LT5709B - Hydrodinamic generator and a reactor internal system (variants) - Google Patents

Abstract

The invention relates to devices for producing vibrations in a fluid medium flow and can be used in the chemical, mining and other industries for treating monophase and multiphase media with the purpose of mixing said media and dispersing phases thereof. The inventive hydrodynamic generator for treating fluid media comprises a tubular body (1), a stream-forming attachment (2) and a resonator plate (3) which is cantilever-secured in a body towards the medium flow. Said resonator plate has two projections which are arcwisely bent in opposite directions in such a way that they are closely joined to the inner surface of the pipe, thereby formingthe plate fastener. The aim of the invention is to design a more simple hydrodynamic generator.

Description

The present invention relates to devices for creating vibrations in a fluid medium stream and can be used in the chemical, mountain and other industrial applications in the treatment of single-phase and multi-phase media when they are to be mixed and phase dispersed.

Known state of the art

Known hydrodynamic oscillators for treating liquid media consisting of a housing, a current-forming nozzle, and a bar or plate-shaped resonator attached to the housing cantilever (SU 1020663, F15B 21/12, 1983; SU 1209949, F15B 21/12, 1986; SU 1498992, F15B 21 / 12, 1989; SU 2169625, F15B 21/12, 2001). The turbulent flow of the medium through the housing causes the resonator to fluctuate, which in the multiphase flow facilitates the mixing of the medium and the dispersion of the phases.

The closest to the proposed one is a known hydrodynamic oscillator for fluid processing, consisting of a housing with a nozzle for forming a current, and a housing-mounted resonator plate (SU 1789794, F15B 21 / 12,1993) mounted in a console. The difficulty of producing this generator is its drawback.

Known in-house reactor unit for gas-liquid phase interaction, consisting of under-grid contact units, each of which is a vertically-mounted upright tube for the grate, divided into lowering and lifting elements by an internal vertical bulkhead which is closely connected to the support grille at the top , and does not reach the lower end of the blocked pipe at the bottom (SU 2114691, B 01 J 10 / 00,1998),

Closest to the first embodiment of the proposed reactor internal unit is an internal reactor unit for gas and liquid media interaction, consisting of end-to-end contact gratings, each consisting of vertical tubular lowering and lifting members interconnected by the same U-shape. with a tubular member of diameter, the lower member being made at the top with an inlet opening for fluid and gas on the lateral surface of the upper portion, and the up member on the support grille having a hole for venting the gas-liquid mixture (SU 2168355, B 01 J 10 / 00,19 / 00,2001).

Closest to the second embodiment of the proposed reactor interior unit is an internal reactor unit for gas-liquid media interaction, consisting of end-to-end contact gratings, each consisting of vertical tubular up and down elements of the same U-shape. with a diameter tubular member, the lifting member having a hole on the support grille for the introduction of fluid and gas, and the lowering member being constructed locked from below with outlet holes for the gas-liquid mixture on the underside of the side surface (SU 2261141, B 01 J 10 / 00,2005 ).

All of the above reactor internals for gas-liquid media interactions are characterized by insufficient phase interaction efficiency.

Disclosure of the Invention

The technical object of the present invention is to develop a hydrodynamic generator of the simplest possible design, which may be part of a more sophisticated apparatus, and to improve the design of the reactor internals for the interaction of gases and liquids.

A technical result that may be obtained in carrying out the invention is to increase the efficiency of mixing liquid or liquid phase multiphase media.

For a technical result, a hydrodynamic oscillator for fluid handling is proposed, consisting of a housing, a jet nozzle, and a consonant plate resonator mounted in the housing opposite to the movement of the medium, characterized in that the housing is tubular and the plate resonator has two protrusions in opposite directions so that it fits snugly against the inner surface of the tube, thus forming the plate mount.

In order to achieve a technical result, variants of the reactor internal unit for gas and liquid media interactions are proposed.

