flow, tends to take a more stable position, which leads it to rotational motion and, naturally, to the appearance of torque.

 During the interaction of the blade with the flow in a position parallel to the axis of the blade and the direction of flow, the resulting force counteracts the spontaneous folding of the blade, which is shown in FIG. 1.

 Thus, the use of the proposed impeller allows you to increase the efficiency of power take-off from the stream, providing the possibility of using low-pressure flows to generate electricity, while it becomes possible to use hydraulic units in the damless version year-round, in addition, the use of the proposed impeller in hydraulic units eliminates the device to form and direct the flow. The use of the impeller is also possible in wind turbines and gas transfer systems.

List of references
1. USSR patent N 1836586, F 03 B 13/00, 1993.

 2. USSR patent N 1449698, F 03 B 7/00, 1989.

Claims (1)

 Impeller driven by fluid or gas flows, containing a hub, folding blades with cavities fixed on it, characterized in that the blades are made of elastic material (for example, polyurethane) in the form of cup-shaped petals in cross section, the outer part of which is thickened and the inner - in the form of a diaphragm, while the cavities in the blades are formed by channels interconnected by an elastic collector, while the collector of one blade is connected to the collector of another, which is diametrically opposed The emergency position, by means of channels made in the hub, in addition, the channels of the blades are filled with liquid with a total volume of cavities corresponding to the volume of two blades, one of which is in a folded position.

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