DE3928370A1 - Gravity sepn. of slurry fed into inclined cylinder - to controlled distance by axial feed with annular gap met by radial connectors - Google Patents

Abstract

A slurry contg. particles, esp. of metals, with greater density than the remaining material, and possibly in a wide spectrum of particle sizes, is fed through an axially aligned inlet (3) into the inclined cylindrical housing (1) of a gravity concentrator. The annular space (8) between inlet pipe and housing has on its high side a radial inlet (4) for a sepn. medium, esp. water, and on its low side an outlet (5) for heavy particles. Light fraction material is radially discharged (6) from the upper end of the housing. To allow for differences in density and grain size in the target solids, the slurry inlet is movable axially inside the housing, with the insert distance varying from 0.5-5 times the housing perimeter, insert perimeter is 0.1-0.9 of the housing perimeter. Housing interior and inlet pipe exterior may both be corrugated. ADVANTAGE - Gradual change from turbulent to laminar flow ensures effective sepn. e.g. of particles with density range 2-60 and with min. consumption of water, which can be recycled.

Description

The invention relates to the separation of solids with the help of a liquid, in particular Water, and affects gravity concentrators.

The invention can be used for particle separation with different density or grain size in mining, chemical and petroleum industries are applied where fractionation of particles is carried out got to

The depletion of ore deposits and soaps leads to that in order to satisfy the needs of the People on metals, especially heavy metals, like gold, platinum, tungsten, lead and considering one increasing demand for these metals ever greater Ore volumes must be prepared.

The increasing demands on ecology, one constant increase in the price of electrical energy allows the primary processing methods of mineral substances to differentiate exactly. In this sense they have Gravity conditioning processes are second to none.

Of the known gravity processing equipment are typesetting machines, preparation stoves and Spiral channels spread. All of the devices mentioned are few powerful, and draw the first two devices high water and electrical energy consumption out.

So there is currently a problem, in principle to develop new gravity concentrators that with a high separation effect of the mineral particles due to a minimal consumption of water and electrical energy mark.

The principle of operation of most industrial devices is based on the difference in movement speed the particles of the material to be separated with different Mass in a liquid, e.g. B. in the water. The goods to be separated are different disorders, e.g. B. vibrations in different levels, pulsations, exposed.  

Such disruptions that result in a steadily flowing Current of the material to be separated is introduced, take place locally on a short section, and they allow massive particles (large gold particles, Platinum, bismuth and tungsten minerals) into a heavy one Separate faction with success. The finer particles but (in a grain size range from 5 to 1000 µm), including the particularly fine particles (50 to 40 µm) are not concentrated in the heavy fraction, and they form an easy fraction. The very same Concentration of fine particles takes place in the known Constructions of the concentrators no solution at all.

It's a gravity concentrator (US, A, 41 57 951) known, consisting of a vertical in space arranged hollow housing, which with a on the lower End face of the housing attached inlet port for the separation medium, one on the upper end of the housing attached discharge nozzle for the separation medium and the light fraction and one on the lower front the discharge nozzle for the heavy fraction is provided.

The material to be separated is placed in the gravity concentrator abandoned together with the separation medium. thanks the supply of the separation medium becomes an ascending in the housing Flow of the material to be separated from the inlet port for the separation medium up to the discharge nozzle for the light fraction creates. The easy fraction will moved upward by the flow of the material to be separated and the discharge nozzle for the light fraction carried out, and the heavy fraction with one higher specific weight is in the lower part of the Concentrated housing and over the discharge nozzle for the heavy faction unloaded.

The well-known gravity concentrator is for Separation of a classified enriched good is suitable. In the housing of the gravity concentrator is only a laminar ascending stream of the one to be separated Generated good, causing the transfer of part of the  heavy fraction in limbo is not possible is. This will give you the opportunity to get a high quality Win concentrate reduced. Because in the known Gravity concentrator the friction effect of the particles of the goods to be separated on the inner housing surface is not used, the fine particles of the heavy fraction from the gravity concentrator the rising stream of the material to be separated is discharged, whereby the separation efficiency of the processed material is lowered.

It is also a gravity concentrator (GB, A, 20 03 756) known, consisting of an inclined in the room arranged cylindrical hollow housing that with a Trennwend is provided, which coupled the housing in two Divides chambers by one in the partition housed and with respect to the longitudinal axis of the housing axially arranged pipe in connection stand. The upper end of the housing is with an inlet connection for the material to be separated and the lower front of the case is with a Discharge nozzle equipped for the heavy fraction. The case is also tangential with additional arranged inlet and discharge nozzle for the separation medium and equipped the light fraction.

