DE2649598C2 - Centrifugal magnetic separator - Google Patents

Description

3. Fiiehkraft magnetic separator according to claim 1, characterized in that the bands of the Magnetic flux interrupters are endless belts and adapt to the shape of the sections assigned to them (4, 5) of the housing (3) are adapted.

4. Centrifugal Magretsche ^ he according to claim 3, characterized in that the housing ·! Is circular) a common endless belt (17) for the curved portions (4) '.

5. Fiiehkraft magnetic separator according to claim 3 or 4, characterized in that each magnetic flux interrupter (17, 18, 19) is equipped with an individual, adjustable drive.

6. Fiiehkraft magnetic separator according to claim 4 or 5, characterized in that all magnetic flux interrupter (17, 18, 19) are equipped with a common drive.

7. Fiiehkraft magnetic separator according to claim 1, characterized in that each magnetic flux interrupter in the form of a limited band (frame with windows 5) and with the Drives (21) for the reciprocating movement is in connection.

8. Fiiehkraft magnetic separator according to claims 1 -3, characterized in that the distances between the straight sections (5) of the housing (3) and the magnet systems (14) Screw connections are adjustable.

9. Fiiehkraft magnetic separator according to claims I and 7, characterized in that at least a section of the housing (3) a step (24) which widens in the direction of flow has, whose end face is provided with a gap and which via a pipe (27) with a control valve (28) is in connection and that a magnet system is arranged behind the gradation (24).

The invention relates to a magnetic separator with a non-magnetizable housing.

Magnet systems for the generation of magnetic fields, one feed and several discharge nozzles. This can be used for wet as well as dry separation of strongly or weakly magnetic ores.

A magnetic separator is known (SU-Urheberschein 4 30 889), which is used for wet processing of strongly magnetic Ores is intended and consists of an airtight housing, which rotating Includes magnetic flux sources and inside the

ore stream to be processed is promoted by means of water. There are a loading and two unloading nozzles for Removing the magnetic and non-magnetic fractions arranged, the discharge nozzle through an adjustable separator at the end of the spiral

H wall are separated from each other. When fed under The ore stream to be processed is subjected to the action of centrifugal forces and pressure in the spiral housing Subjected to magnetic forces which have opposite directions. The stream of the to be reprocessed

Ore in the spiral housing runs against the direction of rotation of the magnetic flux sources.

The - together with the non-magnetic fractions - by the centrifugal forces on the outer wall of the Housing flung magnetic fraction is

attracted by the magnetic flux sources to the inner wall of the housing and thus to the discharge port for the magnetic fraction promoted The non-magnetic fraction is caused by the centrifugal forces on the outer wall of the housing and thrown by the speed

The operating pressure of the ore stream to be processed is conveyed to the discharge nozzle for the non-magnetic fraction, which is arranged at the end of the spiral housing.

The magnetic fraction is over the inner wall of the housing from the effective range of the rotating Sources of magnetic flux removed in the discharge device, gets into the current of the non-magnetic Fraction, which deflects the direction of travel of the magnetic fraction by 150 °, is adjustable by means of the Separated partition wall and through a discharge nozzle

<·> Carried out. The unrr. .Genefish faction will participate in the promoted other side of the partition and removed through a second discharge port.

However, the separation of the magnetic fraction according to the known method causes one

■ * 5 Increase in the magnetic flux in the separator, what then leads to the formation of agglomerates of the magnetic fraction, which in the movement of the Outer wall to the inner wall of the housing during agglomerate formation particles of the non-magnetic frac-

take it with you. The low speed of the magnetic flux sources does not allow the agglomerates of the destroy the magnetic fraction by rolling it off on the inner wall of the volute. Particle the non-magnetic fraction. In

^In practice, only an insignificant part of the non-magnetic fraction carried along by the flakes is thrown onto the outer wall of the spiral housing by the centrifugal forces.
There is also a disadvantage of the known separator

w> in need of forced promotion of the magnetic fraction on the inner spiral wall of the housing against the direction of travel of the material to be processed Ore stream. This also causes and eliminates an increase in the intensity of the magnetic flux sources

'' ■ the possibility of preparing a stream weak magnetic ore.

