FI69251C - KONISK SEPARATIONSYTA FOER SEPARERINGSAPPARAT - Google Patents

Description

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Patent No. Melat 10 01 1986 (51) Kv.lk. '/ Lnt.CI.1 B 01 D 25/00 £ ^ Q | y | p | Q (21) Patent application - PatenUnsfikning 802961 (22) Filing date - Ansökningsdag 19.09.80 fFh '' (23) Starting date - Glltlghetsdag 19.09.80 (41) Published public - Blivlt offentlig 20 03 82

National Board of Patents and Registration (44) Date of registration and publication 8 ™ oq 8.

Patent- oeh registerstyrelsen '' Ansökan utlagd och utl.skriften publicerad * * -7 * 0 · 7 (32) (33) (31) Privilege requested - Begärd priority (71) (72) Viktor Alexeevich Berger, Shelkovichnaya ulitsa 184, kv . 65,

Saratov, Gennady Grigorievich Korobov, Prospekt Kirova, 14/16, kv. 45, Saratov, Stanislav Alexandrovich Kosygin, Shelkovichnaya ulitsa 180, kv. 17, Saratov, USSR (SU) (74) Oy Koister Ab (54) Separate conical separating surface - Konisk separationsyta for separating tails The present invention relates to a device used for separating dispersed systems on the basis of their phases specifically from a conical plate separator.

The invention can be applied to the fine cleaning of lubricating oils, fuels and cutting coolants from mechanical impurities.

It is already known to use a conical plate for use in a separator, the conical part of which has both an inner and an outer bead and the radial ribs on the conical surface 1. partitions of 4-12 pieces. However, there are some drawbacks to this structure.

First, the particles deposited on the conical surface of the dish are subjected to a certain hydraulic force generated by the radial movement of the liquid relative to the surface of the dish, which promotes po. particle removal with the purified liquid.

Second, because the plate has 4 to 12 partitions, they do reduce the removal of particles with the purified liquid to some extent, but at the same time they increase the vortex formation of the discharge flow, which causes vortices between two adjacent plates of the plate group.

2 69251 These disadvantages occur in all conical plates with radial partitions.

In addition, a conical plate structure is known in which the conical part likewise has outer and inner spheres and protrusions therein.

This disc structure has guide plates on the conical surface. The geometric projection of each such plate into a plane perpendicular to the axis of rotation is part of a multi-helical helix. At each point in the coil, the angle between the flow rate vector and the tangent is 30-60 ° in the case of the dispersion phase exit direction. The height of the guide plates is 0.2 to 0.5 of the height of the protrusions, and the flow side edge of each plate forms an angle of 90 ° with the surface of the plate. Indeed, this baffle structure has been found to promote the separation of solid particles and reduce their removal with the purified liquid.

However, as the liquid flow rate and viscosity increase, and as the difference between the respective mass densities of the particles and the purified liquid decreases, the cleaning efficiency decreases. This is because the settling particles move along the flow lines in the plates, subjecting them to the outflow of purified liquid.

The present invention seeks to develop a conical plate for a separator whose guide plate structure reduces the amount of fine particles escaping with the purified liquid.

According to the invention, this is achieved in that the conical part of the conical plate has either inner or outer ribs. In addition, guide plates are attached to the inner or outer surface of the conical part, which are then arranged so that their projection on a plane perpendicular to the axis of rotation of the plate is part of a multi-threaded coil. In the structure according to the invention, the guide plates are constructed so that their height corresponds to a predetermined distance between two adjacent conical plates of the separator plate group. The baffles divide the surface of the conical portion of the dish into several separate channels, each with a fluid flow during the separation process.

It is important that at each point on each baffle the angle between the base line of the side surface of the dish and the line perpendicular to the baffle, which includes that point, is greater

It 69251 3 as the angle of friction between the deposited material and the surface of the dish.

In addition, it may be advantageous for the edge of each guide plate for particle deposition to be inclined at an angle of 15-30 ° to the side surface of the dish, and further for the ratio of the space between adjacent guide plates (at the circumference of the smaller circle of the dish) to 0.1 : 1 - 0.3: 1.

When such conical plates are used in a group of separator plates, the degree of separation of the dispersion systems is considerably improved, i.e. the removal of impurities from the liquids is more efficient.

The invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1 is a separator-Messa, according to a longitudinal section of the present invention used in the conical tray; Figure 2 is drawn in the direction of arrow A of Figure 1 in the direction, Figure 3 is a section on the line III-III in Figure 2 a and showing a guide plate for the separation of heavy particles and Fig. 4 is a section along the line IV-IV in Fig. 2 and shows a guide plate for a plate for separating light particles.

The conical part 3 of the conical plate according to the invention has an outer sphere 1 (Figures 1 and 2) and an inner sphere 2. They are fixedly connected to guide plates 4 arranged either on the inner or outer surface of the conical part 3 of the plate. In the structure now described and shown in the figures, the guide plates 4 are arranged on the inner surface of the conical part 3.

The height "h" of the guide plate 4 corresponds to a predetermined distance between two adjacent cone plates (the adjacent plate 5 is shown in Figs. 1-4 in thin lines) when the plates are connected as a plate group of the separator 1.

The conical surface of the plate is divided by guide plates 4 into several separate channels in which the liquid flows during the separation process.