The whole good to be separated is in Gravity concentrator in the turbulent flow in the Suspended state, creating a high-quality separation of the Particles of heavy and light fractions are not is guaranteed.

The technical one is particularly close Solution that is a gravity concentrator (GB, A, 21 64 589) is composed of one obliquely arranged, elongated hollow housing for accommodation of the material to be separated with an inlet connection for the material to be separated, an inlet connection for the separation medium and with discharge nozzle for the light and heavy fractions of the separated  Good.

In the known gravity concentrator, that a series of successive turbulent Zones are created in which the heavy fraction and the light fraction are separated. The fine particles of the heavy fraction create because of increased turbulence does not affect the bottom of the gravity concentrator to achieve and they will be together carried out with the light fraction. As a result, can the hydrodynamic flow state during the separation of the fractions of the reprocessed material not optimized can be a stream of the material to be separated with local turbulence that is laminar, flow accompanied by the wall effect gradually changes, cannot be generated.

The invention has for its object a To create gravity concentrator in which the hydrodynamic Flow state in the separation of the fractions of the processed material thanks to the production of a Flow of the material to be separated with a local turbulence gradually turning into a laminar flow, which is accompanied by the wall effect, optimized can be what an increase in separation efficiency in the separation of the heavy and light particles of minerals with a wide range of grain sizes guaranteed.

The task is solved in that in a gravity concentrator consisting of a obliquely arranged, elongated hollow housing for accommodation of the material to be separated with an inlet connection for the material to be separated, with an inlet connection for the separation medium and with discharge nozzle for the light and heavy fractions of the one to be separated Good, according to the invention, the inlet port for the Good to be separated on the lower face arranged on the longitudinal axis of the housing and at least part of it inside the housing is introduced, between its outer surface  and a gap is formed on the inner surface of the housing, the one with the socket for the separation medium and to discharge the heavy fraction of the material to be separated is connected, and the discharge nozzle for the light Fraction of the material to be separated on the upper face of the housing is arranged.

It is useful for the separation of a good, whose particles have different densities and grain sizes have, the inlet port for the material to be separated with the possibility of its movement along the longitudinal axis to arrange along the housing.

It is possible that the length is at least one in Part of the inlet connector housed inside the housing for the goods to be separated in a range of 0.5 to 5 of the circumference of the housing cross section.

It is also possible that the ratio of the sizes of the cross sections of the inlet connector for the separating goods and the housing to each other in one area from 0.1 to 0.9.

It is reasonable that the ratio of length of the housing to the circumference of the housing cross section is in a range from 5 to 30.

It is convenient to use the inner surface of the housing designed as a corrugated surface.

It is appropriate to also the outer surface of the inlet connector corrugated for the material to be separated.

It is possible that the geometric shapes of the Cross sections of the housing and the inlet connector for the goods to be separated are similar.

It is also possible that the cross sections of the Housing and the inlet connector for the to be separated Have different geometric shapes.

It is expedient to design the housing in a cylindrical shape.

It is also appropriate to the housing with a rectangular cross-section.  

It is advantageous that the angle of inclination Longitudinal axis of the housing to the horizontal plane 30 is up to 60 °.

The use of the present gravity concentrator allows a compact modular system for Preparation of mineral particles with a wide Grain size spectrum from 5 to 1000 µm in a continuous Creating process, changing density of the goods to be separated in a wide interval of Can change from 2 to 60. The degree of concentration of the particles in this gravity concentrator the value can be 60 to reach. During the operation of such a gravity concentrator the environment is not polluted. The gravity concentrator consumes a minimum Amount of water that can be used repeatedly. The gravity concentrator does not consume any electrical energy or its need for electrical energy is minimal. The required pressure when feeding the to be separated There is good in the housing of the gravity concentrator in a range from 1 · 10⁴ to 3 · 10⁴ Pa.

The invention based on a Embodiment and the accompanying drawings explained in more detail. It shows

Figure 1 shows the overall view of a gravity concentrator according to the invention, in longitudinal section.

Figure 2 shows the section along the line II-II in Fig. 1.

FIG. 3 shows the section A in Figure 1 on an enlarged scale.