Another disadvantage of the known separator is the generation of an ongoing low-frequency

quent magnetic flux from rotating magnetic flux sources behind the inner wall of the spiral housing. The low frequency of magnetic flux does not allow the agglomerates of the magnetic fraction to be destroyed and makes it easier to take away of particles of the non-magnetic fraction through the agglomerates. An increase in the speed of rotation Magnetic flux sources can not be made in view of vibration problems caused by Inadequate exact dynamic balancing of the bulky assembly causes the magnetic flux sources will.

Yet another disadvantage of the known separator is the need to change the Direction of movement of the magnetic fraction by 150 ° at is Discharge of the latter aas the spiral housing through the at great speed running stream of the non-magnetic fraction. This results in a renewed mixing of the already separate products and thus a low selectivity of the processing and losses of magnetic Fraction.

The known magnetic separator does not allow the process of Processing of strongly magnetic ores with regard to the regulation of the content of the magnetic fraction in the Controlling the concentrate and the outlets is not necessary for processing weakly magnetic ores suitable and for fractionating a stream of the strongly magnetic ore to be processed into only two Low selectivity products determined.

It is also a means for separating the weighting agent from coal slurry Mitteis an alternating magnetic field is known (US-PS 29 73 096), wherein the weighting of s ~ <a current flow through a pipe is separated from carbon slurry. It is pressed to one side of the pipe and displaced to discharge by a traveling magnetic field. In the process, however, agglomerates of the weighting agent are formed, which take hold of non-magnetic fractions and reduce the effectiveness of the treatment.

Another well-known decay is used for separation of non-magnetizable metal bodies by magnetic means (DE-PS 7 29 008), with a magnetic Alternating field is used to generate eddy currents in the non-magnetizable metal bodies and these are thus pulled out of the surrounding non-metallic mass by the alternating field will. A separation of magnetizable and non-magnetizable Steffen, however, is not possible possible.

Finally, there is a method and a device for separating substances of different susceptibility known (DE-AS 10 61 714), in which a periodically pulsating magnetic field is arranged. This The method and the device for this are primarily suitable for separations of small amounts in the Laboratory, but not for a large-scale application.

The invention is based on the object of an improved centrifugal magnetic absorber for processing magnetic ores to indicate the simple design of a controllable decomposition of a current of ore to be processed into several fractions, one & 5 Separation of the treatment products with adjustable content of magnetic fraction at a high level The selectivity of the processing and, in particular, the processing of weakly magnetic ores are guaranteed. This object is achieved in that the housing alternates with curved and straight sections is provided and between the sections of the housing and the magnet systems interrupter of the Magnetic flux are arranged, which are made of magnetic material and a movable band exist with windows, the dimensions of the windows as well as their speed of movement depending are of the desired frequency and strength of the magnetic flux and that at the end of each rectilinear Section discharge nozzle arranged between the magnet systems and with adjustable locking devices are provided.

According to a development of the invention, the number of rectilinear sections that of the magnetic fractions taken at the end of each of these sections.

It is particularly advantageous to design magnetic flux interrupter as endless belts which are attached to the mold the housing sections are adapted to them.

Each magnetic flux interrupter can i .; Shape of a revolving endless belt made of non-magnetic material be carried out with windows, with the partitions between the windows made of a r.iagnetischen material are made, with the size and speed of the window movement the duration of the magnetic flux impulses that form the layer of the magnetic fraction and one Promote reduction of the agglomerate size in this layer. The ones on the rounded housing sections arranged members of the magnetic flux interrupter can be united and as a common be designed circular endless belt.

Magnetic flux interrupters as endless belts can be equipped with adjustable individual drives that set the belts in rotation. Magnetic flux interrupters can be used as limited bands can be equipped with adjustable individual drives that set the belts in a back and forth movement. It is also advantageous to provide magnetic flux interrupter with a controllable common drive.

In the centrifugal magnetic separator for processing magnetic ore, some of the straight Housing sections arranged magnetic flux sources are designed to be controllable, the thereby changing strength of the magnetic flux adjusts the content of the magnetic fraction in the concentrate. In addition, magnetic flux sources with magnetic flux interrupters can be mounted behind the discharge connection thereby intercepting the layer of the magnetic fraction and promoting it Layer to the discharge nozzle are favored.

