DE2225262A1 - Method and apparatus for separating solid particles from fluids - Google Patents

Description

Gloucester Point, Virginia, V.St.A,

Method and device for separating solid particles from fluids

Priority; May 25, 1971 / V.St.A. Registration no .: 148 253

The invention relates to a method and an apparatus for separating solid particles from Fluids.

In recent times particular attention has been paid to, and heard from, the mining of ores from the seabed also the extraction of manganese nodules, which are conveyed through a pipe that extends from one to ore mining

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watercraft deployed from the seabed hanging down extends below. Such a conduit can have a collecting head in contact with the seabed and a Have dispensing head attached to the floating production vessel. Together with the tubers it becomes a large one Amount of air and sea water entrained and must be delivered at the delivery head on board the transport ship or from the tubers to be deposited. Often a foaming three-phase mixture of gas, liquid and solids must be used be separated.

The invention

thus creates a method for separating manganese nodules from seawater, in which a mixture of nodules and seawater is introduced helically into a cylindrical cage, the water being discharged sentrifugally from the helical path and the nodules being recovered at the bottom of the cage. For this purpose, a device is proposed which has a helical line through which the mixture of tubers and seawater is introduced into a permeable cage. A helical baffle runs down the helical conduit into the cage, deflecting the tubers downward as the water is centrifugally expelled through the sides of the cage. If air is mixed into the water, as is the case when using a mammoth pump, this device also separates the air from the seawater for two reasons; and that the apparatus provides first space and conditions that promote the release of air bubbles from the seawater, when the mixture is swirled these two phases from the disposed at the center of the cage to the outer casing toward the outside; and second, the centrifugal force acting on the

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Seawater, which is swirling downwards against the outer mantle, acts in a helical manner, creating an increasing pressure gradient towards the outside in this layer of water swirling down helically, releasing air at the inner radius will.

According to the invention, solid particles can be separated from a fluid stream mixture which is with flows at a high linear velocity and has a liquid and entrained solid particles. In the case of a common wisely used design, this stream is a three-phase mixture of gas, liquid and Solids, which form a foaming stream of liquid and gas in which solid particles are suspended. Generally speaking, the method according to the invention provides a stream of liquid and solids within one Porous walls having tube, which is cylindrical overall, in substantially to the inner surface of the tube tangential direction, to discharge the liquid through the porous walls of the tube, while the flow is moving moved helically around the inner surface of the tube, to retain the solid phase within the tube and recovering the solid from the interior of the cylinder after the liquid has been discharged. The porous tube is arranged as a whole so that its axis extends in the vertical direction, and the flow is in the tube with a downward velocity component initiated. Preferably the liquid dispensed through the porous tube is collected and thereby separated from the gas phase possibly contained therein that the given off Lets liquid impinge on the inner, non-porous surface of an outer container that defines the porous tube

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surrounds, causing the foam to dissolve. The gas phase passes upwards to the outside and the Liquid down through the space between the porous wall and the outer container. To prevent, that liquid is entrained in the gas flowing upwards becomes that which passes through the porous walls Liquid preferably directed downwards. The liquid can be collected again at the bottom of the space will.

In the most preferred embodiment, the particulate-containing stream is on its own Routed way down within the porous tube in a generally helical path, whereby the speed of the particles slowly decreases so that the impact the particles experience is weakened .. That namely prevents the particles from breaking into smaller particles or fines, which are less desirable or harder to use. By directing the flow of the particles in such a way that the particles gradually slow down the invention can be used for a wide range of linear separation of liquid-solid streams Speeds are used.

