FI56777C - FOERFARANDE FOER SORTERING AV BRUTEN MALM SAMT FOER UTFOERANDE AV FOERFARANDET AVSEDD SORTERINGSLINJE - Google Patents

Description

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Patent («eddelat V V (S1) Kv.lk.» / Lnt.CI. * B 07 C 5/34

FINLAND — FINLAND (21) Patent application - Patentansökning 7Ö221O

(22) Hakcmitpiivl - Ansökningsdag 10.07 · 78 (23) AlkupUvi - Glltighetsdag 10.07.78 (41) Become public - Blivit ofTentllg

Patent and Registration Board .... ...... ..........

'. (44) Date of issue and of publication. -

Patent-och registerstyrelsen Ansökan utlagd och uti.tkrjften pubiicend 31.12.79 (32) (33) (31) Requested priority — Begird priority (71) Outokumpu Oy, Outokumpu, FI; Töölönkatu U, 00100 Helsinki 10,

Finland-Finland (FI) (72) Pekka Rautala, Espoo, HeikkiJohannes Sipilä, Espoo, Finland-Finland (FI) (7 ^) Berggren Oy Ah (5I +) cast iron is used for the production of the sorting line

The present invention relates to a method for sorting mined ore or a similar mineralized material. It is also directed to a sorting line for performing that method.

The ore to be mined is almost always inhomogeneous, so that ore boulders that are uneconomical to grind and further process are also involved in the enrichment process.

The sorting of the ore already at the stage when it is still in the boulder form has so far only been performed on uranium ore, in which case the analysis may have been based on the ore's own natural radioactivity.

It is an object of the present invention to provide a method by which the sorting of ore and similar mined materials, such as limestone, can be carried out at an early stage of the process, so that unnecessary material, side rock, can be separated and left untreated. To achieve this, the method according to the invention S S 7 7 7 is characterized by what is set forth in the appended claim 1, while the features of the sorting line for carrying out the invention are correspondingly apparent from claim 3.

The invention is thus based on the so-called to use the capture gamma method. In this method, the characteristic gamma radiation of the atoms of the sample is excited by neutron radiation. Thanks to the high permeability of both neutrons and gamma radiation, it is possible to analyze objects weighing several kilograms without breaking them. By selecting a suitable neutron source and gamma detector, the measurement time for several substances is very short, even a few milliseconds. The measurement can be performed, for example, by dropping the ore blocks one by one through the analyzer. In this case, the analyzer is, of course, preferably connected to a control device which, on the basis of the analysis result obtained from each boulder, automatically directs it to the right track.

A suitable measuring device based on the capture gamma method is disclosed in Finnish Patent Application No. 78 1381, which is incorporated herein by reference.

The invention will now be described in more detail by way of example and with reference to the accompanying drawing, in which Figure 1 shows a known crushing and grinding line of a chromium ore concentrator and Figure 2 shows how a sorting device is placed in the known line of Figure 1 according to the present invention.

Thus, Figure 1 shows the initial line of a chromium concentrator where the mined ore is crushed and ground. The following parts are numbered in the line: feeder 1, jaw crusher 2, conveyors 3-5, vibrating screens 6, 8 and 11, cone crushers 7 and 9, conveyors 10, 12 and 14, vibrating transmitters 13, bar mill 15, ball mill 16, cyclone sorter 17 and vibrating screen 18.

Figure 2 shows how the sorting according to the invention is performed by a capture gamma method, in which a capture gamma analyzer is placed in the processing line between the conveyor belts 3 and 4, i.e. between the jaw crusher and the cone crusher. It is clear that the sorting can be carried out at a later stage, but it is advantageous from the point of view of energy use to carry it out as early as possible. The capacity of the jaw crusher is considerably large in relation to its energy consumption and the size of the boulders resulting from it is less than about 20 cm.

In Figure 2, the boulders are marked with the number 19. The boulders fall down through the tube 20 where the capture gamma analysis takes place.

Reference numeral 21 denotes a neutron source, which may be the isotope Cf of Example 252, numeral 22 is the neutron source Moderator and 23 is a gamma radiation detector, which may be a semiconductor detector or a scintillation detector, depending on the application. As already mentioned above, the analyzer is described in more detail in Finnish Patent Application No. 78 1381.

The signals or pulses provided by the detector 23 are received by an electronic control circuit which is further connected to control the compressed air nozzle 25. The control circuit 24 usually has a predetermined threshold value according to which the block 19 is sorted as either a valid or a side stone. In the latter case, the control circuit 24 opens the nozzle 25 / whose powerful air jet directs the block to the left side of the distributor 26 in Fig. 2.

Example 1

With a geometry slightly different from that shown in Figure 2, experimental measurements were performed with two “pyrite stones” (2900 g and 1200 g) .The detector was a 5 "x 5" Na collocide, although the collocide is not optimal for such an application.The detector was surrounded by a boric acid shield that prevented the detector The source was 252 0.5 ug Cf, moderated by water, and a bismuth cone between the source and the detector that protected the detector from gamma from the source.