It is advantageous to have at least one gradation inside the airtight housing of the centrifugal magnetic separator provide, which expands in the direction of flow of the ore to be processed; in the front wall of the A slot is provided through which an ascending current flows in the same direction is fed to another fluid medium that flushes the magnetic fraction and the non-magnetic fraction of the ore stream to be processed is thrown away.

This gradation can be at the junction between a rounded and a straight line Housing section or in front of the discharge nozzle for discharging the concentrate and the intermediate products

to be ordered. Behind the gradation, a longitudinal partition can be arranged, which is a Mixing of the magnetic and non-magnetic fraction of the ore stream to be processed is prevented. In the centrifugal magnetic separator for processing magnetic ore, it is advantageous to use the straight-line To equip housing sections on the inside additionally with magnetic flux sources with magnetic flux interrupters; an additional discharge nozzle provided with an adjustable slide can be arranged which is also on the inside of the housing.

The design of the separator enables the separation of the flow to be regulated to be regulated magnetic ore into several fractions and a separation of processing products with adjustable Magnetic fraction content. The separator according to the invention also enables the To carry out processing of weakly magnetic ores.

The invention is illustrated below by means of exemplary embodiments with reference to the drawings explained in more detail. It shows

Fig. 1 is a perspective view of an inventive Centrifugal magnetic separator for processing magnetic ores;

2 shows a kinematic diagram of the movement of various particles of the ore to be processed in Interior of the case;

F i g. 3 a schematic representation of the centrifugal magnetic separator according to the invention;

4 shows a cross section (IV-IV in FIG. I) of a centrifugal magnetic separator according to the invention;

5 shows a cross section (V-V in FIG. 3) of a centrifugal magnetic separator according to the invention;

Fig. 6 is an overall view of a magnetic flux interrupter;

7 shows a longitudinal section (VII-VII in FIG. 6) of a Magnetic flux interrupter;

8 shows a schematic representation of a centrifugal magnetic separator according to the invention, in which Magnetic flux interrupters and sources of magnetic flux are arranged on the inner sides of the housing; 9 shows a cross section IX-IX of the magnetic separator shown in FIG. 8:?;

Fig. 10 is a longitudinal section of the
Place where a gradation and
are arranged;

Fig. II a cross section (XI-XI in Fig. 10) of the housing with a plan view of the end wall of the Gradation;

Fi g. 12 one. Overall plan of the arrangement of several magnetic separator according to the invention for processing magnetic ores.

The same parts are provided with the same reference symbols in the figures.

The centrifugal magnetic separator according to FIG. 1 contains a vertical frame 1, on the pillars of which brackets 2 are attached on both sides. At one of these Brackets 2 are cantilevered an airtight fixed housing 3 attached, which is made of non-magnetic material is manufactured and has curved sections 4 and rectilinear sections 5. The number of these Sections can be different and corresponds to the number of at the end of each of these sections removing magnetic fractions. In the drawing, for the sake of simplicity, the design is one Magnetic separator shown, each with two such

Housing on which a partition wall sections are provided. The housing 3 has a Outer wall 6 (FIG. 2) and an inner wall 7. In the following, reference is essentially made to FIG taken.

This housing 3 is at the end of one of the rounded sections with a loading connector 8 for feeding under pressure of a stream of ore to be processed, which is supplied in the form of a liquid medium, Mistake. At the end of one of the straight sections 5

: n a discharge nozzle 9 is provided for discharging the concentrate, while at the end of the other straight line Section 5 discharge nozzles 10 and 11 for discharging an intermediate product or the outlets are arranged.

; ι The cross section of the nozzle 10 is the same as that of the nozzle 8. The unloading nozzles 9, 10, 11 are provided with adjustable slides 12. On the outside the curved portions 4 of the housing 3 are sources 13 for a permanent magnetic flux and on the

. "> ÄuGenseiie uci rectilinear sections 5 of the housing 3 sources 14 arranged for a magnetic flow. The magnetic flux sources 13 are stationary attached to the frame 1 and the magnetic flux sources 14 cantilevered on the brackets 2 (Fig. I). Between

r. Sections of the housing 3 and the magnetic flux sources 13, 14 are multi-link magnetic flux interrupters 17, 18 arranged.

every link of the magnetic flux interrupter is in Gest £. < an endless belt made of non-magnetic

ίο Material with windows 15 (Fig. 5) executed. the transverse partitions 16 of this band are made of magnetic material.

