EP0815941B1 - High gradient magnetic separator - Google Patents

Abstract

The two poles of the magnetic unit (1) form an intermediate space between them, in which a homogeneous magnetic field is produced. A matrix frame (2) is set in rotation around an axis (3) and at least partly encloses a ring-shaped inner space divided into segments (5) by dividing walls (4). The segments of the inner space, as the result of the rotation, are fed one after the other through the intermediate space. At least one inflow conduit (6) and an outflow conduit (7) are provided, with the aid of which the fluid can be conducted through at least one segment of the ring-shaped inner space located in the intermediate space.

Description

The invention relates to a high gradient magnetic separator according to the preamble of the first claim.

Such a high gradient magnetic separator is from AU-24983 known. This magnetic separator rotates Matrix frame between the two poles of a magnet. The The matrix frame is divided into segments. Details, in the way in which the division is made is missing. The Poles of the magnet have such a width that the Corresponds to the width of two segments. Above and below of the matrix frame are an inlet and an outlet for the to be cleaned or for the cleaned fluid.

Another high gradient magnetic separator is from US 3,920,543 known. This device has a rotatable, ring-shaped matrix frame arranged horizontally and is divided radially into segments. The segments are with packing, filled with steel wool or balls. Will the matrix frame rotated around its center, each segment passes several magnetic units in succession, which consist of two poles, between which the Matrix frame moves as it rotates. Between the poles a homogeneous magnetic field is generated. The magnetic units can e.g. B. from permanent magnets or electrical Coils exist. In the field of magnetic units a fluid containing solids via an inflow line from above directed into the underlying segment, whereby due to the applied magnetic field para- or weakly ferromagnetic Solids are deposited on the packing. That of the Fluid freed from solids flows in via a drain line down from. The packing is subsequently used in several outside of the magnetic field flushing devices regenerated again.

With this high gradient magnetic separator, the inlet and Drain lines for the fluid one above the other. The fluid is there only in the area of influence of the magnetic field for a short time, so that the separation effect is not optimal.

An overview of the magnetic deposition of in Fluid suspended solids can be found in J. Svoboda: "Magnetic Methods for the Treatment of Minerals", Developments in Mineral Processing, 8, Elsevier Amsterdam - Oxford - New York - Tokyo 1987. On pages 158 to 194 various High gradient magnetic separator, including the one described in detail above.

Another rotatable high gradient magnetic separator is in EP 0 429 700 A1. This magnetic separator contains an annular container filled with steel wool, which is U-shaped in cross section and by a partition that is provided with openings at the bottom of the u-profile, in one outer and an inner area is shared. The container is in a homogeneous magnetic field created by permanent magnets and magnetizable internals is generated. That too cleaning fluid first passes through the outer area of the container, then passes through the openings in the partition and flows into the inner area of the container, taking solid particles be held back. Then the cleaned leaves Fluid the device.

Compared to the device mentioned at the beginning, this has a high gradient magnetic separator the advantage that the way of Fluid within the magnetic field is longer, making it more effective Separation of solids is possible. Indeed it is not possible to have multiple magnetic units in the same To connect the device in series. The main disadvantage is, however, that the device is not operated continuously can be, because the gap is constantly in the Area of the magnetic field between the poles of the magnetic Unit. Therefore the loaded steel wool has to be mechanically be diverted from the area.

The object of the invention is a continuously operating device to propose the type mentioned at the beginning, in which the Path of the fluid within the magnetic field is larger than at the known devices, so that a more effective solid separation is possible. The device is intended to operate simultaneously a series connection of several magnetic devices enable.

The object is achieved by the in the characterizing part of the first claim described feature solved. In the other claims are preferred embodiments of the invention High gradient magnetic separator specified.

An essential advantage of the high gradient magnetic separator according to the invention is that the fluid flow within the magnetic field not just once as in EP 0 429 mentioned above 700 A1, but can be redirected several times, so that overall a much longer path within the magnetic field and thus achieve a better solids separation leaves. The fluid flow is not radial, but as in of the above-mentioned US 3,920,543 performed in a circular manner, so that as in this device, several magnetic devices can be connected in series.

According to the invention is a matrix frame with an annular Interior provided by radially arranged partitions is divided into several segments. The number of segments and thus the partition walls determine the length of the path of the fluid in the space. There are two adjacent ones via one opening each Segments connected to each other. It is essential that the Openings not in the same places, but alternately on a first and a second, the first not opposite point in the area of the partition attached are. This way the path of the fluid can be considerable be extended. The magnetic unit has a width that corresponds to the width of at least two segments, so that the fluid-like path of the fluid through at least two of the segments within the magnetic field lies.

