RU2347153C1 - Hydrodynamic generator - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to chemical industry and power engineering and can be used for activation of chemical reactions and processes or can serve as a hydrodynamic-type water heater. The proposed hydrodynamic generator incorporates a cylindrical casing accommodating an action and reaction turbines with opposite direction of rotation about common vertical axis, and inlet and outlet branch pipes. The said inlet branch pipe is an internal member of the action turbine and is furnished with radial through slots. The action turbine incorporates a blading making an external member of the reaction turbine, working chambers communicating, via swirlers representing confusers, with the aforesaid branch pipe. The confusers' wider parts face the said inlet branch pipe in the plane of its radial slots. Axial zones of the working chambers are interconnected. Note that the reaction turbine represents a Segner wheel with a cup-like casing, its wall being furnished with radial through slots and its bottom being provided with, at least, one journal. The aforesaid cup-like casing space communicates with skewed-end nozzles that can communicate cycle-by-cycle with the working chambers via channels tangential to the working chamber inner surfaces and arranged in the action turbine body opposite the reaction turbine casing slots.

EFFECT: higher reliability and decreased moment of inertia of reaction turbine.

5 cl, 5 dwg

Description

The invention relates to chemical equipment for activation:

- redox reactions in the liquid phase between the dissolved substances and the products of dissociation of water that occur in cavitation bubbles that occur in the working chambers and pass into the solution after their collapse;

- reactions between dissolved gases and substances with high vapor pressure inside these cavitation bubbles;

- chain reactions in solution, which are not induced by radical cleavage products, but by some other substance present in the system and cleaved in the cavitation cavity;

- reactions involving macromolecules (e.g., destruction of hydrocarbons).

It also relates to a power system, namely, fluid-type fluid heaters.

Chemical equipment uses devices of a similar purpose, for example, rotary pulsation apparatuses - RPA (Promtov MA Machines and apparatuses with pulsed energetic effects on the processed substances. M: Mashinostroyenie-1, 2004, pp. 71-72; Promtov MA Rotary-type pulsation devices. Theory and practice. M .: "Mechanical Engineering", 2001, section 7.3 "The main directions of development and classification of rotary-type pulsating devices"; RF patent No. 2026706, B01D 11/2, 1995), which significantly differ structurally from the stated us roystva. The consequence of these differences is that the claimed device does not have RPA disadvantages due to the hard landing of rotors on the rotating shaft that require dynamic balancing and have a limited rotation frequency (due to the high values of the rotor inertia).

The well-known "cavitation-vortex heat generator", which is essentially RPA and contains rotors rotating in opposite directions, discharge and exhaust pipes of the working fluid, the stator housing. Two perforated rotors are placed in the bores of the stator and mounted on shafts that are installed in the sealing and bearing assemblies with the possibility of rotation in opposite directions. The inner annular protrusions of the stator are also perforated (see RF patent No. 2235950 C1, F24J 3/00, 09/10/2001).

The disadvantages of the known device is that the heat in it occurs in turbulent flows due to the dissipation of energy at local hydraulic resistances, the effect of cavitation is not used properly. In addition, this analogue has all the above-described general disadvantages of RPA.

Closest to the claimed invention is a hydrodynamic generator containing a stator housing and rotors placed in it with the opposite direction of rotation, as well as the discharge and outlet nozzles for pumping the working fluid. The rotors are mounted on a fixed vertical axis. In the first rotor, the working chambers communicate through swirlers with a discharge pipe. The second rotor is made in the form of a jet turbine with nozzles made with the possibility of cyclic communication with the outlet openings of the working chambers, the axial zones of the rear ends of which are interconnected (see RF application No. 2005136836 A, F22B 33/16, 05.27.2007) - prototype.

In some modes of operation of the prototype, uncompensated axial loads at the end of the active turbine are possible (at the moments when the response plane of the reactive hydraulic turbine blocks the outputs of the working vortex chambers). The prototype also has a relatively high moment of inertia of the jet turbine.

The technical results of the claimed invention consist in increasing the reliability of work (by fundamentally eliminating the axial loads indicated above in comparison with the prototype), reducing the moment of inertia of a jet turbine, as well as reducing the cost of the apparatus (less material consumption) and increasing its efficiency (the latter - by obtaining an increase in angular jet turbine speed due to its lightening).

Technical results are achieved by the fact that in a hydrodynamic generator containing a cylindrical body in which the active and reactive turbines are located with the opposite direction of rotation around a common vertical axis, as well as the discharge and outlet pipes, the discharge pipe is covered by an active turbine and is made with radial through grooves, the active the turbine is equipped with a vane apparatus covering the jet turbine, and contains working chambers communicated through swirlers in the form of confusers with a blower with the nozzle pipe, the wide parts of the confusers face the discharge pipe in the plane of its radial grooves, the axial zones of the working chambers are interconnected, the jet turbine is made in the form of a Segner wheel with a body in the form of a cup, in the wall of which there are radial through grooves, the bottom of the cup is equipped with at least one trunnion, the body cavity is in communication with nozzles with beveled ends, which are made with the possibility of cyclic communication with the working chambers through the channel tangential to the inner surfaces of the working chambers Which are formed in the body opposite the grooves impulse turbine jet turbine housing.