In one embodiment, there is provided an internal reactor unit for gas-liquid media interaction, consisting of end-to-end contact devices mounted on support grids, each consisting of vertical tubular lowering and lifting members interconnected by a U-shaped tubular member of the same diameter. in addition, the lowering member is made from above with a plurality of inlet apertures for fluid and gas on the side surface of the upper portion, and the lifting element has a perforation on the support grille for venting the gas / liquid mixture. a hydrodynamic oscillator comprising a tubular housing which is part of a lowering member, a current forming nozzle and a plate resonator with two protrusions mounted in the cantilever housing opposite to the direction of movement of the medium s that are bowed in opposite directions so that they fit snugly against the inner surface of the tube, thereby forming the plate fastener.

In one embodiment, there is provided an internal reactor unit for gas-liquid media interaction, comprising contact devices mounted at and above the support grilles, each consisting of vertical tubular elevation and lowering members interconnected by a U-shaped tubular member of the same diameter. in addition, the lifting element has a hole in the support grille for fluid and gas inlet, and the lowering element is made from below closed with an outlet for gas-liquid mixture on the lower surface of the side surface, characterized in that the contact device at the inlet of the tubular lifting element a generator comprising a tubular housing which is part of a lifting element, a current-forming nozzle and a plate cantilever mounted in the housing prior to the movement of the medium, with two protrusions which arc in the form of a engaging in opposite directions so as to fit snugly against the inner surface of the tube, thereby forming the panel mount.

Brief description of the drawing figures

BRIEF DESCRIPTION OF THE DRAWINGS FIGS. Figures 1-3 are a cross-sectional and longitudinal section through a hydrodynamic generator of a particular embodiment of the invention; Figure 4 is a longitudinal sectional view of a reactor for gas-liquid interaction with an internal unit housed therein according to a first embodiment; FIG. 5 is a longitudinal sectional view of the contact device in this reactor, FIG. 6 and 7 is a reactor with another variant of the internal unit and a contact unit included therein.

Embodiments of the invention

The hydrodynamic generator according to FIG. 1-3 is comprised of a tubular housing 1, a coaxial nozzle 2 connected thereto and a coaxial nozzle 2 forming a flow of a fluid through a slit hole, and a plate resonator 3 cantilevered in the housing 1 so that the free end is upstream of the flow medium. . The plate-resonator 3 is made of a flat T-shaped workpiece using an arcuate bend in opposite directions to the projections of the plate which form the letter T-shaped transverse. The said protrusions are folded in such a way that this part of the plan forms a contour which fits into the cross-sectional circumference of the pipe 1 of the housing. Thus, the diameter of the contour in the free state must be slightly greater than the inside diameter of the tube so that the plate can be inserted into the tube by pre-compressing the flanges. Placed in the tube, the plate holds in it due to the elasticity of compressed bumps during placement.

When the generator is operating, the flow of turbulent media through the tube 1 causes oscillations of the plate-resonator 3, which facilitates media mixing and phase dispersion in the multiphase stream.

According to Figure 4, the reactor is comprised of a vertical housing 4 with inlet conduits 5, 6 and 7 for liquid and gaseous reactants, a reaction product outlet conduit 8, a distribution device 9, horizontal perforated baffles 10 and contact devices 11 made of a continuous section. tubes mounted on the support grilles 12 and arranged below them.

According to Figure 5, each contact device 11 is composed of two vertical tubular members - lowering 13 and lifting member 14. The members 13 and 14 are interconnected in the lower portion by a U-shaped tubular member 15. The members 13 and 14 are secured by their upper ends 12. Inlet side apertures for gas phase 16 and liquid phase 17, evenly spaced by a pipe circumference, are provided in the sidewall of the lowering element 13 below the support grilles 12. The inlet openings for the gas phase 16 are located above the inlet openings 17 for the liquid phase. The upper end of the lowering member 13 has a cap 18 housed inside the tube. The outlet aperture 19 of the lifting element 14 is located on the support grilles 12. The contact device 11 has a hydrodynamic generator close to the inlet apertures 16 and 17 comprising a tubular body forming part of the lowering element 13, a current generating nozzle 2 and a resonator 3 sequentially positioned thereon. The plate-resonator 3 is made of a flat T-shaped workpiece using the bending of the plate protrusions in opposite directions to form a T-shaped transverse bar. The said protrusions are folded in such a way that in the plan this part of the plate forms a contour that engages in the cross-sectional circumference of the lowering element 13. Introduced into the lowering member, the plate retains there due to the stiffness of the protrusions compressed when entering.