The segments are with a matrix with a large surface, for example with steel wool, wire mesh or profiled metal plates filled. The material of the matrix is said to be the magnetic field bundle up. The high gradient magnetic separator also contains a flushing device with which the loaded matrix regenerates can be. The flushing device is outside the Magnetic field and consists of an inflow and an outflow, which in are related to each other in such a way that only one segment at a time is regenerated with the flushing device.

There is preferably no separate opening in the partition walls introduced, but the size of the partition walls is chosen so that they have a gap with a wall delimiting the interior form. For example, the matrix frame can represent a torus, the with means for attachment to an axis, such as with two or more spokes. In a lying position of the torus leave the first, third, fifth etc. partition a gap free to the top wall of the torus, while at each second, fourth, sixth etc. partition the gap between between the partition and the lower wall of the torus is.

However, an embodiment in which the interior is not completely limited by the matrix frame becomes. In this embodiment, the matrix frame delimits the interior only on two opposite sides. The matrix frame is integrated into a housing, the Inside walls the two sides not delimited by the matrix frame complete the interior.

This embodiment is used to explain the invention in more detail explained in more detail below with reference to figures.

Fig. 1 eine teilweise (Bruchlinie B) aufgeschnittene Darstellung einer Ausführungsform des Hochgradienten-Magnetabscheiders;

Fig. 2 eine Schnittdarstellung (Schnitt A-A in Fig. 1);

Fig. 3 eine weitere Schnittdarstellung;

Fig. 4 die erste innere Wand des Gehäuses;

Fig. 5 die zweite innere Wand des Gehäuses;

Fig. 6 eine Schnittdarstellung mit Zuflußleitung;

Fig. 7 eine weitere Schnittdarstellung mit Zuflußleitung.

Show it:

Figure 1 is a partial (break line B) cutaway representation of an embodiment of the high gradient magnetic separator.

Fig. 2 is a sectional view (section AA in Fig. 1);

3 shows a further sectional illustration;

4 shows the first inner wall of the housing;

5 shows the second inner wall of the housing;

Fig. 6 is a sectional view with inflow line;

Fig. 7 shows a further sectional view with inflow line.

In Fig. 1 is the embodiment of the high gradient magnetic separator shown in supervision, the housing 10 is cut along the fault line B. The device has a single magnetic unit 1. Im broken Part of the matrix frame 2 can be seen, which consists of a outer 12 and an inner 11 annular wall, which connected to each other by radially arranged partitions 4 are. The matrix frame 2 is about the axis 3 in the housing 10 rotatable. When rotating, the segments 4 are successively through the space between the two poles 1a, 1b (see Fig. 2) form the magnetic unit 1 together, passed. A flushing device 16 is embedded in the housing 10, which is used to regenerate the matrix material 17 (see Fig. 2) serves in segments 5. The detergent supply line is under supervision 16a visible.

Fig. 2 shows a sectional view of the embodiment of the High gradient magnetic separator along the line A-A (Fig. 1). The matrix frame 2 rotates between the two walls 9 of the housing 10. On the walls 9, the poles 1a, 1b of the magnetic Unit 1 attached. There are several of the matrix frame 2 segments filled with the matrix 17 are represented by which are six in the area of influence of the magnetic field of the magnetic Unit 1 are located.

The solids-laden fluid is in through the inflow line 6 in the housing 10 and the matrix frame 2 initiated. It flows through successively the segments between the inflow line 6 and the drain line 7, the fluid alternating the gap 8a on the first 9a and on the second 9b wall of the housing 10 flows through. The edges 13 of the partitions 4 (Fig. 1) are with a means of sealing, here sealing lips made of Teflon, so that in the space between the poles 1a, 1b the side of the respective partition opposite the gap 8a lies tightly against the inner wall 9a or 9b of the housing 10. The sealing lips lie outside this space the partition walls on both inner walls 9a, 9b of the housing 10 and thereby close the relevant segments tightly. In the area of the space have the inner housing walls 9a, 9b indentations, which cause that between the sealing lips and one of the two inner housing walls 9a and 9b the gap 8a occurs.

The separation of the para- or weakly ferromagnetic solids from the fluid instead. The matrix 17 is loaded with the solids while the fluid freed from the solids through the device the drain line 7 leaves. By the flushing device 16, the is arranged outside the magnetic field, the matrix 17th regenerated again, d. H. freed from the accumulated solids.