The width / + / of the windows 15 (Figs. 6 and 7) and the Distance / + / between them, d. H. the width of the

The partition 16 should be greater than the distance "I" between the planes of adjacent magnetic poles or magnetic pole groups (13 in FIG. 4) lying at the edges, ie / + /> /.

One of the magnetic flux interrupters 17 is cylindrical designed and includes all curved portions 4 of the housing 3. This member is cantilevered attached to the console 2

The other magnetic flux interrupter 18 (Fig.2) have an elongated shape and are on the straight

• 15 sections 5 of the housing 3 arranged each of the curved sections 4 of the housing 3 can be provided with a single breaker 19 (Fig.8, 9) which is similar in shape to these sections.

In the embodiment of the centrifugal magnetic separator described here, all magnetic flux interrupters have a common control drive 20 ^ v i g. 1). It should be pointed out, however, that each magnetic flux interrupter can have an individual control drive 21 (FIGS. 5, 6) which sets these members in a rotary motion or to and fro

To regulate the content of magnetic fraction in the concentrate, part of the magnetic flux sources 14, which lie next to the rectilinear sections 5 of the housing 3, executed adjustable, with either the Sources 14 can be adjusted in relation to the housing 3 or the intensity of the magnetic flux of these sources 14 is regulated. To collect the magnetic fraction and to convey this fraction into the Discharge nozzles 9 and 10, it is expedient to place magnetic flux sources 22 with interrupters 23 behind these nozzles to arrange.

Inside the hermetically sealed housing 3

a step 24 (Fig. 10) is provided, which expands the housing in the direction of travel of the ore stream to be processed. In the end wall 25 (Fig. II) of this step 24, a slot 26 is provided through which in the same R ^; caution an ascending stream of another flow medium is fed, which favors an enrichment of the stream of the magnetic fraction. Water is supplied through a nozzle 27 with an adjustable slide 28.

In the exemplary embodiment described here Magnetic separator is the step 24 in front of the discharge port 9 and behind her is a longitudinal one Partition 29 arranged, the mixing of the separated by the gradation magnetic and non-magnetic fraction prevented. The gradation 24 can also be at a connection point of the rounded with the straight sections 4 and 5 of the housing 3 or at all at any section of the Housing 3 are arranged (these modifications of the device are not in the drawings shown).

Each section of the housing 3 can also be added to the inside of the housing 3 (FIG. 8) Magnetic flux sources 30, 32 and magnetic flux interrupters 31, 33 are provided. This allows from the A fine magnetic fraction is deposited into the ore stream to be processed, and from it a layer of magnetic Fraction formed on the inside of the housing 3 and this through discharge ports 34, 35 and the adjustable Slide 12, which are also mounted on the inside of the housing 3, are unloaded. aside from that can thereby reduce the intensity of the magnetic flux at the magnetic flux sources that are connected to the Outside of the housing 3 are arranged and the inner wall 7 of the housing 3 is against intense Wear protected. To process magnetic ores, a shaft 36 (Fig. 12) several centrifugal magnetic separators can be mounted in parallel.

In Fig. 12 the arrangement of series-connected Apparatus of a processing plant is shown in which a simplified technological scheme is carried out using the magnetic separator according to the invention. In this scheme there is a bunker 37 for delivered ore via a feeder 38 and belt conveyor 39 with a mill 40 for ore comminution tied together. The mill 40 is via a sump 41, a pump 42 and a pressure vessel 43 to Charging three centrifugal magnetic separators 44 with a stream of ore to be processed under constant Pressure connected to the centrifugal magnetic separator 44. The magnetic separators 44 are connected to the mill 40, a vacuum filter 45 and a drainage trough 46 connected.

The operation of the centrifugal magnetic separator according to the invention for processing magnetic ores proceeds in the following way.

