SE513451C2 - Ballistic waste separator with two or more crankshaft arrangements - Google Patents

Abstract

The present invention relates to a ballistic waste separator. The separator includes an inclining shaker table with at least four screen elements (1). The material mix which is to be separated is released onto the screen elements (1). These execute a rotational movement with an amplitude and at a speed which result in hard material bouncing on the elements (1) and being discharged at the lower end (6) while soft and flexible material which does not bounce against the shaker table migrates upwards and is discharged at the upper end (5). The screen elements (1) are driven by a drive motor (10) via crankshaft arrangements as a synchronous unit in such a manner that every second element assumes the highest and lowest position simultaneously. Each crankshaft arrangement includes two crankshafts (12) interconnected via an intermediate shaft (13) and a transmission (14). Each crankshaft (12) does not support more than two or three screen elements (1). <IMAGE>

Description

Fig. 1 a separator according to the invention from the side, Fig. 2 a top view of the separator according to Fig. 1, Fig. 3 a principle sketch of the drive shown from above and taken along the line III-III in Fig. 1, Fig. 4 a sectional view taken along the line IV-IV in Fig. 1, Fig. 5 is a detail view showing fastening of saddle elements on the crankshafts, and Figs. 6 and 7 are detail views showing a saddle element from the side and from above, respectively.

In the embodiment shown in the figures, the device has four parallel saddle elements 1 which together form a shaking table. The screen elements 1 are supported via holders 16 by a number of crankshafts 12. The crankshafts 12 are mounted via bearing housings in a framework. The framework comprises a superstructure 3, which rests on a bottom frame 2. In some embodiments, the superstructure is clad with suitable wall material for dust and noise protection. The bottom frame 2 rests on support 4. The bottom frame 2 is arranged inclined in relation to the horizontal plane, so that also the saddle elements 1 which form the shaking table have an inclined extent. By changing the height position of one of the supports 4, you can easily change the inclination of the shaking table.

The shaking table has three different outlets for different material fractions. An outlet at the upper end 5 of the shaking table, an outlet at the lower end 6 of the shaking table and an outlet 7 arranged below the shaking table. The saddle elements 1 have a large number of openings 8 for passing material of relatively small size to the outlet 7 arranged under the shaking table. Such relatively small material can in the case of construction waste constitute various pollutants such as crushed material, organic material, etc.

In the embodiment shown, the saddle elements 1 are broken, in such a way that the lower part of each saddle element 1 has a greater inclination in relation to the horizontal plane than the upper part of the saddle elements 1. The breaking point is arranged at about 1/4 of the total length from the lower end. The breaking point is normally arranged in the area where the waste falls on the shaking table. This keeps this area cleaner. In some embodiments, the saddle elements 1 are lined with a suitable damping material, for example rubber, at least in the area where the waste falls on the shaking table.

In other embodiments, the breaking point is arranged in other positions or the breaking point is completely absent, ie the saddle elements have the same slope along their entire extent. The saddle elements 1 further have a strip 9 with a sawtooth-like structure seen from the side, with a vertical side 21 and an inclined, upper side 22. The inclined upper side 22 is arranged so that it slopes down towards the lower end 6 of the shaking table. are normally arranged in the middle of the sieve elements 1 and are extended along the entire sieve elements, except for the last piece at the lower end of the shaking table. The main purpose of the sawtooth shape is to move the material upwards. Thanks to the strips 9 on the saddle elements 1, the material on the shaking table will also receive movement impulses which are transverse to the normal direction of movement. This helps to stir the material and reduces the risk of the material "floating on top" of other material. For example, there is a risk that hard material ends up and remains on top of, for example, a corrugated board. The mutual movement between adjacent sole elements gives it - main agitation.