The following table shows the capacity and the required measurement time obtained by converting the results obtained for iron.

252 The source is assumed to be 20 ug Cf. Efforts have also been made to predict the interfering effects of other substances.

4 5ό777

Stone size 2900 g Stone size 1200 g diameter approx. 9 cm diameter approx. 6 cm

Hold Ratio required- capacity-required- capacity- error error tate tate tate ^% measurement t / h measurement t / h time s time s

Fe 60 16 0.07 151 0.17 26

Cu 0.5 60 2.5 4 6.4 0.7

Ni 0.2 50 1.8 6 4.6 1

Zn 20 10 40 0.3 92 0.05

Cr 25 20 0.14 75 0.37 12

Mn 60 8 0.19 56 0.48 9

Ti 5 20 0.3 35 0.76 6

The short measurement time required (e.g. for Fe and Cr) means that the analysis performed on these substances is advantageous from the point of view of sorting, as it does not substantially slow down the crushing process.

Example 2

The corresponding experimental measurements were performed on two "stones" (5300 g and 850 g) made from Jones' feed and the results were as follows:

Stone size 5.3 kg Stone size 850 g diameter approx. 12 cm diameter approx. 6.5 cm

Hold Ratio required- capacity- Ratio. required capacity error standard error error standard ^ ^ measurement t / h „measurement t / h time s time s

Cr 21.4 13 0.1 190 25 0.1 30 20 0.04 480 20 0.16 19

Fe 14.6 29 0.1 190 20 0.2 95 16 0.3 64 These results must be considered promising. It should be noted that several large Nal crystals can be used and that optimization of the geometry will reduce the background, thereby significantly improving the peak-to-background ratio.

5 b 6 7/7

It should be noted that in the case of the enrichment of the metal to be analyzed slowly as such, sorting may possibly be carried out in respect of another substance, provided that these substances are present in some way in combination in the ore. For example, in the sorting of limestone, on the other hand, it may be desired to remove boulders that contain too much iron, allowing the analysis to be performed on iron.

Finally, it should be noted that the method presented can only measure the total amount of a substance. If concentration measurements are desired, the size of the stones must also be determined. For this purpose, either a sieve or a separate mass measuring device of the type previously built may be connected to the analyzer.

Claims (14)

567/7 6 A method for sorting mined ore or a similar mineralized material, characterized in that the individual boulders are chemically analyzed for at least one elemental content by a capture gamma method and on the basis of the obtained analysis the boulders are sorted mechanically one by one. Method according to Claim 1, characterized in that the analysis is carried out while the block is in motion. Method according to Claim 1 or 2, characterized in that the analysis is carried out on the substance to be recovered. Method according to Claim 1, characterized in that the analysis is carried out on a substance which is not recovered. Method according to one of Claims 1 to 4, characterized in that the analysis and sorting are carried out on boulders with a maximum size of the order of about 20 cm. Method according to one of the preceding claims, characterized in that the crushed boulders are allowed to fall down one by one through a capture gamma analyzer and the side rock to be removed on the basis of the analysis is directed to the side by a strong compressed air jet. Method according to one of the preceding claims, characterized in that, in connection with the capture gamma analysis and before sorting, the size of the boulders is also measured in a manner known per se, in which case the concentration of the test substance in the boulder is also determined. A sorting and extraction ore or similar mineralized material for carrying out the method according to claim 1, comprising a plurality of crushers (2, 7, 9) or the like for reducing the mined ore into lumps and the necessary conveyors (3, 4, 5) between the crusher, known u that it comprises a capture gamma measurement based on 56? / 7 an analyzer (20-23) arranged to perform a transport path analysis of the boulders (19) for each boulder separately with respect to at least one of its elements, and a control device (24, 25) located downstream of the analyzer connected to control the boulders (19) at least for two different tracks depending on the analyzes performed on them individually. For sorting according to claim 8, characterized in that the analyzer (20-23) is located immediately after the first crusher (2), which is preferably a jaw crusher. Sorting line according to claim 8 or 9, characterized in that the analyzer (20-23) comprises a substantially vertical tube (20) through which the boulders are dropped, a neutron source (21) placed opposite each other on both sides of the tube, and a gamma radiation detector ( 23), which is further connected to said control device (24, 25). Sorting line according to claim 10, characterized in that the control device (24, 25) comprises an electronic control circuit (24) which receives the signal transmitted by the detector (23) and compares it with a preset threshold level, the control circuit being connected to a compressed air nozzle (25) or the like, oriented substantially horizontally to divert the falling boulders (19) sorted as sideways out of the treatment line. Sorting line according to one of Claims 8 to 11, characterized in that it further comprises means for measuring each block at least roughly, the control device (24, 25) also being connected to these size measuring means. Sorting line according to claim 12, characterized in that said means consist of screens of different degrees of roughness. Sorting line according to claim 12, characterized in that said means comprise a mass determination device known per se. . 8 So? / 7