RU2392485C1 - Fluid medium energy using device - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: invention refers to hydropower engineering and can be used for supply of process water to production plants. Fluid medium energy using device includes housing 1, hydraulic turbine and volumetric pump 5. Device is equipped with flow boosters 7 and 8 located in vertical plane parallel to the device axis symmetrically on external part of housing 1 and made in the form of tubes with cross section enlarging towards edges, wings 19 located on external part of housing 1 and installed on the shaft located in horizontal plane perpendicular to the device axis, as well as with differential pressure gauge installed in housing 1, opposite cavities of pressure gauge by means of piezometric pipes are connected to internal cavities of flow boosters 7 and 8. Diaphragm of pressure gauge is connected by means of the rod having the possibility of back-and-forth movement to the disc rigidly installed on the shaft.

EFFECT: increasing device efficiency and providing its operation in conditions of winter period.

Description

The invention relates to the field of hydropower and can be used to supply industrial enterprises with process water.

A known power unit, driven by a fluid flow, containing a frame mounted on floats, generators coaxially mounted on the frame, the shafts of which are located across the flow, the impellers with cylindrical blades, with the impellers placed on either side of each of the generators with the formation rows along and across the flow, the shafts of the wheels are parallel to the shafts of the generators and are rigidly interconnected in the transverse rows, and in the longitudinal rows with the generator shaft of their row by means of a belt drive and with pulleys, in the transverse rows, the pulleys of the wheels located relative to the generator downstream of the generator are made of a smaller diameter than the pulleys of the wheels located closer to the stream (see AS No. 1661469, IPC F03B 13/12, published 07.07.91 )

In this device, the efficiency cannot be high due to the large number of impellers, each of which rotates on separate bearings, and their shafts are connected to the generator shaft by belt drives, which lose their effectiveness with increased sliding, which in this case is a result of air humidity and direct liquid getting on the transmission elements.

It is also known a device for using the energy of a fluid containing a turbine, an electric generator and rows of containers radially arranged at different levels, mounted for rotation on a horizontal shaft and sequentially communicated with each other by means of diametrically arranged channels, the tanks on the one hand have a suction, and on the other - discharge nozzles, the volume of the containers is made variable, decreasing from the suction to the discharge nozzle, the turbine is mounted to rotate to the side, prot vopolozhnuyu rotation capacitances is connected to the generator rotor and stator of the latter is connected to a horizontal shaft. The device is equipped with a hollow body covering the shaft, mounted for rotation on it and divided by vertical partitions into sealed sections, the shaft is equipped with scapular crowns located in each section, the channels are made in the form of pipes, each of which consists of two parts connected between themselves (see AS No. 1581851, IPC F03B 13/12, publ. 30.07.90).

This device, due to its design features and the principle of operation, is not able to create high efficiency, because raising the fluid to a certain height already leads to the loss of kinetic energy that it had before entering the suction nozzles. With the help of this device, only one form of energy is transformed into another, which significantly reduces its efficiency.

The prototype of the invention is a wave power plant containing a float and a vertically arranged tubular body associated with it, submerged beneath the water level and having a tapering section inside, in which a capsule and a hydraulic turbine are placed, kinematically connected to an electric generator placed inside the capsule and having a rotor and stator with windings . The impeller of the hydraulic turbine from each end is equipped with a guide apparatus, the rotor of the electric generator is fixed on the inside of the impeller and is equipped with permanent magnets, and the stator is made of two parts placed with a gap above and below the rotor (see AS No. 1583649, IPC F03B 13/12, published 07.08.90).

This design, in accordance with the kinematics of the drive, is not able to provide a sufficiently high rotor speed, which is necessary for the appearance of electromotive force used for practical purposes in the windings, and this inevitably leads to the use of a multi-pole low-speed generator, which will have a high cost, as well as dimensions in a plane perpendicular to the axis of the generator. The latter circumstance leads to an increase in drag, reducing the efficiency of the device.

The above analogues also have a common drawback - the inability to work in the winter season, when the pond is covered with an ice shell, and this significantly reduces the efficiency of their use in the northern latitudes.

The technical result of the invention is to increase the efficiency and ensure the operation of the device in winter time.

The result is achieved in that a device for using fluid energy containing a housing, a hydraulic turbine and a volumetric pump is characterized in that it is equipped with flow accelerators located in a vertical plane parallel to the axis of the device symmetrically from the outside of the housing and made in the form of tubes with increasing the ends of the cross section, wings located on the outer part of the body and mounted on a shaft located in a horizontal plane perpendicular to the axis of the device, as well as the differential with a manometer installed in the housing, the opposite cavity of the manometer are connected with the piezometric tubes to the internal cavities of the flow accelerators, and the manometer’s membrane is connected with a disk rigidly mounted on the shaft by means of a thrust that can be moved reciprocally.

The device is also characterized in that the average specific gravity of the device is equal to the specific gravity of the fluid.

Due to the fact that the average density of the entire structure is equal to the density of the fluid, the device is in a state of indifferent equilibrium and maintains the level at which it was originally installed. This creates the possibility of reorienting the device under the action of insignificant efforts, if necessary.

The presence of a vertical orientation mechanism, consisting of two flow accelerators, with piezometric tubes located in them, which are connected with unlike cavities of a differential pressure gauge and acting on a membrane connected by a thrust to a disk and wings fixed on a horizontal axis oriented perpendicular to the direction of flow, allows the device take a position where the flow rate is maximum, and thereby increase its efficiency.

The presence of a rod connected to the device by means of a roller mechanism and fixed motionlessly on the base of the channel allows the device to be moved in the vertical direction and thereby determine the position corresponding to the maximum flow rate.