According to the invention, the axial zones of the working chambers are interconnected through the bypass nozzles and the annular chamber containing the annular diaphragm, while the bypass nozzles are mounted on the diaphragm.

According to the invention, the working chambers contain conical sections that provide focusing of the shock waves reflected from the body of the jet turbine into the axial zones of the working chambers.

According to the invention, the axial bypass pipes are made up of mating cones and cylinders.

According to the invention, the confusers of the vortex chambers can be equipped with check valves.

The invention is illustrated by the following drawings:

figure 1 - hydrodynamic generator, combining a General view with a section;

figure 2 - section GG in figure 1;

figure 3 - active turbine;

figure 4 - projection of the housing of the jet turbine;

figure 5 - channels of the active turbine.

In the figures, the elements of the device are indicated by the following positions: 1 - discharge pipe; 2 - radial through groove; 3 - confuser; 4 - active turbine; 5 - a working chamber; 6 - tangential channel; 7 - a casing of a jet turbine; 8 - thrust bearing; 9 - radial grooves of the housing 7; 10 - annular cavity; 11 - jet turbine nozzle; 12 - scapular apparatus; 13 - axial zone of the chambers; 14 - bypass pipe; 15 - buffer annular chamber; 16 - aperture; 17 - the edge of the bypass pipe; 18 - conical section; 19 - exhaust pipe; 20 - generator housing; 21 - base; 22 - pin of the housing 7; 23 - pin of the housing 20; 24 - ball bearing; 25 - jet turbine.

The hydrodynamic generator comprises a cylindrical housing 20 detachably connected to the base 21. In the housing 20 there are active 4 and reactive 25 turbines with the opposite direction of rotation around a common vertical axis. The jet turbine 25 is formed by a housing 7 and nozzles 11, rigidly fastened to each other. The base 21 is equipped with a cylindrical discharge pipe 1, coaxial to the vertical axis of rotation of the rotors. A thrust bearing 8 is fixed in the upper part of the nozzle 1. In this case, the rotor of the active turbine 4 covers the nozzle 1, in the wall of which there are radial through grooves 2. Assembled, the grooves 2 lie in the plane of the confusers 3. The wide sections of the confusers 3 lie on the inner surface of the rotor of the active turbine 4 The confusers 3 of the working chambers 5 can be equipped with check valves (not shown in the figures), which provide unidirectional movement of the working fluid.

The confusers 3 communicate with the working chambers 5 connected through axial zones 13 with tangential channels 6 inclined relative to the inner cylindrical surface of the rotor of the active turbine 4. In addition, the axial zones 13 are connected through axial bypass pipes 14 to each other by a buffer annular chamber 15 with an annular diaphragm 16. The rotor of the active turbine 4 is equipped with a blade apparatus 12, covering the turbine 25, which is made in the form of a Segner wheel with a housing 7 in the form of a glass and nozzles 11 attached to the glass with beveled ends .

Radial through grooves 9 are made in the cylindrical wall of the housing 7 of the rotor of the jet turbine 26. Its bottom is provided with at least one central pin 22. The housing 7 of the rotor of the jet turbine 8 is made with a cavity 10 with which the nozzles 11 communicate. This design made it possible to significantly facilitate the jet turbine 25 and reduce its moment of inertia, and also increase on this basis the angular velocity of rotation compared with the prototype. In the body of the pin 22, a blind hole is made in which a pin 23 is fixed rigidly on the housing 20. The end face of the pin 22 is supported by a ball bearing 24 lying at the bottom of the thrust bearing 8. This set of features ensures rotation of the turbine 25 with minimal friction loss and reliably perceives axial load. The outputs of the tangential channels 6 of the rotor of the active turbine 4 are located opposite the radial grooves 9 of the housing 7 of the jet turbine 25. The inlet sections of the nozzles 11 are in communication with the cavity of the housing 7 of the jet turbine 25. The nozzles 11 are cyclically communicated, as described below, with the outputs of the tangential channels 6, that is, with the outlet openings of the working vortex chambers 5 (through the grooves 9 of the housing 7).

The device operates as follows.