A stream "a" (F i g. 3) of the for-magnetic ore under constant pressure from the pressure vessel 43 (FIG. 12) 8 (Figure 3) printed in the charging stub During the course of the reprocessed stream "a" by a rounded Section 4 of the housing 3 acts on this ore flow centrifugal forces Fc (FIG. 2), which are directed onto the outer wall 6 of the housing 3, and forces Fm of the magnetic flux which act in the same direction as the centrifugal forces Fc . Only the centrifugal forces Fc act on the particles "q" of the non-magnetic fraction, while the

Particle "e" of the magnetic fraction is the centrifugal force Fc and the forces Fm of the magnetic flux act.

The absolute value of the forces Fm acts of the magnetic flux ve to the magnetic particles, "is dependent on the intensity of the magnetic flux, which is reduced in the area of the cross section of the housing 3 in the direction of the inner wall 7 and sufficient for the displacement of the fine-grained fraction magnetic particles from the inner wall 7 to the outer wall 6 of the housing 3 must be.

The force Fv of the velocity pressure of the ore flow to be processed "a" is determined by the components of the separator, the maximum grain size of the ore flow particles, the ore flow mass and the velocity pressure losses and should have the maximum permissible value in each given case.

The design of the separator according to the invention enables high optimal ore flow speeds, especially in the dry processing of magnetic ore, over 20 m / s.

For example, a particle with a volume of 0.01 cm ^{3 of} the magnetic fraction of a magnetite ore and hematite ore, the ^{density of which is 5.1-5.3 g / cm 3} , with a radius of curvature of the outer wall 6 of the housing 3 of 1000 mm acts a centrifugal force Fc equal to 3.1 N, while a centrifugal force equal to 1.05 N acts on a particle of the same size of the non-magnetic fraction quartz, the density of which is 2.7 g / cm ^{3, that is, three times smaller} . Thus, relatively large particles "e" of the magnetic fraction in the curved section 4 are pressed against the outer wall 6 of the housing 3 by the total force "P" and displace the particles "q" of the non-magnetic fraction, on which the much smaller total force "P \ « Acts on the surface of the layer of the magnetic fraction, whereby both vectors» Ρ «and » P \ « in the direction of flow of the current » a «of the ore to be processed have positive components.

The difference between the effect of the centrifugal forces Fc and the forces Fm of the magnetic flux on the magnetic and non-magnetic particles "e" and "q" of the fine fractions is small, but it does exist. Therefore, the force Fv of the velocity pressure of the ore to be processed and the magnetic flux sources 13 should be mutually coordinated as a function of the aforementioned difference in the total forces which act on the fine magnetic and non-magnetic fraction.

In the given embodiment of the centrifugal magnetic separator, the speed of the flow medium at the inlet is assumed to be 3.4 m / s and the intensity of the magnetic flux on the inner wall 7 of the housing 3-600Oe for wet processing of a strong magnetic ore. The forces Fv, Fv \, Fv2 at the velocities of the flows "a", "e" and "K" in the interior of the housing 3 are transmitted over a wide range through the outlet of the treatment products "b", "c", "d" the adjustable slide 12 arranged on the discharge nozzle 9, 10, 11 is regulated as a function of the duration of action of the magnetic flux 13 on the ore to be processed, which runs through the curved section 4 of the housing 3

The interrupter 17, which operates at a certain frequency, is the one generated by the sources 13 xnagueuSCiie l ^ süCtnUu m a puiSicrenuen ι iUu converted When the magnetic partitions 16

(Fig. 5) come to rest over neighboring magnets of the sources 13, the magnetic current is through the Partition walls 16 closed, and its effect on the ore stream to be processed, which is rounded in the ; Section 4 is running will be interrupted. During the

'■ Periods of time during which the window 15 over

(adjacent magnets, the magnetic one acts

^: Flow to the ore stream to be processed with a

K magnetic field, which is equal to the maximum.