According to Fig. 6, the reactor consists of a vertical housing 4 with liquid and gaseous reactant inlet pipes 5, 6 and 7, reaction product outlet pipe 8, distribution device 9, horizontal perforated baffles 10 and contact devices 11 made of fixed-diameter pipes and attached on the support grille 12. The contact units are located on the support grille in the lower third of the reactor where there is a large amount of gaseous phase. The number of perforated baffles and the distance between adjacent baffles are determined by the nature of the process being performed and may vary.

According to FIG. 7, each contact device 11 is comprised of two vertical tubular members, lowering 13 and lifting 14. Elements 13 and 14 are interconnected at the top by a U-shaped tubular member 15. Elements and 14 are secured at their lower ends in support grooves 12. the lifting element 14 has a hole 20 on the support grille which is open to allow for liquid and gas, the opening of the lowering element 13 is covered by a cap 18. The lower part of the lower element is provided with openings 21 for gas-liquid mixture exit. The support grilles 12 have drainage holes 22 for draining the reaction fluid when the process is stopped. The contact device 11 near the inlet hole 20 has a hydrodynamic generator comprising a tubular housing which is part of the lifting element 14, a current-forming nozzle 2 and a consonant plate 3 arranged consecutively therewith. The plate resonator 3 is made of a flat folding in opposite directions to form a T-shaped transverse bar. Said protrusions are folded in such a way that in the plan, this part of the plate forms a contour which engages in a cross-sectional circumference of the lifting element 14.

During operation of the reactor (in both embodiments), the passage of the turbulent gas-liquid flow through the portion of the contact device where the plate-resonator 3 is disposed causes its vibrations, which facilitate gas dispersion.

Industrial applicability

The invention can be used in the chemical, mountain, and other industries by treating single-phase or multi-phase media to mix and disperse the phases.

Claims (3)

Definition of the Invention 1. A hydrodynamic oscillator for processing fluid media consisting of a housing, a nozzle for forming a jet, and a plate resonator mounted in a cantilever cantilever against the movement of the medium, characterized in that the housing is tubular and the plate resonator has two protrusions bent in opposite directions , that fits snugly against the inner surface of the tube to form the plate mount. 2. Internal reactor unit for gas-liquid media interaction, consisting of end-to-end contact pieces located on a support grid, each consisting of vertical tubular lowering and riser elements interconnected by a U-shaped tubular member of the same diameter, the element is made from above closed with inlet apertures for fluid and gas on the side surface of the upper part, and the lift element has a hole in the support grille for removing the gas / liquid mixture, apart from the contact device having a hydrodynamic generator comprising the pipe a housing formed as a part of the lowering member, a nozzle for forming current and a plate cantilevered in the housing against the movement of the cantilever, with two protrusions bowed in opposite directions so that they fits snugly against the inner surface of the tube to form the plate mount, 3. Internal reactor unit for gas-liquid interface, consisting of end-to-end contact lugs, each consisting of vertical tubular risers and tubing members interconnected by a U-shaped tubular member, with the addition of a riser an element on the support grille having a fluid and gas evacuation aperture, and a lowering element made from below with an outlet aperture for a gas-liquid mixture on the lower surface of the lower part, characterized in that the contact device has a hydrodynamic generator comprising a tubular a body forming part of the lifting member, a nozzle for forming current and a plate cantilevered in the housing against the movement of the cantilever, with two protrusions, bowed in opposite directions so that they fits snugly against the inner surface of the tube to form the plate mount.