RU185656U1 - HYDRODYNAMIC OSCILLATOR GENERATOR - Google Patents

Abstract

The generator of hydrodynamic vibrations refers to devices that excite vibrations in a flowing liquid medium, and can be used to intensify technological processes in liquid media, in particular, to remove dissolved substances in the treatment of natural and waste water. Fluctuations in the liquid are accompanied by pressure pulsation, which leads to dispersion of emulsions and suspensions, contribute to the mixing of local volumes of liquid.The device contains sequentially connected inlet channel of circular cross section in the form of a confuser with a coaxial conical insert-displacer located in it, a toroidal vortex chamber and an outlet channel. In front of the inlet channel there is an annular cavity connected to it, which provides a tangential supply of fluid to the channel. On the surface of the conical displacer insert along the generatrix of the cone, grooves with sharp edges are made. The surface of the vortex chamber is divided into two parts. The radius of the profile of the first part adjacent to the sharp edge of the outlet of the chamber is smaller than the radius of the profile of the second part, which forms a step downward along the fluid flow along the surface of the vortex chamber. The output channel in the zone of its transition into the diffuser is blocked in diameter by a wedge-shaped plate, the tip of which is directed towards the fluid flow. The diffuser is closed by a lid with an opening in the side wall, which provides a tangential drainage of fluid from the generator. The combination of these features promotes activation of cavitation processes, mechanothermolysis of the water structure and its pollutants with the appearance of free hydrogen bonds, dispersion and homogenization with the formation of stable emulsions, suspensions, and destruction of biological cells . This allows you to solve the problems posed to the generator of hydrodynamic vibrations.

Description

The utility model relates to devices that generate oscillations in a flowing liquid medium, and can be used to intensify technological processes in liquid media, in particular, to remove dissolved substances in the treatment of natural and waste water. Fluctuations in the liquid are accompanied by pressure pulsation, leading to dispersion of emulsions and suspensions, contribute to the mixing of local volumes of liquid.

The excitation of sound and ultrasonic frequency oscillations in the current fluid flow is based on the physical effects observed in the Galton whistle, Helmholtz, Hartmann resonator, as well as in the conditions of formation and collapse of cavitation cavities under certain regimes of fluid flow.

Known hydrodynamic cavitation reactor (RF patent 2091157), containing sequentially located confuser and flow chamber. In the flow chamber along it at a distance from each other, cavitators are installed in the form of wedges, the tip of which is directed against the fluid flow, and the chamber cavity is made in the form of sections that stepwise expand in the direction from the confuser, while the cross section of each subsequent section is larger than the cross section of the previous section 1.05-1.45 times. In the reactor according to the second embodiment, cavitators in the form of wedge-shaped rings are mounted on a longitudinal rod located along the axis of the reactor. The cross-sectional area of the flow of fluid passing through changes in the diameter of the rod. In this case, during the flow around the wedge of the cavitator and on its back side, cavitation cavities and local shock waves are formed that act on the flowing fluid.

The disadvantages of such a device include poor mixing of the fluid flow moving in a long flow chamber, which is especially important if the fluid is multicomponent and there is no possibility of preliminary mixing of the components.

Known dispersant for low viscosity emulsions and suspensions (RF patent 2349374), comprising a housing with a fluid supply nozzle and a discharge pipe. Inside the casing, perpendicular to the axis of the nozzle, a barrier is installed in the form of a cylinder, in the lateral surface of which there are through longitudinal grooves in which wedges are installed, the tip to the center of the casing. In this case, behind the wedge, a part of the longitudinal groove remains, along which the liquid can flow to the outlet branch pipe. A stream of liquid from the nozzle hits the center of the cylinder and is thrown along its plane to the wedges.

The disadvantage of this device is that the energetic effect on the liquid occurs once during the impact of the jet, and when the liquid is thrown to the periphery over a large area, the flow rate decreases significantly, and the flow energy will not be sufficient for the formation of active cavitation at the ends of the wedges. Accordingly, there will be no pulsations of cavitation pressure. Since the liquid flows to the outlet pipe through autonomous channels, there will also be no active mixing of the liquid.

According to copyright certificate No. 1227261, the vortex generator contains a housing, a conical nozzle, a toroidal chamber divided by sectors into plates, and a conical diffuser successively made in it. Such a device allows the liquid to be mixed well, but the frequency of oscillations excited by a conventional toroidal chamber is low, which does not contribute to the active occurrence of cavitation and corresponding local pressure pulsations.

