RU2159660C1 - Thin-layer settler - Google Patents

Abstract

FIELD: apparatus for separation of two immiscible media of different densities, for example, liquid-liquid, gas-liquid and liquid-suspension; separation of mixtures, such as condensate-glycol and gas-condensate in processing oil gas, cleaning waste water and clarifying vegetable oils and petroleum products. SUBSTANCE: thin-layer settler includes vertical housing with branch pipes for inlet of mixture to be separated and outlet for separated phases; stack of thin-layer elements is arranged inside housing. Branch pipe for inlet of separable medium is fitted at the bottom of apparatus coaxially relative to housing; it is deepened at distance equal to 0.1 to 0.5 of height of apparatus. Thin-player elements are located along axis of apparatus; each thin-layer element is made from plates stacked in form of funnel directed downward. Upper base of lower thin-layer element is blanked-off and upper thin-layer element is connected with housing by means of circular partition mounted in upper portion of apparatus. Mounted additionally between inlet branch pipe and lower thin-layer element is one or several thin-layer elements. Base of thin-layer element which is nearest to inlet branch pipe is connected with upper edge of branch pipe. Angle of inclination of generatrix of thin-layer element relative to level ranges from 30 to 70 deg. EFFECT: enhanced efficiency of separation of light fraction from heavy one. 4 cl, 2 dwg

Description

 The invention relates to apparatus for separating two immiscible media of different densities, for example liquid-liquid, gas-liquid, liquid-suspension, and can be used to separate condensate-glycol, gas-condensate mixtures in the processing of oil gas, for wastewater treatment and clarification vegetable oils and petroleum products.

 Known thin-layer sump containing a block consisting of several packages of sheets of a V-shaped with curved edges, installed with a gap relative to each other for the release of sediment. To separate the gases from the liquid, the sides of the V-shaped sheets are converging at the top and diverging at the bottom (Overview "Modern sedimentation tanks for water purification systems": "Chemical and oil refining engineering", TsINTIkhimneftemash, M., 1974).

 The disadvantages of the known sump include high metal consumption and low separation efficiency due to the secondary mixing of the separated and separated phases.

 Closest to the proposed one is a thin-layer sump designed to remove both sedimentary and pop-up contaminants from the water. The sump contains a vertical casing with contaminated water inlet pipes and purified water and sludge outlet pipes and a thin-layer block (Thematic review. Analysis of the design solutions of thin-layer settlers ", TsNIITEneftemash, M., 1989, p.19).

 A disadvantage of the known sump is the low separation efficiency. As a result of the friction forces, turbulent disturbance arises at the boundary of the zones of the moving water flow and the sliding sediment, the sediment is aggravated and the water flow is secondarily contaminated, which is accompanied by an increase in the concentration of pollution of the outgoing water.

Common features of the proposed and well-known sedimentation tanks are:
- vertical body;
- a package of thin-layer elements;
- pipe inlet mixture;
- outlet pipes of the separated phases.

 The technical problem is to create a design of the sump, providing high efficiency and versatility of separation of the light dispersed phase from the heavy.

 The task is achieved in that in a thin-layer sump, including a vertical casing with nozzles for the input of the separated mixture and the output of the separated phases and a package of thin-layer elements placed inside the casing, the inlet is placed at the bottom of the apparatus coaxially to the casing and is recessed by a distance of 0.1-0.5 the height of the apparatus, thin-layer elements are placed along the axis of the apparatus, and each thin-layer element is made in the form of a funnel facing down, in addition, the upper base of the lower thin-layer element is muffled, and the upper thin layer oyny element connected to the housing by an annular partition installed in the upper portion of the apparatus.

 In addition, between the inlet pipe and the lower thin-layer element, one or more thin-layer elements are additionally installed, and the base of the thin-layer element closest to the inlet pipe is connected to the upper edge of the inlet pipe.

In addition, the angle of inclination of the generatrix of the thin layer element is 30-70 ^o .

 In addition, each thin-layer element is made of a set of plates.

