DE2706306C2 - Method and device for conveying a solid mixture, e.g. coal - Google Patents

Abstract

The object of the invention is to propose a method which enables the volume concentration to be increased at a lower conveying speed and at the same time avoids material concentrations and clogging. The task is solved by the fact that the raw material is only fraction-wise subjected to a sorting with regard to the grain fractions leading to clogging after the classification and before the hydraulic conveying. With this method, all those parts of the raw material are to be withstood whose rate of descent is greater than the rate of descent of the maximum clean material to be conveyed. This applies, for example, to raw coal, while for ore the extraction would have to be exactly the other way around. The desired sorting effect is particularly accurate and effective if, as suggested, the classified material is divided into defined quantities and pre-mixed with the separating medium, granulated and suspended in water by means of Schleu

Description

description

The invention relates to a method for conveying a solid mixture, e.g. B. of coal according to the preamble of claim 1. The invention also relates to a device for implementation this procedure.

The hydromechanical coal extraction and the hydraulic conveyance of the debris extracted in this way over greater distances in the horizontal and in the vertical is known (Zeitschrift Glückauf, Heft 20.99. Vintage, Essen, 25.9. 1963). With the previously known In the process, the classification is used to achieve the upper grain limit in the heaps to be hydraulically conveyed to be determined. This prevents hydraulic Grain that cannot be conveyed gets into the conveyance and that too large in the heaps to be conveyed hydraulically Differences in grain size lead to turbulence and other disturbances in the conveying medium. It has However, it turned out that the proportion of the heap must be relatively low in the flow. In practice, this leads to considerable amounts of water, which the Conveying costs increase or become clogged when the concentration of the debris in the conveyed medium increases is raised sharply.

The invention is based on the object, the vorbc-

knew procedures to lead in such a way that there is an increase the volume concentration of the solids at a lower conveying speed and at the same time oil dust accumulations and blockages can be avoided.

The invention solves this problem with the characteristic features Features of claim 1. Appropriate embodiments of the invention are the subject of the subclaims.

By according to the invention the known class

tion follows a sorting, which, however, only leads to the sinking speed in the sorted pile to unify the coarsest grain in each case, is prevented that regardless of the material composition of the pile, a certain upper grain, too high a relative velocity can develop in the hydraulic conveyance compared to the remaining grains, which leads to sacrifice leads. This enables a higher volume concentration of the solid in the pumped medium and / or in the reduction of the conveying speed. In the method according to the invention, this sorting is carried out in several grain classes based on weight. This method is based on the fact that the same large parts of very different density a difference in the rate of descent that can be used as a separating effect exhibit. This makes it possible for the separated The parliamentary group can be clearly assigned to a certain material composition. When promoting each of the raw coal is separated

b5 factions formed by mountains in the promotion of Ores is the ore. This opens up the possibility of leaving the isolated mountains underground and the hydraulic delivery accordingly

relieve.

Preferably, and with the features of claim 2, one depends on the sink rate differences further through a classification according to several grain classes and, on the other hand, achieves a simple one Sorting by separating the faster sinking component in this way from the other component separates

With the Mcikmalen of claim 3 will be In the case of Ford coal, the mountains that are larger than 10mm are eliminated. This procedure is based on that a mountain grain of 10 mm has the same sinking speed as a grain of coal of 60 mm and the grain of coal of larger size does not exist in most of the piles as a result This process leads to the separation of the mountains in the case of raw coal, which leads to the processing of the hydraulically promoted goods relieved

In the following a device is described in more detail with which the method according to the invention can be practiced. Show it

ng. 1 shows a section through a sink separator according to FIG the invention,

Fig. 2 is a simplified side view of the sink separator according to Fig. 1,

Fig. 3 schematically the control of the sink separator according to FIGS. 1 and 2 and

Fig. 4 is a diagram of the control.

The sink separator described below is intended for sorting coal and mountains.

According to Fig. 1, the housing 1 of the sink separator encloses the main part, which is completely filled with water. Internally of the housing is the section drawn shaft 2, which according to the embodiment Has a square cross-section This creates turbulence in the water-filled Manhole suppressed

The feed channel is located above the housing 1 13 over which the raw material to be conveyed is divided into individual fractions after classification by the individual allocation devices is fed. The rotor 33 of the metering device 3, which is seated on the drive shaft 4, contains four evenly arranged and equally formed chambers 6, 7, 8 and 9, which are located under the inlet funnel 10 move in the direction of the slide 11. With the drive shaft 4, the slide 11 is through a Control connected, the cylinder 12 being used to open and close the slide 11 of the housing 1 is divided into two sub-spaces in which the two conveyors are each in the form of a screw conveyor 27 and 28 respectively. The use of screw conveyors makes it possible to follow the au Sink separator of the hydraulic conveying assigned good with regard to setner grain size largely mixed to give up. Another transport device can also be used for the heavier or worthless components Find use, since mixing is no longer absolutely necessary for this

The bend 29 of the housing 1 ensures that the material to be conveyed safely into the screw conveyor 27 or 28 slides. Above these areas, i. H. on the housing middle wall 30, the counter flap 24 is one controlled task. At the other end 22 of the shaft, the movable ones are on the shaft wall 31 Flap gratings 23 hinged. A rotor 33 with openings 21 in its chambers is attached to the casing 5 of the metering device 3 surround.