.) 'Thus the magnetic flux acts during the pulse duration

to the magnetic fraction "e" of the. ;; Ore stream flowing in the curved section 4 of the

ΐ Housing 3 runs and draws a micro portion

Outer wall 6 (Fig. 2) with a force Fm. The particles ;;; "Ee" of the magnetic faction are also replaced by the

i centrifugal forces Fc pressed against the outer wall. The parts

% »Q« of the non-magnetic fraction, which is only available through the

Centrifugal force Fc are pressed against the outer wall 6, are pushed by the particles "e" to the surface of the layer of the magnetic fraction, since the total force P acting on the particles "e" is considerably greater than the total force P \ , which acts on the particle »shipowner non-magnetic fraction acts. Particles "q" pushed onto the surface of the captured micro-portion of the magnetic fraction are carried along by the ore stream "a" to be processed, which runs over the particles at great speed.

$ If the action of the magnetic flux is interrupted

'4 momentum on the micro-portion of the particles "e"

'* this portion through the ore stream to be processed "a"

promoted to the next following magnet of different polarity of the magnetic flux source 13. The size of the V micro-portions of the particles is the magnetic flux in-

'k intensity proportional and the pulse duration of the magnet

; flow inversely proportional. The pulse duration of the

) \ Magnetic flux is determined by the running frequency of the

τ! Interrupter 17 regulated. The entrainment of non-magnetic

'{-l shear particles »q« due to the microportion of magnetic

■ ;; = ■ shear particle "e" is the size of the microportion

f i dependent. The inventive design of the magnet

yy,; Scheiders enables the process of the formation of

■; ^; Microportions of magnetic particles "e" in the distance

; f area to regulate?> nd thus a layer of

h magnetic fraction and its strength to shape that

'j through the ore stream "a" to be processed on the

;, j outer wall 6 of the housing 3 for rectilinear

· ', * Section 5 is funded. Since the conveyor speed

| jj speed of the layer moving on the outer wall 6

p of the magnetic fraction in relation to the running

|; speed of the ore flow to be processed "a"

U is low, this layer protects the outer wall 6 from

I] intense wear and tear.

Ü In the space of the straight section 5 of the

§ Housing 3 (F i g. 2) is the action of centrifugal forces

p interrupted on the flow rates. You just will

* 1 by the hydraulic speed pressure

|| pushed. The layer of the magnetic fraction will be

l'l by the force Fv \ of the velocity pressure on the

j | Outer wall 6 kept moving while the

p particle q of the non-magnetic fraction in the rest

|| Space of the rectilinear section 5 by the force

yy | of the speed pressure Fv , the

ψ considerably exceeds the first force Fv ^

p The layer containing the magnetic fraction

f§ mainly digested grains of the magnetic

Il see minerals and adhesions that result from magnetic

5! and non-magnetic mineral. On the

H space of the rectilinear section 5 is almost open

its entire length a magnetic alternating flux through the fixed magnetic flux source 14 and the elongated magnetic flux interrupter 18 moving at a certain frequency is generated. Here can this device is removed by a controllable drive either in front of the outer wall 6 of the housing 3 or moved closer, whereby in the rectilinear section 5 the magnetic flux intensity is changed.

A weak alternating magnetic flux can be caused by the force Fm \ (F i g. 2) inside the housing 3 on the outer wall 6 z. B. hold back only disrupted particles "e" of the magnetic fraction. The adhesions "K", which have a larger volume than the disrupted particles "e" , are flushed out of the formed layer of the disrupted particles "e" of the magnetic fraction and promoted by the force of pressure Fv ₁ . The unlocked particles of the magnetic mineral are settled by the force of pressure Fv \ , the total vector P _{2 of} all forces is directed in the direction of the shift of the layer of unlocked particles "e" of the magnetic mineral.

The non-magnetic fraction is conveyed at high speed V.

When the slide 12 of the loading nozzle 10 is wide open (FIG. 3), the only partially open slide 12 of the discharging nozzle 9 (FIG. 2) releases particles "e" of the magnetic mineral in pure form with the aid of the inside of the Housing 3 generated velocity pressure of the ore stream to be processed "a" discharged. When the slide 12 of the discharge connection 9 is opened, adhesions “K” are carried along by the exiting concentrate flow “b” , and thus the content of the magnetic fraction in this concentrate is reduced.

It follows that by changing the magnetic flux intensity in the space of the straight section 5, the alternating magnetic flux, the flow medium velocity in this section and the passage cross section of the slide 12, the content of magnetic mineral in concentrate "b" can be regulated.