 Placing the inlet pipe in the lower part of the device coaxially with the housing allows you to evenly distribute the incoming stream to the package of thin-layer elements. The deepening of the inlet pipe into the housing by an amount equal to 0.1-0.5 of the apparatus height makes it possible to form a storage compartment for collecting the heavy phase in the space between the generatrix of the lower thin-layer element and the upper edge of the inlet pipe.

 Placing a packet of thin-layer elements along the axis of the apparatus and executing each element in the form of a funnel facing down allows maximum use of the useful space of the settler and promotes efficient phase separation.

 The execution of the upper base of the lower thin-layer element damped contributes to the formation of the directional movement of the shared stream.

 The connection of the upper thin-layer element with the housing by means of an annular partition installed in the upper part of the apparatus is necessary so that the shared flow does not pass by the package of thin-layer elements, but is directed into the space between the elements.

 The placement of additional thin-layer elements between the inlet pipe and the lower thin-layer element contributes to the separation efficiency due to uniform flow distribution and preliminary rough separation in the interplate space.

To increase the efficiency of separation of pure flows, the optimal angle of inclination of the generatrix of the thin-layer element to the horizon is 30 ^o , and for spontaneous sliding of the sediment from the surface of the plates of thin-layer elements when separating light and heavy phases containing solids, the optimal angle of inclination of the generatrix of the thin-layer element to the horizon is 70 ^o .

 A thin-layer sump is shown in the drawing, where in FIG. 1 shows a general view of the settler; FIG. 2 - view AA.

The thin-layer sump contains a vertical casing 1 with a nozzle of the input of the shared mixture 2 and nozzles of the output of light and heavy phases 3.4, respectively. The inlet pipe 2 is placed at the bottom of the housing 1 coaxially to it and is buried in the housing at a distance equal to 0.1-0.5 of the apparatus height. A package of thin-layer elements 5 is placed inside the housing 1. Each thin-layer element 5 is made of plates assembled in the form of a funnel facing down with a large base. The upper base 6 of the lower thin-layer element 7 is muffled. The upper base of the upper thin-layer element 8 is connected via an annular partition 9 installed in the upper part of the sump to the housing 1. Between the inlet pipe 2 and the lower thin-layer element 7, one or more thin-layer elements 10 are additionally installed, made similarly to the main thin-layer elements 5. The base of the closest the inlet pipe 2 of the thin-layer element 10 is connected to the upper edge of the inlet pipe 2. The angle of inclination of the generatrix of the thin-layer element to the horizon is 30-70 ^o .

 Thin-layer sump works as follows. A mixture of two immiscible media (light and heavy with a certain content of solid impurities) enters through the inlet pipe 2 into the channels formed by thin-layer elements 5, where separation occurs in the laminar thin layer. The light phase rises upward on the lower surface of the plate surface of the thin-layer elements 5 and is discharged through the nozzle 3 through the gap between the housing 1 and the annular partition 9. The heavy solid phase is deposited on the upper surface of the thin-layer elements 5, along which it slides down and then, without mixing with the main stream , is discharged through pipe 4 from the apparatus.

Claims (4)

 1. A thin-layer sump, including a vertical casing with nozzles for the input of the separated mixture and the output of the separated phases and a package of thin-layer elements located inside the casing, characterized in that the inlet pipe is located at the bottom of the apparatus coaxially with the casing and is deepened by a distance equal to 0.1 - 0.5 the height of the apparatus, thin-layer elements are placed along the axis of the apparatus, and each thin-layer element is made in the form of a funnel facing down, in addition, the upper base of the lower thin-layer element is muffled, and the upper thin-layer element with It is single with the body by means of an annular partition mounted in the upper part of the apparatus.  2. The thin-layer sump according to claim 1, characterized in that between the inlet pipe and the lower thin-layer element, one or more thin-layer elements are additionally installed, and the base of the thin-layer element closest to the inlet pipe is connected to the upper edge of the pipe. 3. The thin-layer sump according to claim 1, characterized in that the angle of inclination of the generatrix of the thin-layer element to the horizon is 30 - 70 ^o .  4. A thin-layer sump according to claim 1, characterized in that each thin-layer element is made of a set of plates.

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