RU2688623C2 - Water-wind engine - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to water-wind power engineering. Water-jet engine includes a body mounted on support-rotary axle 2 with guide flap-splitter 3, working shafts with blades 6 and a consumer drive shaft, a consumer shaft drive mechanism connecting the working shafts and the consumer drive shaft. Blades 6 of one working shaft are arranged without contact with blades 6 of another working shaft. Flared end flap 3 is made in the form of two planes connected at an acute angle, facing the flow with a vertex. Axis 2 is located behind inlet section of funnel-splitter 3. Blades 6 are made flat and fixed on each working shaft with eccentricity. Drive mechanism of the consumer shaft is made in the form of one branch, which includes a chain and "parasitic" sprocket, and is intended for provision of synchronous rotation of working shafts in opposite directions.EFFECT: invention is aimed at providing possibility to use engine with high degree of efficiency.1 cl, 6 dwg

Description

The invention relates to water power engineering, in particular to engines that use the energy of water or wind to generate mechanical energy in various fields of technology, in particular, in the power industry to drive an electric generator.

Known installation for the use of wind energy at the request of Germany No. 2955560, class. F03D 3/02, 1980, containing wind wheels with blades, mounted in tiers one above the other and next to each other with the possibility of rotation on common vertical axes.

However, such installations for using wind energy have a number of disadvantages: - automatic orientation to the wind using floats and wave energy is possible only if there is a water surface, and the sluggish movement of the floats cannot provide a sufficiently fast reorientation to the changed wind direction, and this reduces wind efficiency engine;

- wind wheels located next to each other reduce the efficiency of the wind engine, since the wind wheel that receives the wind first cuts it in front of the wind engine behind it;

- the blade of the wind wheel in the area of the wind, overcoming the resistance of the spring, rotates at the hinge, and getting into the area protected from the wind by the wind-guiding device returns to its original position, and this happens with each turn of the wind wheel and is accompanied by shock, vibration and rapid wear of the hinge, springs and blades.

Known wind engine according to the patent of the Russian Federation No. 2006970, cl. F03D 3/00, 1980, containing placed in tiers in the support frames and mounted on two vertical kinematically interconnected axes of the windwheel with blades, a vertical mast located symmetrically with respect to the axes of the windwheels, with a mechanically driven platform installed on it, and an orientation device, in order to increase efficiency, the orientation device is made in the form of two vertical planes connected at an acute angle with the apex directed to the wind, and is provided with vertical posts that are articulated windwheels with supporting frames that can be moved in a horizontal plane, with horizontal frames connected in pairs by tension springs, and the mast has a lower ball heel and upper ball bearing, the mechanical drive contains an inertial flywheel mounted coaxially with the mast, and a counter-rotating transducer of the windwheel into a unidirectional , made in the form of a pair of cylindrical gears.

However, the design of the engine does not allow for the efficient use of the wind flow to it. The use of water flow by the engine is not provided at all, and it is not possible.

Famous water-venting engine according to the patent of China No. 1055039, cl. F03B 1/00, 1991, adopted by the applicant for the prototype. It contains on the rotary axis a housing with a guide socket-divider, working shafts with blades housed in the housing, a consumer shaft drive mechanism connecting the working shafts and the consumer drive shaft. The working shafts are arranged parallel to each other, and the reverse zones of the blades of the working shafts are combined into one reverse zone. Moreover, the drive mechanism of the consumer’s shaft is designed to provide synchronous rotation of the working shafts in opposite directions and transfer the rotation to the consumer’s drive shaft.

The known invention relates to devices for the generation of electrical energy using tides of rivers and natural wind, the purpose of which is to create a device for the natural generation of electrical energy by the natural wind, which uses the tidal natural wind of the river.

However, this design of the device is not very effective due to the fact that the pivot axis is placed in front of the device, the blades of the working shafts are spaced apart from each other and do not overlap the working areas, the drive shaft of the consumer is made of two branches.

The technical problem of the claimed invention is the need to create an engine of such a design that would allow its use using either wind flow or water flow, while using an engine with a high degree of efficiency, for example, as an alternative source for generating electrical energy.

The problem is solved by the fact that in the proposed solution containing a housing mounted on a rotary axis with a guide socket-divider, working shafts with blades and a consumer drive shaft are placed in the housing, while the blades of one working shaft are placed without contact with the blades of another working shaft , the drive mechanism of the consumer’s shaft, connecting the working shafts and the consumer’s drive shaft, the guide socket-divider is made in the form of two planes connected at an acute angle, with its tip facing the flow y, and the rotary axis is located behind the inlet section of the guide socket-divider, the blades are flat and fixed on each working shaft with eccentricity, the drive mechanism of the consumer’s shaft is one branch, which includes a chain and a "parasitic" sprocket, and is intended , including, for ensuring synchronous rotation of working shaft in the opposite directions.