A high selectivity in the processing of weakly magnetic ores can be achieved by using a weak magnetic flux in the rectilinear section 5 of the housing 3 can be achieved.

Since centrifugal forces and a magnetic flux which have one and the same direction act on the magnetic fraction "e" of weakly magnetic ores in the curved section 4 of the housing 3 , the formation of a layer of magnetic particles "e" of the weakly magnetic ore becomes possible. A layer of the magnetic fraction "e" is formed from these particles on the outer wall 6 of the curved section 4 of the housing 3 by the alternating magnetic flux of the high-intensity sources 13. Strength) of the magnetic flux periodically held back particles "e" of a magnetic fraction of the weakly magnetic ore, stored in the discharge nozzle 9 and discharged through the slide 12 by means of the pressure force Fi ^ of the ore stream "a". In this way it is possible to process weakly magnetic oxidized iron ore, manganese and chromium iron ore in the magnetic separator according to the invention.

The adhesions "K" and the non-magnetic

Praluion "q" are conveyed by the ore stream "a" at the speed V (FIG. 2) to the second curved section 4 of the housing 3 (FIG. 3). In this section the process of the deposition of the adhesions "K" in the layer of the magnetic fraction "e", which was described above, is repeated. Then the movement of the adhesions "K" on the outer wall 6 of the straight section 5 is braked by the magnetic flux source 14 and the magnetic flux interrupter 18, while the conveyance of the layer "K" along the outer wall 6 to the discharge port IO by the hydraulic pressure force Fv des Flow medium takes place. The intermediate product "c" separated into the discharge nozzle is passed through the adjustable slide 12 for regrinding into the mill 40 (FIG. 12). The non-magnetic fraction "q" as deposited in the first rectilinear section 5 through the fluid medium flow "A", which has a large speed V and through the discharge openings 11 and adjustable slide 12 is discharged, the discharging of the third intermediate "c" from the centrifugal force Magnetic breaker enables the loss of the magnetic fraction with outlets "d" to be reduced significantly.

The non-magnetic fraction "q" is thrown into the area of the flow medium by a controllable ascending stream of water, which crosses the stream of the magnetic fraction "e" and runs from the graduation 24 (FIG. 10) to the Maignet flow source 14 Has speed. The graduation 24 arranged at the beginning of the partition 29 is also supplied with water, the ascending stream of which hurls the non-magnetic fraction "qvan the inner wall 7 of the housing 3 and the penetration of the non-magnetic fraction " q " into the discharge zone for the magnetic fraction "*;" from the separator prevented

The initiation and regulation of the wet processing process in the centrifugal magnetic separator according to the invention for the processing of magnetic ores proceed in the following way:

The adjustable slide 12 (FIG. 3) on the discharge nozzle 10 is completely opened, while the adjustable slide 12 on the discharge nozzle 9 and 11 is closed. The magnetic flux interrupters 17, 18, 19, 23 (FIG. 8) are switched on, and the slide of the pressure vessel 43 (FIG. 12) is opened. The flow medium of the ore stream "a" to be processed flows into the feed nozzle 8 under a certain pressure and at the calculated speed V. The adjustable slide 12 of the connecting piece is opened up to the nominal passage cross section and the slide 12 of the connecting piece 10 is closed up to the nominal passage cross section. The gradation 24 is supplied with water by means of the adjustable slide 28 (FIG. 10) through the connector 27 under a certain pressure. Water is also fed to the other gradations not shown in the drawings. To prevent clogging of the discharge connection 9 (Fig. 8), the adjustable slide 12 is opened slightly. A layer of the magnetic fraction "e" forms on the outer walls of the curved sections 4. by regulating the rotational frequency of the interrupter 19 for the magnetic flux of the sources 13, which generate an alternating magnetic flux of a certain frequency. On the outer wall 6 of the straight section 5, a layer "K" of coarse-grained intermediate product is formed by the magnetic flux interrupter.

while on the inner wall 7 of the rectilinear section 5 through the interrupters 31, 33 a layer "e" of a fine magnetic fraction is formed, both of which are discharged via the connection 10 and 35, respectively, by the velocity pressures of these currents and the exit current " de can be regulated by the slide 12 until the magnetic fraction "e" appears in the outlets.