The geometric projections of the plates 4 in a plane perpendicular to the axis of rotation define a part of the multi-helix (Fig. 2). Its shape is determined by the fact that the angle formed between the line perpendicular to the guide plate 4 at each point and the base line of the side surface of the dish, po.

69251 inclusive, is greater than the angle of friction between the deposited material (precipitate) and the surface of the dish.

The height "h" of the plates 4 corresponds to a predetermined distance between the plates of the plate group, i.e. it always delimits the space between two adjacent plates.

Depending on the size of the particulate material to be separated from the liquid, edges 6.7 having an angle of inclination / S with respect to the surface of the plate of 15-30 ° are formed on either the concave or convex side surfaces of the plates 4.

If po. the angle is less than 15 °, then the MiL-like channel into which the precipitate settles comprises the main part of the channel formed between the adjacent plates 4. In this case, it is to be feared that the precipitate 8 will clog the po. channel fast. On the other hand, if the angle is more than 30 °, the separation function of the settled particles is impaired.

The ratio of the distance "n" between the adjacent plates 4 (this is the circumference of the smaller circle of the dish) to the length of the base line "1" of the dish is 0.1: 1 to 0.3: 1.

When the ratio "n: 1" is less than 0.1: 1, the dimensions of the channels between the adjacent plates 4 become too small for the fluid flowing in the laminar flow. On the other hand, if po. the ratio is greater than 0.3: 1, the channels become too large, again creating vortices and eddy currents.

The notch 9 in the smaller circumference of the plate holds the plate in a certain angular position when it is connected to the plate group of the separator.

The liquid separation process is described in more detail below.

The figures show two adjacent rafts. The phases of the suspension 1 slurry are separated in the space between adjacent plates when the plates are grouped together and rotate.

When a relatively heavy fraction (heavy particles) has to be separated from the liquid, the flow is directed from the circumference of the dish to its center. The liquid comprising solid particles enters the interior of the dish through openings formed between the flanges 1 of adjacent plates and then continues to flow along the channels formed between adjacent pairs of plates 4. As the liquid flows through the channels in the conical part 3, the particles with a specific gravity heavier than the liquid move towards the inner part of the plate in question. Figures 1 and 2 illustrate situation (position) A, which corresponds to the initial stage of the separation process, and situation (position) B, which 60251 s corresponds to the end of the process in the case of particle 8. The settled particle 8 is then affected in position B by a hydraulic force "X", the vector of which comes at the same point as the direction of fluid flow, as well as by the centrifugal force "F". As a result of both of these forces, the particle moves along the surface of the plate in the direction of the resultant force towards the concave edge 6 of the plate 4, along the path "b" (Fig. 2), and possibly moves from position B to position C.

This event increases the efficiency of the separator because it promotes the distribution of liquid and sediment flows.

When the space between the plates is relatively small, even fine particles accumulate at the edge 6, which in the separators hitherto almost always leave with the outflow of the purified liquid.

When the edge 6 is at a certain angle of inclination with respect to the surface of the plate (Fig. 3) along the entire length of the plate 4, it delimits a channel in which the liquid flow rates decrease sharply as the height of the wedge-shaped channel decreases (the hydraulic force "X" acting on the particle 8 is small). Instead, the centrifugal force has a perpendicular component "F" which pushes the particle against the edge 6, as well as a tangential component "F" which pushes the particle in the direction of the dirt collector opposite to the direction of the purified liquid outlet pipes. Therefore, the particle 8 cannot leave the separator with the liquid purified therein, but its transfer to the dirt-winding device is enhanced.

When the liquid is separated from particles having a specific gravity lower than the specific gravity of the pure liquid, the flow is directed from the center of the plates to their circumference, the liquid then flowing into the space between the plates from the openings delimited by the inner slits 2 of adjacent pairs of plates. The inclined edge 7 is then made on the convex side of the plate (Fig. 4), i.e. plates comprising such a baffle structure 4 are used po. separation method.

Separators with plates according to the invention have been found to retain particles of up to 1-3 microns and also larger and are intended to replace expensive fine cleaning filters, e.g. 5 micron fine filters, with a dirt separation capacity of only a fraction of the efficiency of plate group separators.

Claims (4)

6 Claims 6 9 2 51 A conical plate for use in a separator, the conical part having an outer surface and an inner sphere and guide plates fixed to either the outer or inner surface of the conical part and arranged so that their projection on a plane perpendicular to the axis of rotation of the plate is part of a multi-turn coil. the guide plates (4) are constructed so that their height (h) corresponds to a predetermined distance between two adjacent conical plates of the separator plate group, the surface of the conical part of the plate being divided po. with baffles into several separate channels, each with a fluid flow during the separation process. Conical plate according to Claim 1, characterized in that at each point of the guide plate (4) the angle po between the base line and the perpendicular line of the side surface of the plate. is greater than the angle of friction between the separated material (8) and the surface of the dish. Conical plate according to Claim 1 or 2, characterized in that the edge (6 or 7) of each guide plate (4) to which the agglomerated particles (8) adhere is arranged at an angle of inclination of 15 to 30 ° with respect to the side surface of the plate. Conical plate according to one or more of Claims 1 to 3, characterized in that the ratio of the distance (n) between the adjacent guide plates (4) in the case of the circumference of the smaller circle of the plate is 0.1: 1 to 0.3: 1. Il