Figure 1 shows a General view of the device in operating position; figure 2 is a graph of the distribution of flow rates in the presence of ice cover; figure 3 is a longitudinal section of the device, figure 4 is a section aa in figure 3.

A device for using the energy of a fluid consists of a cylindrical hollow body 1, the bow of which is streamlined. In the rear part of the housing with the possibility of rotation around an axis coinciding with the longitudinal axis of the housing, an impeller 2 is fixed. A streamlined shank 4 is rigidly attached to the hub 3 of the impeller coaxially to it and the housing. A volume pump 5 is installed in the cavity of the casing, the rotor 6 of which has a rigid connection with the hub of the impeller. Two flow accelerators 7 and 8 are attached to the device casing in the upper and lower parts, each of which is a cylindrical tube, passing at the ends into conical tubes with an increase in the cross section from the middle of the tube. Piezometric tubes 9 and 10 are placed in the middle cylindrical part of each of the flow accelerators. The other ends of the piezometric tubes are connected to the cavities A and B of the differential pressure gauge 11, which are separated by a flexible membrane 12. The membrane is rigidly connected to one of the ends of the rod 13, which can translate into guides 14. In this case, the other end of the thrust by means of the pin 15 and the radial groove 16 of the disk 17 forms a kinematic pair with a shaft 18, on which the disk is rigidly fixed. The shaft 18 has a horizontal arrangement, perpendicular to the axis of the housing 1 and has the possibility of rotational motion. On the shaft from the outer part of the body are symmetrically placed two wings 19 having a flat shape.

The device has a movable connection with a vertical rod 20, by means of an arm 21, which is fixedly attached to the housing on one side and, on the other, forms a rotational pair with a roller 22, which is capable of translational movement along the rod. In this case, the contact spot is on the side of the rod facing upstream. The rod 20 by means of a screw 23 is screwed into the bottom of the channel and installed motionless.

The device operates as follows. In the winter season, the flow rate in rivers decreases due to the appearance of additional resistance from the inner surface of the ice, which has a certain roughness. When using the device in this case, it is necessary to orient it vertically so that the flow passing through the cross section of the impeller has a maximum power, which is determined from the dependence

where V is the flow rate;

m ₀ - the unit mass of the stream passing through the cross section of the impeller.

The velocity distribution in the vertical longitudinal section is affected by the roughness of the bed of the channel and the inner surface of the ice cover. The coordinate x of the location of the maximum velocity vector can be determined from the equation

where h is the depth of the reservoir in the liquid phase;

m is a coefficient depending on the roughness of the bed of the channel;

m ₁ is a coefficient depending on the roughness of the inner surface of the ice cover.

During the winter period, the depth h constantly decreases due to an increase in the thickness of the ice, which leads to a redistribution of flow rates. In order to increase the efficiency of the device in this situation, it is necessary to reorient it in the vertical direction.

From the course of hydraulics it is known that with an increase in the flow rate, the dynamic component of the total pressure increases, which is determined by the formula

,

,

where ρ is the density of the fluid.

This shows that the dynamic component of the total pressure of the medium is proportional to the square of the flow velocity, which means that the speed can be monitored using a manometer. The proposed device is equipped with two flow accelerators 7 and 8, in which piezometric tubes 9 and 10 are installed, perceiving the hydromechanical component of the pressure of the medium. Flow accelerators are necessary in order to increase the dynamic and, accordingly, lower the hydromechanical component of pressure, thereby increasing the sensitivity of the vertical orientation mechanism.

In a situation where the maximum flow velocity vector runs along the longitudinal axis of the device and thus the flow has maximum power, flow accelerators, at equal distances from the device axis, pass through them jets having equal speeds, and therefore having the same hydromechanical pressure components. Since the tubes are connected to the cavities A and B of the differential pressure gauge 11, separated by a membrane 12, the pressure in this case will be the same in them, and the membrane is in the neutral position. The thrust 13, connecting the membrane with the wings 19 by means of the disk 17 and the axis 18, orientes the wings so that they are parallel to the flow. In this case, the device is oriented along the flow at a certain depth corresponding to the maximum speed.

If with increasing ice or due to a change in roughness over time, the maximum velocity vector begins to shift downward, then the jet velocity in the flow accelerator 8 will increase, and in the accelerator 7 it will decrease. In this case, the hydromechanical pressure components of the two jets will also change. The pressure in the cavity A of the differential pressure gauge will increase, and in the cavity B decrease. The membrane will move to the left, pushing the rod 13 and turning the disk 17 through it counterclockwise along with the wings. An acute angle will appear between the plane of the wings and the direction of flow, which will cause the appearance of a transverse force and, accordingly, the device will move down. When the device enters the optimal zone where the flow power is maximum, the pressure in the accelerators is equalized, the membrane of the differential pressure gauge takes its initial position, and the wing planes occupy a position parallel to the axis of the device. The transverse force of the flow pressure on the wings disappears, and the device assumes a new position in the vertical coordinate.

Claims (2)

1. A device for using the energy of a fluid containing a casing, a hydraulic turbine and a volumetric pump, characterized in that the device is equipped with flow accelerators located in a vertical plane parallel to the axis of the device symmetrically with the outer part of the casing and made in the form of tubes with an increasing cross-section towards the ends, wings located on the outside of the casing and mounted on a shaft located in a horizontal plane perpendicular to the axis of the device, as well as a differential pressure gauge mounted in the case, the opposite cavities of the manometer by means of piezometric tubes are connected to the internal cavities of the flow accelerators, and the pressure gauge membrane is connected with a disk rigidly mounted on the shaft by means of a thrust having the possibility of reciprocating movement. 2. The device according to claim 1, characterized in that the average specific gravity of the device is equal to the specific gravity of the fluid.

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