The sink separator works as follows:

Classified raw material to be conveyed with a defined grain size range reaches the straight line via the feed channel 13 pending chamber 6. The rotation of the rotor is chosen so that the chamber 6 is with the material to be conveyed can fill. Upon further rotation, the chamber 6 according to FIG. 1 reaches the chamber 8, which when immersed in the water level 34 has already partially filled with water. A disquiet of the water surface as well the water column can under these circumstances

to not take place and give rise to a deterioration in the separation results. That's why the material already mixed with the separation medium before it is placed in the separation shaft.

The cylinder 12 controlled by the drive shaft 4

opens the slide 11, via which the contents of the Chambers 8 and 6 suddenly emptied into the water-filled shaft 2. This shaft takes place through the different sinking speeds of the heterogeneous material the desired separation process (sorting process) instead of the specifically £, '. who reach parts first the lower end 22 of the f chachtes 2 and according to the position shown in Fig. 1 of Flap grids 23 and the counter flap 24 in the space of the screw 27 passed according to the exemplary embodiment is assigned to the tailings The specifically lighter material, d. H. so the coal, reaches the Area of the lower end 22 of the shaft 2 only later. Then the flap grids 23 according to the The direction of the arrow is pivoted into the dotted position while the counter flap 24 makes a countermovement executes With this measure it is achieved that the incoming conveyed material (coal) in the space of the screw conveyor 28 is directed, which is assigned to the coal The actuation of the flap grate 23 as well the counter flap 24 is carried out by the cylinder 25 which is controlled via the drive shaft, which is further below is explained.

The cylinder 25 has a lever system 32 that allows the flap grids 23 and the To move counter flap 24 in the opposite direction. The movements that influence the success of the separation the water column are largely avoided in that the flap gratings or the counter flap have the holes shown or similar openings. As a result, the flaps 23,24 offer the Water as little resistance as possible. Because the flaps are at an angle to the vertical in every position the sorted material can slide over the opening in the flaps without falling through.

The FJg. 2 shows the entire sink separator in a simplified side view. According to the invention are the assigned to individual fractions shafts 2, which have a length corresponding to d: r ivOtfigröhe. Of the shortest shaft is assigned to the smallest parts and the smallest shaft is assigned to the largest parts it is achieved that the residence times of the individual materials to be separated in the adjacent Shafts are of the same length. Also shown is the spatial arrangement of the individual shafts 2 with the flap grids 23 and the Gtgenklappe at the lower end 22 of each shaft 2 24, as well as further details. With the sink separator shown, all fractions in the Scope of the classification have been obtained, sorted in the device and automatically separated from one another will.

Above the allocation device 3. The sea elements, which are arranged on the drive shaft 4, are loaded

stands, the feed channels 13 are arranged, through which the conveyed goods classified according to the specification are fed. In the example shown, a total of six fractions are fed into the feed channel 13 of the separating device, which accordingly consists of six or five allocation devices. Tests have shown that dividing the material over 10 mm into the following fractions is sufficient:
10-20, 20-30, 40-50 and 50-60 mm. The grain over 60 mm is already passed over the classifying device and, if necessary, further processed, fed back to the classifying device. After sorting, the appropriately sorted material is conveyed away with the aid of the screw conveyor 27 or the screw conveyor 28 located behind it and is then taken to the coal bunker

At the end of the drive shaft 4 sit the control slide 14 associated with the individual discharge segments, ie the slide 11, the flap remainders 23 and the counter flap 24. Known elements are suitable as components for the control. Also not shown in FIG. 2 is the arrangement of the segments of the dispensing device 3 assigned to the individual shafts 2, which segments are shown in FIG. 1 and denoted by 6 to 9. The parts of the dispensing device seated on the common drive shaft 4 are each offset by 18 °, so that the discharge of the solids in each individual dispensing device takes place at a different point in time and these points in time follow one another. Flg. 3 shows the principle of the control using two sub-controls. In Fig. 3 above, the three on the drive shaft 4 sitting next to each other and associated cam disks 15, 17 and 19 are shown from the control member 14, which the two cylinders 12 and 25 have to operate. The four cams 16 of the cam disk 15 actuate the cylinder 2 four times during one full revolution for a period of time which corresponds to the angle α. The cams 18 of the cam disk 17, as well as the cams 20 of the cam disk 19 control the cylinder 25 such that after a time which corresponds to the angle β on the cam disk 17, the cylinder 25 is reversed and after a time which is on the cam disk 19 Corresponds to angle γ , is moved back to the starting position. The time for the control itself is the same for both cam disks and corresponds to the angle /?.