Fig. 4 section B in Fig. 1, on an enlarged scale.

The gravity concentrator contains a hollow housing 1 ( Fig. 1) of an elongated shape with a longitudinal axis 2 , which is arranged in space with an angle of inclination γ to the horizontal plane. The size of the angle γ is chosen in a range from 30 to 60 °. The housing 1 is provided with an inlet nozzle 3 for the material to be separated, which is arranged on the lower end face of the housing 1 along the longitudinal axis 2 , an inlet nozzle 4 for the separation medium and a discharge nozzle 5 for the heavy fraction.

The gravity concentrator is also provided with a nozzle 6 for discharging the light fraction, which is arranged on the upper end face of the housing 1 .

In the direction of arrow α, the material 7 to be separated is fed through the nozzle 3 . The nozzle 3 for the inlet of the material to be separated protrudes at least in part into the interior of the housing 1 , so that a gap 8 is formed between the outer surface and the inner surface of the housing 1 . With the gap 8 , the inlet port 4 for the separation medium and the discharge port 5 for the heavy fraction are connected.

In the direction of arrow L, the separation medium is fed into the gap 8 through the nozzle 4 . The heavy fraction 9 is discharged through the nozzle 5 in the direction of the arrow β. In the direction of arrow R, the light fraction 10 is discharged through the nozzle 6 .

Fig. 2 shows the section along the line II-II in Fig. 1. In this specific embodiment of the gravity concentrator, the housing 1 is designed in the form of a cylinder and the gap 8 in the form of a ring.

The inner surface 11 ( FIG. 3) of the housing 1 can be corrugated to increase the roughness of this surface and thereby to retain the heavy fraction in the layer adjacent to the wall.

The outer surface 12 ( FIG. 4) of the nozzle 3 can also be corrugated in order to increase the roughness of the surface and thereby to retain the heavy fraction in the layer adjacent to the wall.

The gravity concentrator operates as follows.

The material to be separated 7 ( FIG. 1), which is a mixture of mineral particles and a liquid, is fed into the interior of the housing 1 through the inlet connection 3 for the material to be separated. The separation medium, e.g. B. water is fed through the inlet port 4 into the gap 8 and mixed with the material 7 to be separated. This creates turbulent eddies in the flow of the material 7 to be separated due to the inhomogeneity of the properties of this material at the moment of mixing with water. As a result of the turbulence, the mixture obtained becomes suspended, and the particles are separated within the material to be separated. The sinking heavy grains forming the heavy fraction 9 are discharged through the nozzle 5 . Part of the liquid is used as the transport stream, which passes into the housing 1 of the gravity concentrator through the nozzle 4 . The light particles of the material 7 to be separated, ie the light fraction 10 , which is entrained by the flow of the material 7 to be separated, which moves upwards in the inclined housing 1 in a tight state, is in the discharge nozzle 6 for the light fraction carried out. During the movement of the material to be separated 7 in the inclined housing 1 , the material to be separated is fractionated under the action of gravity, the frictional force, the ejection force, the resistance to the movement of the mineral particles in the material to be separated, which is caused by the viscosity of the good to be separated. The particularly heavy particles 9 of the material 7 to be separated, which enter the layer adjacent to the wall under the force of gravity, move against the direction of movement of the flow of the material 7 to be separated in the interior of the housing 1 . The formation of the layer on the wall is associated with the friction of the flow of the material to be separated occurring on the inner surface of the housing 1 . The occurrence of local turbulence due to the inner surface of the housing 1 , the outer surface of the inlet connection 3 for the material to be separated and the water flow contribute to the fact that the heavy particles 9 , which move in the layer adjacent to the wall, getting cleaned. After the heavy particles 9 have entered the gap 8 , where they are mixed with the water flow, these particles 9 are additionally cleaned due to local turbulence caused by the inhomogeneity of the properties of the material to be separated at the moment it is mixed with water.

The presence of roughness on the inner surface 11 ( Fig. 3) of the housing 1 and on the outer surface 12 ( Fig. 4) of the nozzle 3 causes local turbulence and promotes the separation of the heavy particles from the material to be separated and cleaning them from the adhering light particles 10 . The local turbulence of the flow of the material 7 to be separated leads to a reorientation of the moving particles 9, 10 in the material 7 to be separated, centripetal accelerations occur, which favor a pre-separation of the particles 9, 10 . The final separation of the particles 9, 10 according to density and grain size takes place in the transition area which arises in the volume of the moving material to be separated between the laminar and the turbulent flow state.