In addition, the pivot axle is placed vertically, and the body is fixed on it so that the working shafts are placed in the case vertically and parallel to the supporting and turning axis, or the working shafts are placed in the case horizontally and perpendicularly to the supporting and turning axis.

The technical result from the use of the present invention is that the engine is obtained with the same high degree of effective use from wind flow and water flow to generate electrical energy for various consumers, for example, to provide electricity to country houses and cottages.

FIG. 1 is a front view of a water jet engine;

in fig. 2 shows section A-A in FIG. 1 with the placement of the working shafts and blades;

in fig. 3 - kinematic diagram of the connection of the working shafts - the mechanism of the drive shaft of the consumer;

in fig. 4 - a variant of the horizontal operating position of the engine when it is used;

in fig. 5 - variants of the vertical operating position of the engine when it is used;

in fig. 6 is a variant of an example of using a wind power engine placed in a stream of an aqueous medium.

A wind-powered engine consists of a carrying case 1, which is mounted on a supporting-turning axis 2 and containing a guide socket-divider 3, which is made in the form of two planes connected at an acute angle, with its tip facing the stream. In the housing 1 there are working shafts 4 and 5 with blades 6. The blades 6 are made flat and rigidly fixed on the working shafts 4 and 5, which ensure the operation of the engine without noise, shock and vibrations. Moreover, the blades 6 are fixed on each working shaft 4 and 5 with eccentricity "e". In this case, the blades 6 of one working shaft are placed without contact with the blades 6 of another working shaft. Namely, the blades 6 are oriented in space in the form of engagement without contact, and the rotation of each working shaft is carried out by its own air or water flow, with each working shaft 4 and 5 rotating independently of the other.

The pivot axis 2 is located behind the inlet section of the guide socket-splitter 3, unlike the prototype, where it is placed in front of the socket, which allows the body 1 with the working shafts 4 and 5 to rotate with the least resistance. a water-borne engine, namely, in the form of a “weather vane”, makes it easy to orient its body 1 in the direction of air flow and to achieve the most complete use of its energy.

On the outer side of the housing 1 on the working shafts 4 and 5 are installed on the same diameter sprocket 7 and 8, which are kinematically connected by means of chain 9 and "parasitic" sprocket 10 with the tension system and form the drive mechanism of the consumer 11, connecting the working shafts 4 and 5 and consumer drive shaft 11.

Moreover, the consumer’s drive mechanism, unlike the prototype, where such a mechanism is represented as two branches, is made as a single branch, which includes a chain 9 and a “parasitic” sprocket 10, and is designed to provide simultaneous rotation of the working shafts 4 and 5 in opposite hand and avoid touching the blades 6 between themselves in the area of reverse, as well as the transfer of rotation to the drive shaft of the consumer 11. Chain 9 in this mechanism is a synchronizing element, since the synchronization of the shafts depends on the pitch of chain 9.

Instead of a noisy chain transmission, it is permissible to use gear pulleys and a double-sided flat-toothed belt. This transfer does not require lubrication.

The pivot axis 2 is always placed in a vertical position, however, the housing 1 can be fixed on it so that the working shafts 4 and 5 can be placed in the housing 1 vertically and parallel to the supporting rotary axis 2, or the working shafts 4 and 5 can be placed in the housing 1 horizontally and perpendicular to the rotary axis 2.

In the case of placing the engine in the water, it is made with the possibility of fixation in the water flow by means of anchors 12 or stretch marks 13.

Zones of the return stroke of the blades 6 of the two working shafts 4 and 5 are combined into one zone of the reverse stroke in order to reduce the dimensions of the engine, add up the speeds of rotation of the blades and, as a result, increase the efficiency of the engine. In this case, the blades 6 of each working shaft 4 and 5, placed in planes that are offset from the center of rotation of the working shaft 4 and 5 by the value of eccentricity "e", due to this eccentricity "e", create a shoulder for the initial starting torque, contributing to a smooth the beginning and further smooth rotation of the blades 6.

Vautovatov engine works as follows.

The work of the wind-driven engine is based on the conversion of the kinetic energy of the air or water flow into the mechanical energy of rotation of the working shafts, which have blades evenly spaced around the circumference of the shaft.

The engine is exposed to meet the flow of air or water made in it with a guide socket-divider 3 so that the stream enters the engine housing 1 as much as possible, and the supporting-swivel axis 2 minimally compensates for minor deviations of this stream, directing it to the socket-splitter 3. Designed as two planes connected at an acute angle, facing the top of the stream, the socket-splitter 3 divides it into two streams with more concentrated jets, which deviate to the side, on the blades of the working shafts 4 and 5, pr acquire a speed exceeding the speed of a free flow and increase the efficiency of its energy.