Thereafter, the alternating magnetic flux of the sources 14, 22, 30, 32, the frequency of which is regulated by the speed of the magnetic flux interrupters 18, 23, 31, 33, creates a layer of the magnetic fraction "e" on the walls 6 and 7 of the straight section 5 is formed. The slides 12 of the nozzles 9 and 34 are then opened until the moment of the discharge of the concentrate "b" with the target content of magnetic fraction "e" . During this time the slides 12 of the nozzles 10, 11 are closed by vr.zv. by means of the water pressure regulates the speed of the ascending current which flows out of the slots 26 of the graduations 24 and crosses the currents of the magnetic fraction "e" which run from the graduations 24 to the magnetic flux sources, w ^! rd increases the selectivity of the processing by transferring the non-magnetic fraction "q" to the high speed zone of the ore flow to be processed "a" . The content of the magnetic fraction "e" in the outflows "d" can increase. In this case, the slide 12 of the nozzle 10 is opened somewhat and the content of magnetic fraction "e" in the outlets "d" is reduced to a minimum. By arranging transmitter devices for instantaneous measurement of the content of magnetic fraction "e" in the treatment products "b". "C", "d" on the centrifugal magnetic separator, the treatment process can be fully automated by regulating the drives of the slides 12 with simultaneous regulation of all other drives arranged on the separator. The content of magnetic fraction "e" in the finished product "b", ie in the concentrate, and in the outflows "d" deviates only slightly from the target values. The concentrate "b" is made with the nominal content of the magnetic fraction. r, while in the outflows "d" a \ z mentioned fraction is not included in practice.

The centrifugal magnetic separator according to the invention can be used for dry processing of magnetic ores to be used. Here the effectiveness and "economy is significantly higher than with wet processing, which is due to the change in the flow medium, since the viscosity of the air is much lower than that of water.

When installing the centrifugal force according to the invention ^{; Λ} Magnetic separator in the series of apparatuses of the processing plant shown Fig. 12, the flows of processing products are produced in the following way.

The delivery ore is dosed out of the bunker 37 by the feeder 38 and by the belt conveyor of the ^{1 |!} Mill 40 supplied and here z. B. crushed up to class 4-0 mm The ore stream to be processed "a" is then fed from the mill 40 under the action of its own weight via a channel to the sump 41 and pumped onward by the pump 42 into the pressure vessel 43 "' A certain height arranged pressure vessel 43 is the ore stream to be processed "a" under a certain constant pressure in the centrifugal force Mamet according to the invention

ΙΛ

separator 44 The intermediate product "c" separated from the latter returns under the action of its own weight via a chute to the mill 40 for regrinding, the concentrate "b" of the required quality is passed for dewatering via a chute to the vacuum filter 45, while the outflows "D" with a minimal content of magnetic fraction "t" can be discharged into the downcomer 46.

The principle of processing magnetic ores using only the magnetic properties of the minerals in the deposition according to the invention

which enables the preparation process magnetic ores without the costly averaging operations usually accompanying them To carry out ores and concentrate. The use of the separator according to the invention makes it possible it is also, from the complex of apparatuses known processing plants, ineffective and requiring a lot of steel Classification equipment whose operation is based on the gravitational properties of the ore to be processed is based, to be removed almost entirely.

In addition 7 sheets of drawings

Claims (2)

Claims; 1. F eyesight magnetic separator with a no magnetizable housing, magnet systems for generating magnetic fields, a supply and several discharge nozzles, characterized that the housing (3) alternating with curved and straight sections (4, 5) is provided and between the sections of the housing (4, 5) and the magnet systems (13, 14) Interrupters of the magnetic flux (17, 18, 19) are arranged, which are made of magnetic material are made and consist of a movable band with windows (15), the dimensions of the Windows as well as their speed of movement depend on the desired frequency and Strength of the magnetic flux and that at the end of each straight section (4) discharge nozzle (9, 10, 11) arranged between the magnet systems (14, 13) and with adjustable locking devices (12) are provided. 2. Fiiehkraft magnetic separator according to claim 1, characterized in that the number of rectilinear Sections (5) corresponds to the number of magnetic fractions removed at the end of each section will.