Closest to the proposed device is a vortex acoustic generator according to the patent of Russian Federation 2162376, in which an increase in the intensity of the emitted (generated) disturbance is achieved due to the fact that the device contains a confuser input channel with a coaxial conical flow divider inside it, an output channel and a toroidal vortex chamber between them. The working fluid is supplied under pressure to the inlet channel. Movement of the flow divider, carried out forcibly, allows you to change the gap between the side surfaces of the divider and the inlet channel, adjusting the flow rate, working fluid pressure and hydraulic resistance of the generator.

The analyzed acoustic generator has the following disadvantages. Typically, centrifugal pumps are used for pumping liquids, the maximum pressure of which at one stage does not exceed 0.3 MPa. The pressure characteristic of centrifugal pumps is such that when the resistance to the pumped flow increases, the pump pressure does not increase, and the flow rate drops until the flow stops completely. Thus, a decrease in the gap between the side surfaces of the conical divider and the inlet channel will simply lead to a decrease in the flow rate and a decrease in the energy of the fluid flow pressure fluctuations excited by the vortex chamber. In principle, the maximum flow rate at the entrance to the vortex chamber will be achieved in the complete absence of a propellant in the input channel. The frequency of oscillations excited by an ordinary toroidal chamber is low, which does not contribute to the occurrence of active cavitation and corresponding local pressure pulsations.

In addition, the presented description of the invention does not address the issue of how liquid will be supplied to the annular cavity of the inlet channel and to ensure equal dynamic pressure along its perimeter.

The technical problem solved by the claimed utility model is to increase the efficiency of the generator of hydrodynamic vibrations by activating cavitation processes in the fluid flow and the resulting pressure pulsations.

The solution to this problem is achieved by the fact that the hydrodynamic oscillation generator, containing a ring-shaped input channel in series in the form of a confuser with a coaxially conical displacer-displacer located in it, a toroidal vortex chamber and an output channel, has an annular cavity connected to it in front of the input channel, providing tangential fluid supply to the channel. This is achieved due to the location in the side wall of the cavity of the hole for the fitting directed tangentially to the circumference of the annular cavity. On the surface of the conical displacer insert inside the confuser, grooves with sharp edges are made along the generatrix of the cone. The surface of the vortex chamber obtained by rotating the figure forming it around an axis lying in the plane of this figure and coinciding with the axis of the input and output channels is divided into two parts. The radius of the profile of the first part adjacent to the sharp edge of the outlet of the chamber is smaller than the radius of the profile of the second part, which forms a step downward along the fluid flow along the surface of the vortex chamber.

The diameter of the hole at the outlet of the confuser inlet channel and the inlet of the vortex chamber is (1.1-1.2) D - diameter of the outlet of the vortex chamber. The distance between the edges of the inlet and outlet openings of the vortex chamber is approximately 0.7 D, the step of the vortex chamber has a height of approximately 0.2 D, the length of the outlet channel is approximately equal to 2 D, while the outlet channel is blocked by a wedge-shaped plate in diameter outlet area.

The tip of the wedge is directed towards the fluid flow, and the plate is fixed in the slit of the diffuser adjacent to the outlet of the outlet channel and closed by a lid, which provides a tangential discharge of fluid from the reactor through the provided hole in the side wall of the lid.

A diagram of the device of the proposed generator of hydrodynamic oscillations is shown in FIG. 1, which shows a longitudinal section along the axis of the input and output channels and views along these sections. The device consists of five case elements. An annular cavity 1 is made in the first element, an opening for the nozzle for supplying the treated water 2, and a conical insert-displacer 3 with grooves 4 is fixed on its conical surface. In the second element, a confuser 5 and a second part of the vortex chamber 6 are made. In the third element, the first part of the vortex chamber 7 with its sharp edge 8 is made. A step 9 is formed in the contact zone of the second and third housing elements due to the difference in size. The diffuser is made in the fourth element 10 with a slot 11 in which a plate 12 having a wedge shape in the area of the outlet channel is mounted. The fifth element is made in the form of a cover 13 having an opening 14 in its side wall, which provides a tangential discharge of liquid from the reactor.

The first, second and third elements of the device can have an integral connection, the fourth and fifth elements (diffuser and cover) are connected using countersunk screws 15. The detachable connection allows you to monitor the state of the plate 12 and replace it in case of damage.