An apparatus according to the invention for separating solid particles from a liquid containing the solid particles entrains, comprises a generally cylindrical tube with a porous wall and fluid inlet means which is designed and adapted to control the flow of fluid into the top of the tube in generally -jur Wall of the pipe directs tangential direction, the fluid tending to move in a generally helical direction Direction along the inner surface of the pipe wall

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to flow downwards and the liquid exits through the porous wall as the solids slide down within the tube. A helical guide device is preferably provided in the interior of the tube, which guides the solid particles downward in a helical path, namely generally parallel to the longitudinal axis of the tube. This guide means is preferably arranged in the vicinity of the inner surface of the porous wall of the tube at the inlet. It is true that this device is designed for separating streams of fluid flowing at a high linear velocity; but it is often desirable to reduce the linear velocity initially before the flow enters through the inlet. To achieve _r , a curved helical or helical conduit is in fluid flow communication with the fluid inlet. The best results are obtained when the fluid flow inlet has a polygonal, in particular a quadrilateral, cross-section; the line directly connected to the inlet has the same cross-section. In general, a pipe of circular cross-section can be connected to the polygonal pipe by known means.

A collection device is usually provided at the bottom of the porous tube to collect the solid particles. A container is provided around the porous tube to collect the liquid exiting through the porous wall. This container is preferably arranged cylindrical and concentric to the inner porous tube. At the bottom of the container a corresponding device can be provided for collecting and discharging the liquid.

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This device is for separating a three-phase? Mixture can be used, the gas with the liquid passing through the wall and then in the annular space between the pipe and the container flows upwards. In order to increase the efficiency of this separation device in the treatment of a To improve the foaming liquid, the inner surface of the container wall should be arranged as close to the porous tube as that the liquid hits the wall. This encourages the foam to break up. To better prevent that Liquid is entrained with the gas, a deflection device is provided on the porous wall, which the liquid steers down.

The porous wall can be made from a screen which has vertical and horizontal members is formed. The sieve openings should be so small that the solid particles to be separated cannot pass through. The length and diameter of the tube and its porosity should be chosen so that essentially the all liquid can pass through so that it is separated from the solid particles.

The invention is particularly effective for separating seabed-extracted manganese nodules from the seawater. The manganese nodules are often extracted from the sea floor with the help of a mammoth pump system in a three-phase system Air, water (foam) and solids conveyed. The pores or sieve openings should be sized so small that most Tubers or particles do not fit through, although of course there may be fine particles with the fluid can be derived.

The invention is explained below with advantageous details on the basis of schematic drawings of an exemplary embodiment explained in more detail.

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Figure 1 is a partially sectioned front view of an apparatus according to the invention and shows the attachment of a helical deflection device in a cylindrical cage;

Figure 2 is a top plan view of the apparatus of Figure 1;

Figure 3 is a front view of the helical diverter;

Figure 4 is a partial view showing the attachment of the inlet port and helical baffle within horizontal rings;

Figure 5 is an enlarged view, partially in section, of the attachment of the horizontal rings in relation to spray deflectors and support elements of the device according to the invention;

Figure 6 is an enlarged fragmentary view of the attachment of a cover over the manhole Bottom of the jacket of the device according to the invention.

In Figure 1, an outer jacket 20 is shown with an angle iron stiffener 30 at its upper end, which supports a permeable cage, designated as a whole by 21, with the aid of several supports 36, 38. The coat 2O can be used on angle iron legs 22, 24, 26 and 28 with dimensions 15.24 χ 15.24 χ 1.27 cm (6 χ 6 χ 1/2 in.) to be appropriate. An inlet pipe 32 of circular section is mounted in a ring-like 31 and goes for example at the butt weld 35 into a rectangular inlet tube 34, creating a rectangular discharge opening formed with dimensions of 22.86 χ 30.48 cm (9 χ 12 inches) will. A helical deflecting device 42 extends in a helical or helical shape from this opening 40 down to the bottom of the cage. The helical deflection device can be a single, downwardly extending

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Flange 44 include and at the outer edge 46 on a number of the cage circumference delimiting horizontal rings 68 with Measures 0.63 χ 1.27 χ 91.44 cm in diameter (1/4 χ 1/2 χ 36 inches) welded on. The rings 68, in turn, can be at 50.8 χ 0.63 cm (2 χ 1/4 in.) Support members 48 be welded, which extend vertically up and down. On the outside of the Support elements 48 are attached to a plurality of downwardly and outwardly inclined spray deflection members 50, 52, 54, 56, 58 and 60. At A support rim 66 is attached to the underside of the cage 21 which has a plurality of 50.8 χ 0.63 cm (2 1/4 inch) thick support arms 62 and 64 which extend inwardly to support a delivery cone 70 for the tubers. From the cone can a cone extension 72 having an outer diameter of 53.34 cm (21 inches) to an axial one not shown here Lead the bulb collecting vessel.