The flow in the socket-splitter 3 of the housing 1 is compacted, due to which it increases its speed in the narrow part of the housing 1. Here, the driving mass of the stream presses on the blades 6 and they begin to rotate in different directions the working shafts 4 and 5. However, the consumer drive shaft 11 or the “parasitic” sprocket 10 rotates in one direction, summing up the forces from the working shafts, thanks to the drive mechanism of the consumer shaft, synchronizing the rotation of the working shaft in opposite directions. The implementation of the hollow square profile of the working shafts 4 and 5 for easy mounting of the blades 6 and the displacement of the point of application of the flow pressure from the center of rotation by the eccentricity value "e" increases the sensitivity of the beginning of the movement of the blades 6. There is a smooth rotation of the working shafts 4 and 5 without jerks, because the maximum load alternately perceive the blades 6 of the shaft 4 and the shaft 5, which contributes to the orientation of the engine to the flow front.

Due to the synchronous rotation of the working shafts 4 and 5, their total rotation can be represented as the rotation of one shaft from the blades 6, which divide the rotation circle into eight identical sectors. The zone of reverse motion of the blades 6 does not perceive the pressure of the flow, since it is closed by the shield of the socket-distributor 3 and there is no reason for the braking of the rotation of the blades 6 from the oncoming flow in the reverse zone.

The consumer drive shaft 11 included in the drive circuit is also driven, for example, by the electric generator. And the electric generator converts this rotational movement into electrical energy, which it provides, for example, country houses or cottages.

The power of this engine can be determined from the formula: N = psv ^3/2, where

p is the density of the moving mass flow in the pressure zone on the blade;

s - the area from which the flow is collected in the socket-divider;

v - flow rate in the zone of pressure on the blade.

It is seen that the result has a cubic dependence on the flow velocity in the working area, which is created by the socket splitter 3, whose presence in the design is justified. Taking into account that liquids are practically not compressed, in an aquatic environment, the efficiency of the engine immediately rises 800 times, since the density of water and air differs 800 times under normal conditions, which cannot be ignored.

To operate the engine in a stream of water, it is placed perpendicular to this stream of water, for which purpose the engine is fixed with braces 13 or anchors 12. And to change the speed and direction of flow do not affect the operation of the engine, it is placed on the pontoon, where the workers also synchronize shafts.

The use of the proposed technical solution allowed the creation of a highly efficient, universal engine operating using both wind flow and water flow, which can be used as an alternative source for generating electrical energy.

A more complete use of wind and water energy and improving the efficiency of the proposed engine compared with the known solutions is achieved as follows.

1. The implementation of the guide socket-divider in the form of two planes connected at an acute angle, facing the top of the stream.

2. Fixing the case on the pivot axis and the pivot axis on the guide socket divider, namely, making the engine in the form of a “vane”, which makes it easy to orient the case in the direction of flow and to achieve the most complete use of its energy.

3. Flat, rigidly fixed blades of the working shafts ensure engine operation without noise, shock and vibration.

4. Fixing the blades on each working shaft with eccentricity.

5. Orientation in space of the blades of one working shaft relative to another in the form of engagement without contact, and with the water-air layer.

6. The implementation of the drive mechanism of the consumer's shaft as a single branch.

The design of the engine involves its manufacture on universal machines, since the blades are made flat and do not have shaped surfaces.

In addition, the windmill engine can be made of different sizes for ease of installation and use in the transmission of mechanical rotational energy to different consumers, both for generating electrical energy and for rotating, for example, a screw when installing the engine in watercraft.

Claims (2)

1. A wind-powered engine containing a housing mounted on a rotary axis with a guide socket-divider, working shafts with blades and a consumer drive shaft placed in the housing, while the blades of one working shaft are placed without contact with the blades of another working shaft, the consumer drive shaft connecting the working shafts and the consumer's drive shaft, characterized in that the guide socket-divider is made in the form of two planes connected at an acute angle, with the tip facing the flow, and the supporting turn the rear axle is located behind the inlet cross section of the guide socket-divider, the blades are flat and fixed on each working shaft with eccentricity, the drive shaft of the consumer is made as a single branch, which includes a chain and a “parasitic” sprocket, and is also intended to ensure synchronous rotation of the working shaft in opposite directions. 2. The engine under item 1, characterized in that the pivot axle is placed vertically, and the body is fixed on it so that the working shafts are placed in the case vertically and parallel to the supporting and turning axis, or the working shafts are placed in the case horizontally and perpendicularly rotary axis.

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