FIG. 3 shows an alternative to the embodiment in FIG. 2. The inner walls of the housing have no depressions here on; rather, they are shaped like wavy lines, whereby the bulges corresponding to the recesses 15 Stand gap. This achieves the same effect as with the embodiment shown in FIG. The remaining reference numbers have the same meaning as in FIGS. 1 and 2.

4, the first inner wall 9a is in the embodiment shown in Fig. 2. There are four depressions 15 in the area between the poles 1a and 1b (Fig. 1). The flushing device 16 is also shown.

Fig. 5 shows the second inner wall 9b in the embodiment according to Fig. 2. In the area of the space between the poles there are 5 wells 15, the centers of which are the wells 15 in Fig. 4 stand on gap.

6 and 7 are two alternative embodiments shown for the derivation 7. The derivatives are through one of the two poles, pole 1a. This embodiment has the advantage that a higher one in the area of the leads Magnetic field prevails and thus the risk of accidental Detachment of the solids is significantly reduced. Similar Embodiments can also be in the area of the feed line 6 be used.

Experimental example:

The embodiment of the high gradient magnetic separator shown in FIGS. 1 and 2 was with a matrix diameter of 500 mm. The matrix was in 40 segments in one Dimensions of approx. 80 x 35 x 40 mm divided. The speed of rotation the matrix was 1 revolution per 20 minutes. The flux density used was approximately 0.57 Tesla, the volume flow was 1 l / min. The phosphate concentration in the feed was 10 mg P / l. The initial turbidity became about 50 turbidity units Formazin (FEF) determined. The experiment showed that during constant low over the entire test period of over 2 hours Turbidity values below 4 FEF on average and phosphate concentrations below 0.5 mg P / l could be achieved.

Claims (5)

1. High-gradient magnetic separator for continuously separating para- or weakly ferromagnetic solids from a fluid, said separator having

   a) at least one magnetic unit (1) provided with two poles (1a, 1b), which have a spacing therebetween and form with each other an intermediate space in which a homogeneous magnetic field can be produced,

   b) a matrix frame (2), which can be set to rotate about a spindle (3) and surrounds, at least partially, an annular interior which is divided into segments (5) by dividing walls (4), the segments (5) of the interior being successively guidable through the intermediate space as a consequence of the rotation, and

   c) at least one feed pipe (7) and one discharge pipe (7), by means of which pipes the fluid can be conducted through at least one segment (5) of the annular interior, which segment is situated in the intermediate space,

   d) the width of the magnetic unit (1) along the interior corresponding to at least the width of two segments (5),

   characterised in that, in the region of the intermediate space, each segment (5) of the annular interior is connected to its adjacent segments (5) via a respective opening (8), the openings (8) being provided alternately at a first location and at a second location, which is not situated opposite the first location, so that the path of the fluid extends in the manner of an undulatory line.
2. High-gradient magnetic separator according to claim 1, characterised in that the segments (5) in the region of the intermediate space are formed by those dividing walls (4) which alternately form a gap (8a) on a first and on a second wall (9) which defines the interior.
3. High-gradient magnetic separator according to claim 1 or 2, characterised in that the matrix frame (2) is incorporated in a housing (10) and includes an inner wall surface (11) and an outer wall surface (12), which surfaces are in the form of a cylinder casing and are interconnected via the dividing walls (4), the first and second walls (9) being formed by a first internal wall (9a) and a second internal wall (9b) of the housing (10); the dividing walls (4) include, at their regions pointing towards internal walls of the housing (10), edges (13) which are provided with sealing means (14) for sealing from the internal walls (9a, 9b); and the internal walls (9a, 9b) of the housing (10) are shaped in such a manner that, in the region of the intermediate space, the sealing means (14) alternately touch the first internal wall (9a) and the second internal wall (9b) of the housing (10) and alternately form the gap (8a) on the second internal wall (9b) and on the first internal wall (9a) of the housing (10).
4. High-gradient magnetic separator according to claim 3, characterised in that radially provided indentations (15) are introduced into the internal walls (9a, 9b) of the housing (10).
5. High-gradient magnetic separator according to claim 3 or 4, characterised in that the housing includes a rinsing device (16) comprising a feed line and a discharge line, which lines are provided externally of the magnetic field and lie opposite each other on the first and second internal walls of the housing.

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