A floor pan 74 is supported with its axis inclined so that its lower end is 45.72 cm (18 inches) lower lies as its upper end. A normal drain pipe 76 leads from the lower end through which water is drained off, which centrifugally passes through the sides of the cage into those between the cage 21 and the inner wall of the shell 20 formed annulus 23 was released. As FIG. 6 shows, a cover 78 can be placed on the jacket 20 via an access hole be fastened by means of screw bolts 80 with a square head. The bolts are on the sides of the shell 20 through Tack weld is attached and includes a 1/4 inch thick rubber seal 81 and a nut and washer assembly 82 on.

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The device shown here was used to separate tubers from seawater under ambient conditions used, and their output was 60 tons of tubers per hour.

It will be understood that various other types of permeable cages and helical baffles can be used can be used within the scope of the invention, as well as the proposed structure enlarged or reduced can be.

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Claims (1)

Expectations 1. Process for separating solid particles from a fluid that has a liquid-solid suspension, characterized in that a stream of liquid and solids within a porous walls having tube in a direction substantially tangential to the inner surface of the porous wall so that As the flow moves helically around the inner surface of the wall, the liquid passes through the porous wall of the pipe is discharged while the particulate matter is inside of the pipe are retained, and that the solid particles after the liquid has been released from the interior of the Rohres can be obtained. 2. The method according to claim 1, characterized in that the fluid stream of solid particles and liquid in a helical path within the pipe. 3. The method according to claim 1 or 2, characterized in that the liquid discharged through the porous wall is collected will. 4. The method of claim 3, wherein the liquid passing through the porous wall contains entrained gas, characterized in that the mixture of liquid and air in the downward direction against a porous wall around 209850/0 872 giving surface is guided, so that the entrained Gas is separated from the liquid. 5. The method according to any one of claims 1 to 4, characterized in that the fluid flow prior to its discharge into the pipe is passed through a helical line with a polygonal cross-section. 6. The method according to claim 4, characterized in that the fluid mixture is a foaming three-phase fluid with water, Has air and ore nodule particles from the sea floor and flows out of a mammoth pump system. 7. Device for separating out solid particles a fluid, in particular for carrying out the method according to one of claims 1 to 6, characterized by a tube (21) having a porous wall, a fluid inlet (32,34), the fluid in a first end of the tube in general to the wall of the tube tangential direction, and means (70) for collecting solid particles at the second end of the tube. 8. Apparatus according to claim 7, characterized in that a helical guide device within the tube (21) (42,44) provided i.-st that goes with the tube with porous wall is connected to the fluid inlet. Device according to claim 7 or 8, characterized in that ; ß the tube (21) within an outer container (20) 209850/0872 is arranged so that a gap (23) is formed between the tube and the container. 10. The device according to claim 9, characterized in that the container (20) and the tube (21) are substantially concentric Are cylinders, and that a device is provided for collecting the liquid flowing in the space. 11. Device according to one of claims 7 to 10, characterized in that with the porous wall of the tube (21) a Deflection device (50,52 ... 6O) is connected, which directs fluid discharged through the porous wall in the downward direction. 12. Device according to one of claims 7 to 11, characterized in that a helical line in Fluid flow communication with the fluid inlet is. 13. Device according to one of claims 7 to 12, characterized in that the porous wall has a number of horizontal ones Links (68) and vertical links (48) operatively connected to one another at their points of intersection to create a screen are connected. 14. The device according to claim 13, characterized in that on the outside of the screen (48,68) horizontal deflection members (50,52,54,56,58,60) are attached and inclined so that they dispensed liquid through the sieve in a downward direction to steer. 209850/0872