The gravity concentrator according to the invention thus allows the hydrodynamic flow state in the separation of the fractions of the reprocessed material thanks to the generation of a stream of the material to be separated with a local turbulence that gradually turns into one laminar current, which is accompanied by the wall effect, passes to optimize. This creates conditions for an effective separation of the heavy and the light Mineral particles with a wide range of grain sizes created.

The length of the inlet nozzle 3 for the material to be separated inside the housing 1 is 0.5 to 5 of the circumference of the cross section of the housing 1 , which contributes to the fact that an optimal turbulence zone for the flow of the material to be separated 7 with the transition into one laminar flow state is generated. A reduction in the length of the nozzle 3 by a value of less than 0.5 of the circumference of the housing 1 leads to a reduction in the size of the turbulence zone for the flow of the material to be separated and accordingly also to a deterioration in the conditions for the separation of the material into the light 10 and the heavy 9 fraction. Increasing the length of the nozzle 3 to more than five times the circumference of the housing 1 shortens the path of the frictional interaction of the particularly fine particles of the material 7 to be separated on the inner surface of the housing 1 and reduces the possibility of their separation into the heavy fraction 9 and the discharge through the nozzle 5 .

The ratio of the circumferences of the cross sections of the inlet connection 3 for the material to be separated and of the housing 1 to one another is in a range from 0.1 to 0.9. With this ratio, an optimal turbulent flow of the material 7 to be separated is achieved, which gradually changes into a laminar flow, which helps to create the most favorable conditions for the separation of the light fractions from the heavy fractions. A reduction in the size of the ratio to a value of less than 0.1 substantially increases the distance that must be overcome by the mineral particle from the stream of the material 7 to be separated into the wall layer of the housing 1 . At the same time, reducing the size of the ratio to a value less than 0.1 leads to a reduction in the turbulence zone, which has a negative effect on the separation conditions as a result of a joint separation of the light 10 and the heavy 9 fractions.

Increasing the ratio to a value above 0.9 leads to an enlargement of the turbulence zone until it is completely replaced by a laminar zone, which also worsens the conditions for the separation of the material into the light 10 and the heavy fraction 9 .

The geometric cross-sectional shape of the housing 1 can be different, for. B., circle, ellipse, rectangle, which is determined by the properties of the material to be separated. A product that tends to fluctuate and coagulate requires the execution of a round or elliptical cross section of the housing 1 in order to shorten the extent of the zones of local turbulence. A product which is not prone to flocculation and coagulation requires a rectangular cross section of the housing 1 , in which an extended turbulence zone and a gradual transition to a laminar flow state are achieved.

The cross section of the housing 1 and the inlet connection 3 for the material to be separated are designed congruently for the goods which tend to flocculate and coagulate, which is why a shortening of the zones of local turbulence is achieved.

For the goods which tend to flocculate and coagulate, the use of the cross sections of the housing 1 and the connecting piece 3 of different geometric shape is more expedient, as a result of which a turbulence zone which is extensive in cross section is achieved, which changes to a laminar flow state both in section and in length , which ensures a more effective cleaning of the heavy fraction from the light fraction.

The ratio of the length of the housing 1 to the circumference of its cross section is in a range from 5 to 30. With this ratio the optimum value of the wall layer of the material 7 to be separated and a gradual transition of the material from the turbulent flow state into a laminar state are achieved. As a result, a particularly intensive separation of the heavy fraction 9 into the wall layer with the subsequent discharge of this fraction through the nozzle 5 is achieved.

The design of the housing with a length of less than five times its circumference leads to a reduction in the size of the wall layer, shortens the path length where the friction of the material 7 to be separated takes place on the walls of the housing 1 , which worsens the conditions for segregation and the probability that the mineral particles get into the wall layer of the housing 1 is reduced. Shortening the length of the housing 1 also reduces the size of the transition zones from the turbulent flow state of the material to be separated into a laminar one. An extension of the housing 1 to more than thirty times its circumference does not promote additional separation of the particles of the material. The formation of the zones of local turbulence with the transition to a laminar flow state and the separation of the heavy fraction 9 and the light fraction 10 from these zones comes to a conclusion with a length of the housing of less than 30 times its circumference.

