RU139031U1 - DEVICE FOR RECYCLING ENERGY ENVIRONMENT - Google Patents

Abstract

1. A device for utilizing the energy of a flowing medium, characterized in that it contains a tapering channel open from two ends, in which a blade machine is located; the blades of the spatula machine are provided with inlet and outlet edges, as well as one convex side surface, while the blades are bent in transverse projection and tapering in thickness from the inlet to the trailing edge; the channel inlet is equipped with a diffuser, the channel outlet is equipped with an expanding nozzle. 2. The device for utilizing the energy of the flowing medium according to claim 1, characterized in that the blades of the spatula machine contain one concave side surface. The device for utilizing the energy of a flowing medium according to claim 1, characterized in that the blades of the spatula machine contain one flat side surface. The device for energy recovery of the flowing medium according to claim 1, characterized in that the channel is made conical. The device for energy recovery of a flowing medium according to claim 1, characterized in that the blades are provided with an open cavity located on the side surface opposite the convex surface.

Description

The technical solution relates to the field of small energy, and in particular to means for converting the energy of flowing water into electrical energy and can be used for installation in river channels.

The well-known "VORTEX DIRECT HYDROTURBINE FOR USING ENERGY OF RIVERS AND TIDES" consisting of a hollow supporting shaft-cylinder with adjustable ballast, allowing the hydraulic turbine to fully immerse in water or float out of it to the surface on which are attached to the half-cylinder blades with a ballast providing neutral buoyancy to a hydraulic turbine, characterized in that several disks or flat cylinders with p are mounted uniformly along the bearing shaft-cylinder along its length on the rim, in which the blades are attached, having the form of the side surface of a hollow cylinder, cut off by a longitudinal plane, so that the disks are inscribed in the inner ends of the blades, forming a free central space between the disks of the surface of the bearing shaft-cylinder and the ends of the blades, and their outer the ends, tightened by narrow hoop rings, formed a multi-vane cylinder, the bases of which are completely closed by containers with ballast, providing neutral buoyancy to the turbine, rigidly connected to the torus s the blades and the shaft-bearing hollow cylinder. The flow, passing along the C-shaped blade, both from the opposite and from the back of the turbine, creates a torque in the bend.

The closest in technical essence is the "Engine for the disposal of the current environment" according to the patent of the Russian Federation for utility model No. 109348 of 06/10/2011, published on 10/10/2011, IPC H02K 7/18, F03B 13/10, F03B 3/04. The technical solution described in the prototype consists of a submersible casing installed on the foundation at the bottom of the river, with a rigidly connected surface platform on which the chain drives from the impellers to the electric generator are located. Two impellers are installed in the underwater part of the body, and the direction of the blades is mirror-image. When the water flow moves through the impellers, a torque is created on both wheels directed oppositely to each other and, accordingly, the wheels of the turbine begin to rotate opposite to each other. The rotation of the wheels is transmitted by a chain drive to two power take-off shafts that are kinematically connected with the electric generator.

The flow of the current medium, such as water, acts on the blades of the turbo wheels. As a result, the turbowheels begin to rotate on the shaft in different directions. The rotational movement of the turbowheels is transmitted to the power take-off shafts, which are connected through gears, so that the turbowheels are kinematically rigidly connected. As a result, the turbowheels rotate synchronously and counterclockwise. Under the influence of the flow, an increased pressure is created on the “outer” plane of the turbo-wheel blade, and a reduced pressure is created on the opposite side of the blade. Thus, two zones are formed between the blades of adjacent turbowheels, one with increased pressure and the other with reduced pressure, and these zones move towards each other. At a certain distance between the blades, when meeting the zones of high and low pressure, moving counterclockwise, vortices accelerate the flow. As a result, the flow rate at the output of a pair of blades increases, and since the turbowheels rotate synchronously, this mechanism acts in an orderly manner, increasing the engine power, which, through the appropriate gear, enters the power take-off shaft and then to the electric generator.

All existing solutions utilize only the kinetic energy of the flow, which is no more than 1 kW from an area of 1 m2 of the river cross section at a flow velocity of V - 1 m / s. Existing blade design of blade machines used to utilize the energy of the fluid flow, as well as the design of the hydrogenerators themselves, are not able to provide effective selection of the potential flow energy. In addition, to date, there are no known methods associated with the use for the extraction of energy flow of blade machines in which blades with a curved cross-sectional profile are used.

The objective of the proposed technical solution is to increase the energy recovery coefficient of the current environment. In addition, the purpose of the invention is the creation of a recessed, without foundation, disembodied device for utilizing the energy of the current environment, allowing installation on rivers with any channel, while not interfering with navigation, in general, with the possibility of operation on rivers with ice.

The problem is solved by a device for utilizing the energy of the current medium, characterized in that it contains a tapering channel open from two ends, in which the blade machine is located; the blades of the scapular machine are provided with inlet and outlet edges, as well as one convex lateral surface, while the blades are made curved in the transverse projection and tapering in thickness from the inlet to the outlet edge; the channel inlet is provided with a diffuser, the channel outlet is provided with an expanding nozzle; impeller blades contain one concave lateral surface; impeller vanes comprise one flat lateral surface; the channel is made conical; the blades are provided with an open cavity located on the side surface opposite the convex surface.

The essence of the technical solution is illustrated by drawings, where in FIG. 1 - a device for utilization of energy of the current environment, in FIG. 2 is a cross-sectional profile of a blade, in FIG. 3 is a cross-sectional profile of a blade with a hook-shaped cavity.

In FIG. 1 shows a device 1 for utilizing the energy of the current medium, stream 2, channel 3, blade machine 4, impellers 5, blades 6, input edge 7, output edge 8, convex side surface 9, opposite side surface 10, diffuser 11, nozzle 12 , open cavity 13, swirl zone 14.