Rg. 3 below shows the same processes for the next cam disks 15, 17 and 19, which are assigned to the cylinders 12 and 25 of the next allocation device 3 or the next shaft. Old cams have the same shape as in Fig. 3 above. They are only offset by the angle δ on the common drive shaft 4. This angular distance also exists between the following control members 14 of the remaining parts of the sink separator.

In Fig. 4, a control diagram is shown, which makes the timing of the control illustrated in FIG. 3 clear

This control diagram shows that the control processes of the cylinders 12, 25 and thus the movements the KJappenroste 23 and the Gegenkappe 24, all of them take place under water, spread over the entire period of a full revolution of the metering device 3, so that only a slight disturbance to the comparatively large water flow in the main part of the separating device is transmitted. This concern is further compounded by the angular cross-sectional shape of the manhole 2 kept within limits.

According to the illustrated embodiment, the raw coal is initially unier at a Korngrölk 60 mm classified. If the material is larger than 60 mm, the device shown is passed away. Its follow-up is not the subject of the invention.

The goods under 60 mm are divided into the individual feed channels as follows:

13 All material under 10 mm

including the conveyed water,

13 'grain size 10 to 20 mm,

13 "grain size 20 to 30 mm,

13 "'grain size 30 to 40 mm,

13 "" grain size 40 to 50 mm,

13 "" 'grain size 50 to 60 mm.

The grain size distribution changes with the hardness of the coal to be extracted. It can therefore be expedient be, äüCu uie short tensions of the fractions accordingly change and / or reduce or increase the number of factions.

A particular advantage of the device shown is that by eliminating the recovery portion Plastic concentrations above 10 mm and thus blockages are prevented. Overall, the sought-after higher volume concentration achieved, which can be conveyed at a lower conveying speed. Besides derri “The sink separator is robust and simple in design and therefore the special conditions adapted for underground mining. The sink separator can be used in the vicinity of blind shafts or partial shafts or in other suitable pit rooms without major investments will.

For this purpose 4 sheets of drawings

Claims (10)

1 claims 1. Process for conveying a solid mixture, e.g. of coal, in which from the Raw materials containing components of different sizes and weights by classifying Coarse grain separated and the classified material is hydraulically conveyed, characterized that the classified conveyed goods are sorted and all of the grain of the heavy component is separated whose rate of descent is greater than the rate of descent of the largest grain of the light component, and that the sorting into grain classes takes place according to the weight, whereupon the heavier or the lighter component is hydraulically conveyed and the other component in each case is used elsewhere. 2. The method according to claim 1, characterized in that that from the classified conveyed material grain classes aj? are divided, from which partial quantities are formed, which are suddenly introduced into the water and their rate of descent respective components are sorted. 3. The method according to any one of claims 1 or 2, characterized in that the classification of a Conveyed coal into a coarse grain fraction with a grain size greater than 10 mm and into which the underlying grain sizes containing conveyed material takes place. 4. Device for carrying out the method according to one of claims 1 to 3, characterized by one of the hydraulic, η conveying upstream, Sink separator filled with water as the separating medium, the housing of which - »(1) in shafts (2) of different lengths, each of which is preceded by an allocation device (3), and by a discharge device (22), each consisting of a conveyor (27, 28) with a flap-controlled Task (23,24) exists, which is linked to the allocation device (3). 5. Device according to claim 4, characterized in that that the distribution devices (3) assigned individually to the shafts (2) on a common Drive shaft (4) are arranged non-rotatably and each one in several chambers (6 to 9) subdivided rotor (33), the chambers (6 to 9) of which with a slide (11) into the inlet (10) of the relevant shaft must be opened individually. 6. Device according to one of claims 4 or 5, characterized in that the allocation device (3) immersed in the separating medium in the housing (1) of the sink separator. 7th Device according to one of Claims 4 to 6, characterized in that the feed, arranged at each shaft (2) at its lower end (discharge device 22), consists of two flap gratings (23) and a central counter flap arranged on the housing (1) of the sink separator (24) is formed. 8. Device according to one of claims 4 to 7, characterized in that for driving the The flap grids (23) and the counter flap (24) have a double lever controlled by a cylinder (25) (32) is used. 9. Device according to one of claims 4 to 8, characterized in that the conveyor of the Sink separator consist of screw conveyors (27, 28). 10. Device according to one of claims 4 to 9, characterized in that for controlling the Cylinder (25) of the discharge device (22) and one for controlling the slide (11) Cylinder adjustable cam disks (15 to 19) are used.