The angle of inclination of the housing is in one Range from 30 to 60 ° selected.

With an angle of inclination of the longitudinal axis 2 of the housing 1 of less than 30 ° there is a reduction (to zero) in the movement speed of the mineral particles of the heavy fraction in the layer adjacent to the wall.

An increase in the angle of inclination of the longitudinal axis 2 of the housing 1 to over 60 ° is not expedient since the probability that the heavy mineral particles get into the layer of the flow of the material moving in the housing adjoining the wall is reduced. An optimum value for the angle of inclination of the housing is an interval of 30 to 60 ° at which the highest speed of movement of the heavy mineral particles in the layer adjacent to the wall with the greatest probability that these heavy mineral particles in the layer adjacent to the wall from the total volume of the good to be separated, is achieved.

example

For the determination of the optimal parameters of the Gravity concentrator became several models of such Made concentrators in which the values of the angle of inclination the longitudinal axis of the gravity concentrator to the horizontal plane as well as the values of the ratios the circumference of the inlet port for that too separating good and the housing to each other, the length of the housing and the length of the inlet connector for the Good to be separated can be varied inside the housing. The information is given in Table 1.  

Table 1

Thus, the invention allows by Optimization of the hydrodynamic flow state in the separation of the fractions of the reprocessed material to increase the processing efficiency

Claims (13)

1. Gravity concentrator, consisting of:

• - An obliquely arranged elongated hollow housing ( 1 ) for accommodating the material to be separated, which comprises:
  • - an inlet connection ( 3 ) for the material to be separated,
  • - an inlet connection ( 4 ) for the separation medium,
  • - A discharge nozzle ( 5 ) for the heavy fraction of the material to be separated and
  • - a discharge nozzle ( 6 ) for the light fraction of the material to be separated,

characterized in that

• - The inlet connection ( 3 ) for the material to be separated is arranged on the lower end face of the housing ( 1 ) along its longitudinal axis ( 2 ), so that at least part of it is guided into the interior of the housing ( 1 ).
• - A gap ( 8 ) is formed between the outer surface of the inlet connector ( 3 ) for the material to be separated and the inner surface of the housing ( 1 ),
• - The inlet connection ( 4 ) for the separation medium and the discharge connection ( 5 ) for the heavy fraction of the material to be separated are connected to the gap ( 8 ),
• - The discharge nozzle ( 6 ) for the light fraction of the separating material is arranged on the upper end face of the housing ( 1 ).

2. Gravity concentrator according to claim 1, characterized in that in order to adapt to the density and grain size of the material to be separated, the inlet connector ( 3 ) for the material to be separated can be moved in the longitudinal direction of the housing ( 1 ). 3. Gravity concentrator according to claims 1, 2, characterized in that the length of at least the inside of the housing ( 1 ) part of the inlet connector ( 3 ) for the material to be separated in a range from 0.5 to 5 of the circumference of the cross section of Housing ( 1 ) is 4. Gravity concentrator according to claims 1 to 3, characterized in that the ratio of the circumferences of the cross sections of the inlet connector ( 3 ) for the material to be separated and the housing ( 1 ) to each other is in a range from 0.1 to 0.9. 5. Gravity concentrator according to claims 1 to 4, characterized in that the ratio of the length of the housing ( 1 ) to the circumference of its cross section is in a range from 5 to 30. 6. Gravity concentrator according to claims 1 to 5, characterized in that the inner surface of the housing ( 1 ) is corrugated. 7. gravity concentrator according to claims 1 to 6, characterized in that the outer surface of the inlet port for that too separating goods is corrugated. 8. Gravity concentrator according to claims 1 to 7, characterized in that the geometric cross-sectional shapes of the housing ( 1 ) and the inlet connector ( 3 ) for the material to be separated are similar. 9. Gravity concentrator according to claims 1 to 8, characterized in that the cross sections of the housing ( 1 ) and the inlet connector for the material to be separated have different geometric shapes. 10. Gravity concentrator according to claims 1 to 9, characterized in that the housing ( 1 ) is designed in the form of a cylinder. 11. Gravity concentrator according to claims 1 to 10, characterized in that the housing ( 1 ) is designed with a rectangular cross section. 12. Gravity concentrator according to claims 1 to 11, characterized in that the angle of inclination γ of the longitudinal axis ( 2 ) of the housing ( 1 ) to the horizontal plane is 30 to 60 °.