A device for utilizing the energy of the current environment is as follows.

The device 1 for utilizing the energy of the current medium contains a housing in which the channel 3 is open. The channel 3 is made tapering from the inlet to the outlet, i.e. the cross-sectional area of the channel gradually decreases. Optionally, channel 3 is made conical. In the channel 3 is located, a blade machine 4, containing at least one impeller 5, equipped with blades 6. The impellers 5 can be from one to four, depending on the flow rate 2, with the rotation of adjacent wheels 5 in opposite directions. The blades 6 are provided with inlet 7 and outlet 8 edges, as well as one convex, essentially upper, lateral surface 9. The profile of the blades 6 is made curved so that the output edge 8 is offset in the plane of the cross section of the blades 6 in the direction from the convex side surface 9 relative to inlet edge 7. Opposite convex 9, essentially lower, side surface 10 is either concave or flat, depending on the expected flow rate 2. Optionally, the blades 6 are provided with an open hook-shaped cross-section along a cavity 13 located on the side surface 10 opposite the convex surface 9. The impellers 5 are mounted with the possibility of transmitting rotation to a single shaft connected to the generator. The generator is optionally installed in the immediate vicinity of the device. The inlet to the channel is provided with a diffuser 11. The outlet from the channel is provided with an expanding nozzle 12.

The method of energy utilization of the current environment is as follows.

The stream 2 of the fluid is directed into the channel 3, where it is accelerated by gradually reducing the cross-sectional area of the channel 3. Then, the kinetic energy of the stream is converted into mechanical power by supplying the stream 2 to at least one impeller 5 containing blades 6. Blades 6 provided with inlet 7 and outlet 8 edges, as well as one convex, essentially upper, side surface 9. The profile of the blades 6 is made curved so that the output edge 8 is offset in the plane of the cross section of the blades 6 in the direction from the convex a flat lateral surface 9 relative to the inlet edge 7. Then, the flow 2 is slowed down. Stream 2 is optionally slowed by a sharp increase in the cross section of channel 3.

A device for energy recovery of the current environment works as follows.

The water stream at a speed of V1 is fed into the diffuser 11, where the water first increases the speed of the stream 2. Then, the stream 3 is fed into the channel 3 with a gradually decreasing cross-sectional area. Due to the narrowing of the channel 3, for example, its taper, the stream 2 is additionally accelerated to the working speed V ₂ and fed to the blades of the impeller 5. The stream falling on the blades 6 of the impeller 5 gives off potential energy P ₁ which is generated due to the difference in the flow rates above and below blade 6. The difference in flow rates 2 under and above the blade 6 is formed due to the presence in the blade 6 of one convex side surface 9 and the opposite concave or flat side surface 10.

P ₁ = C _F qV ₂ / 2S

C _F - lift coefficient, dimensionless quantity, determined experimentally; q is the density kg / m ³ ; S is the area of the blade m ² ; V - flow rate m / s

It can be seen from the equation that the greater the flux density and the difference in speeds, the greater will be the lifting force, since the denominator is a constant value.

An approximate calculation through the pressure difference, excluding the area of the blade and other forces:

P ₁ - pressure under the blade; P ₂ - pressure above the blade; V ₁ - flow rate under the blade; V ₂ - flow rate above the blade; q is the density of kg / m ³ .

At a flow velocity of V = 1 m / s, V ₁ is less than 0.5 m / s; V ₂ - 1.3 m / s

P = 845-125 = 720 kg / cm ²

720 × 9.8 = 7 kW

Then, water flow 2, due to the curved profile, as well as narrowing in thickness from the inlet to the outlet edge of the blade 6, changes direction by 45 ° –90 °, thereby giving off the kinetic energy Pk. At a high flow rate 2, a vacuum is generated under the blade 6, which will give the impeller 5 the opposite direction of rotation, to open the vacuum on the flat or concave surface of the blade 10, additional open hook-shaped cavities 13 are installed. If there are open hook-shaped cavities 13 in the blades 6, data cavities 13 reduce the flow rate 2 and form swirl zones 14.

The technical effect of the proposed technical solution is to increase the energy recovery coefficient of the current medium due to the device for energy recovery of the current medium characterized in that it contains a narrowing channel open from two ends, in which the blade machine is located; the blades of the scapular machine are provided with inlet and outlet edges, as well as one convex lateral surface, while the blades are made curved in the transverse projection and tapering in thickness from the inlet to the outlet edge; the channel inlet is provided with a diffuser, the channel outlet is provided with an expanding nozzle; impeller blades contain one concave lateral surface; impeller vanes comprise one flat lateral surface; the channel is made conical; the blades are provided with an open cavity located on the side surface opposite the convex surface.

Claims (5)

1. A device for utilizing the energy of the current medium, characterized in that it comprises a tapering channel open from two ends, in which the spatula is located; the blades of the scapular machine are provided with inlet and outlet edges, as well as one convex lateral surface, while the blades are made curved in the transverse projection and tapering in thickness from the inlet to the outlet edge; the channel inlet is provided with a diffuser; the channel outlet is provided with an expanding nozzle. 2. The device for utilizing the energy of the current medium according to claim 1, characterized in that the blades of the scapular machine contain one concave side surface. 3. The device for energy recovery of the current medium according to claim 1, characterized in that the blades of the scapular machine contain one flat side surface. 4. The device for utilization of energy of the current medium according to claim 1, characterized in that the channel is made conical. 5. The device for utilizing the energy of the current medium according to claim 1, characterized in that the blades are provided with an open cavity located on the side surface opposite the convex surface.

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