The working fluid (in the case of using the declared hydrodynamic generator as a heat source) or the processed fluid (in case of using it in chemical equipment) is pumped into the inlet pipe 1. Through radial grooves 2 in the inlet pipe 1, the working fluid flows into the radially located confusers 3 in the rotor body active turbine 4, covering the inlet pipe 1. The confusers 3 provide a tangential input of the working fluid into the working chambers 5 of the rotor of the active turbine 4 and its twisting with the formation of macrovortex th flows. In such flows, the working fluid is structured under the action of a radial pressure gradient. From the working chambers 5, the working fluid is discharged through inclined channels 6 made in the rotor body of the active turbine 4. In this case, the working fluid moves from its periphery to its axis. In the casing 7 of the turbine 25, radial grooves 9 and the outputs of the inclined channels 6 of the rotor of the active turbine 4 are made when the active turbine 4 and the turbine 25 rotate, they communicate with the annular cavity 10, or are disconnected from it. Therefore, in the inclined channels 6 of the rotor of the active turbine 4, water hammer is generated. From the cavity 10 of the turbine 25, the working fluid enters the nozzle 11. When the fluid flows from the nozzles 11, a moment arises, which causes the turbine to rotate. At the same time, the jets flowing from the nozzles 11 rotate the turbine 4 by interacting with the blade apparatus 12 that is rigidly fixed on the rotor of this turbine. The turbines 4 and 25 rotate in opposite directions. When the outputs of the channels 6 of the turbine rotor 4 are blocked by the turbine body 25 (with the formation of water hammers), shock waves are reflected in the axial zones 13 of the working chambers 5 and through the axial bypass pipes 14 enter the annular chamber 15 connecting the working chambers 5 to each other. In the annular chamber 15, the reflected shock waves transmit energy to the annular diaphragm 16 and the axial zones 13 of the working chambers 5, which are currently open at the outlet, that is, communicated through the radial grooves 9 of the housing 7 with its nozzles 11. The edges 17 of the bypass pipes 14 generate acoustic vibrations, which increases the intensity of cavitation in the working chambers 5 of the turbine 4.

To focus the reflected shock waves into the axial zones 13 of the chambers 5, the surface of the latter contains conical sections 18, and the axial bypass pipes 14 are made up of conjugate cylindrical and conical sections. The working fluid is discharged from the device through the exhaust pipe 19. In the axial zones 13 of the chambers 5 there are low pressure zones, accompanied by hydrodynamic cavitation and the formation of vapor-gas bubbles (caverns). When the shock waves are directed to the bubble formation zone, the latter collapse. In this case, energy is released, and the working fluid is subjected to local discrete-pulse action. The combination of hydrodynamic vortex cavitation with shock-wave action and sonication in the ultrasonic range, which provide the edges 17 of the axial nozzles 14, mounted on an annular diaphragm, entails synergy, second-order nonlinear processes occur. This ensures intensive cavitation in the working fluid, in particular, increases the rate of heating of the fluid (in the case of using a hydrodynamic generator as a heater).

The implementation of the device according to the features of the claims allows to eliminate axial loads on both turbines, as well as reduce the moment of inertia of the jet turbine, which results in:

- increases the resource and reliability in the work,

- increases the efficiency of the discrete-pulse effect on the fluid being treated by increasing the angular velocity of rotation of the jet turbine (ceteris paribus), therefore, the frequency of hydropercussion effects on the liquid.

- reduces the cost of the apparatus (the new design of the turbine provides an increase in the utilization of the material and a decrease in its total consumption).

The achievement of technical results in the above ways does not follow explicitly from the prior art, which confirms the inventive step of development.

Claims (5)

1. A hydrodynamic generator comprising a cylindrical body in which active and jet turbines with an opposite direction of rotation around a common vertical axis are placed, as well as a discharge and an outlet nozzle, an injection nozzle is enclosed by an active turbine and made with radial through grooves, the active turbine is equipped with a blade apparatus, covering a jet turbine, and contains working chambers communicated through swirls in the form of confusers with a discharge pipe, wide parts of confusers They are connected to the discharge nozzle in the plane of its radial grooves, the axial zones of the working chambers are interconnected, the jet turbine is made in the form of a Segner wheel with a housing in the form of a cup, in the wall of which there are radial through grooves, the bottom of the cup is equipped with at least one journal, the cavity of the housing is in communication with nozzles with beveled ends, which are made with the possibility of cyclical communication with the working chambers through channels tangential to the internal surfaces of the working chambers, which are made in the body of an active turbine, n opposite the grooves of the housing of the jet turbine. 2. The hydrodynamic generator according to claim 1, in which the axial zones of the working chambers are interconnected through the bypass nozzles and the annular chamber containing the annular diaphragm, while the bypass nozzles are mounted on the diaphragm. 3. The hydrodynamic generator according to claim 1, in which the working chambers contain conical sections that provide focusing of shock waves reflected from the body of the jet turbine into the axial zones of the working chambers. 4. The hydrodynamic generator according to claim 2, characterized in that the axial bypass pipes are made in the form of conjugate conical and cylindrical sections. 5. The hydrodynamic generator according to any one of claims 1 to 4, characterized in that the confusers of the vortex chambers are equipped with check valves.

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