Using a generator of hydrodynamic vibrations is as follows. The processed liquid is fed through the hole 2 into the annular cavity 1 of the generator and rotates in it, during which it also rotates moves in the annular gap between the wall of the confuser 5 and the conical insert-displacer 3. With this organization of the fluid flow, pressure unevenness is eliminated already at the beginning of the input channel. The performance of the pump supplying the liquid to be cleaned must provide a flow rate of the liquid in the outlet channel of at least 4 m / s.

Since the diameter of the annular gap decreases when moving along the confuser inlet channel, the rotational speed of the fluid flow, at the same flow rate, increases significantly. Under the action of centrifugal forces, the fluid flow is pressed against the walls of the confuser, and the inner part of the rotating flow experiences less pressure. When the fluid moves over the grooves with sharp edges 4, conditions are created in them for the formation of cavitation cavities, which, moving in the fluid flow, are closed one by one, creating a background of active cavitational pressure pulsations.

Water rotating by inertia enters the vortex chamber and is cut by its sharp edge 8 into two streams. Part of the water continues to move along the outlet channel, and the other part enters the chamber, flowing around the surface 7 and further 6, abutting and compressing the stream exiting the confuser, directing it only to the outlet channel. In this case, the flow of liquid into the vortex chamber is stopped and there is a vacuum, which again deflects the flow and directs it into the vortex chamber. Thus, there is a pulsation of the pressure of the fluid flow in the output channel of the generator. At the same time, when fluid flows along the walls of the vortex chamber behind step 9, a zone with a reduced pressure is formed, where cavitation cavities and pressure pulsations occur when they collapse.

The liquid flow leaving the channel is dissected by a wedge-shaped plate 12, which is accompanied by wedge-tone oscillations, and since the flow velocity pulsates due to the vortex chamber, the wedge-tone oscillation spectrum expands significantly. Behind the flat end of the wedge, a vacuum zone is also created, which contributes to the formation of cavitation cavities. Due to the tangential drainage of liquid from the cavity of the lid 13 through the hole 14 in the cavities of the lid and the diffuser also forms a circular motion of the liquid.

Thus, in the proposed device, the conditions for good mixing of the liquid in the annular cavity in front of the inlet channel, in the channel itself, in the vortex chamber and in the diffuser and the cavity of its cover are provided.

When fluid moves over grooves with sharp edges of the displacer insert, flow runs onto the sharp edge of the vortex chamber, flows over a step in the vortex chamber, and a sharp wedge dissects the fluid flowing from the outlet channel, cavitation processes actively occur. This contributes to mechanothermolysis of the structure of water and its pollutants with the appearance of free hydrogen bonds, dispersion and homogenization with the formation of stable emulsions, suspensions, and the destruction of cellular biological cultures.

Together, all this allows the generator of hydrodynamic vibrations to successfully solve the tasks.

Claims (2)

1. The generator of hydrodynamic vibrations, containing a series-connected input channel of annular cross-section in the form of a confuser with a coaxial conical insert-displacer located in it, a toroidal vortex chamber and an output channel, characterized in that an annular cavity connected to it is provided in front of the input channel, providing tangential inlet liquid in the channel, and on the surface of the conical propellant insert along the generatrix of the cone grooves with sharp edges are made, while the surface of the vortex chamber taught by the rotation of the figure forming it around an axis lying in the plane of this figure and coinciding with the axis of the input and output channels, is divided into two parts, and the radius of the profile of the first part adjacent to the sharp edge of the outlet of the chamber is less than the radius of the profile of the second part, which forms a downward along the course of the fluid along the surface of the vortex chamber a step. 2. The hydrodynamic oscillation generator according to claim 1, characterized in that the diameter of the hole at the outlet of the confuser inlet channel and the inlet of the vortex chamber is (1.1-1.2) D is the diameter of the outlet of the vortex chamber, and the distance between the edges of the inlet and the outlet of the chamber is approximately 0.7 D, the step of the vortex chamber has a height of approximately 0.2 D, the length of the outlet channel is approximately 2 D, while the outlet is blocked by a diameter wedge-shaped plate in the area of the outlet, the tip wedge directed towards the fluid flow, and the plate is fixed in the slots of the diffuser, adjacent to the opening of the outlet channel and closed by a lid, providing tangential discharge of liquid from the reactor through the hole in the side wall of the lid.

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