As mentioned above, the crankshaft elements 1 are supported by crankshafts 12. The crankshafts are included in crankshaft arrangements where each crankshaft 12 carries only two saddle elements 1. In the embodiment shown, each crankshaft arrangement comprises two crankshafts 12a, b; c, d, an intermediate shaft 13, a transmission 14 and bearings 15. The crankshafts 12 are driven by a single motor 10. The motor 10 drives via a gear ratio 11 a first crankshaft 12a, this first crankshaft 12a is connected to an intermediate shaft 13 which drives a second crankshaft 12b via a transmission 14. This second crankshaft 12b carries the two other saddle elements 1 which are not supported by the first crankshaft 12a. The end of the second crankshaft 12b facing away from the transmission 14 is arranged in a bearing 15 supported by the framework. The two crankshafts 12a, b in the crankshaft arrangement are arranged mutually offset in the longitudinal direction. In the embodiment shown, the transmission 14 is made of a chain drive, but in other embodiments gears or toothed belts are used. One and the same motor thus drives the two crankshafts 12 which support the sieve elements 1. The sieve elements 1 move in pairs in such a way that every other element moves synchronously, ie they assume the highest position and the lowest position, etc. simultaneously.

It is possible to arrange crankshafts 12 and intermediate shafts 13 in several other ways than what is shown in this exemplary embodiment. The important thing, however, is that the parts of the shafts rotate with constant displacement. The crankshafts are interconnected and operated as a synchronous unit.

In the embodiment shown, the drive device is arranged at the upper end 5 of the shaking table. At the lower end 6 of the shaking table, a further crankshaft arrangement is arranged which supports the sieve elements 1. The crankshafts 12c, d at the lower end are not driven in the embodiment shown in drawing - the ings. Here too, each crankshaft 12c, d carries only two sieve elements 1 each. The crankshafts 12c, d are interconnected via an intermediate shaft 13 and a transmission 14. The interconnection of the non-driven crankshafts 12c, d takes place so that uncontrolled dead positions do not occur. The sole elements 1 transmit the movement to the non-driven crankshafts 12c, d at the lower end 6 of the shaking table. All crankshafts 12 are thus driven directly or indirectly by one and the same motor 10.

The sieve elements 1 are supported on the respective crankshaft 12 by a holder 16 which is rotatably arranged in relation to the crankshaft 12 via a bearing 17. Adjacent sieve elements 1 are supported variably at different levels on the crankshafts.

The outlet 7 under the shaking table has such a funnel shape that it catches all material which falls through the openings 8 along the entire extent of the sieve elements 1.

Each individual screen element 1 performs during rotation a rotational movement which goes in the direction of the arrow 23 according to Figure 1, the crankshafts rotating counterclockwise as shown in Figure 1. The rotational speed of the elements 1 is set so that the vertical speed exceeds the free fall hard and soft materials. l5 20 25 30 35 513 451 5 The shaking table normally has an inclination of 8-15 ° to the horizontal plane of the upper part 5, while the lower part 6 is inclined an additional 5 ° in relation to the horizontal plane. The height of the sieve elements 1 is approximately 80-180 mm.

In some embodiments, the waste separator is adapted so that it can be easily moved as needed. This is done, among other things, by adapting its size to the possibility of transporting it by truck.

In use, for example, construction waste is conveyed to an inlet 19 of the separator by means of a conveyor 18. The inlet 19 and the conveyor 18 are only shown indicated by dashed lines in Figure 1. To control the position of the waste precipitation on the shaking table is in part embodiments a guide plate (not shown) arranged at the inlet. This guide plate is often adjustably arranged to change the position of the fallout area depending on the type of waste, if necessary.

Hard materials such as brick, wood, metal, etc. that are included in the waste will bounce on the inclined shaking table. Due to the inclination of the shaking table, the hard material will bounce in the direction of the lower end 6. By adjusting the inclination of the shaking table, the bouncing direction can be adjusted as desired. When the hard material after the first bounce has assumed a new position on the shaking table, it will "lift" from the shaking table when the sieve element or elements 1 on which it moves moves downwards, because according to the above the sieve element 1's velocity for the material. When the sieve elements 1 again meet the falling, hard material, the material will receive a new shock impulse in the direction of the lower end 6 and thereby be moved in this direction to eventually be ejected from the separator.

Soft and flexible material such as paper, corrugated cardboard, film plastic, etc. that falls on the shaking table does not bounce in principle. When the sieve element or elements 1 on which the soft material rests move downwards, these elements 1 have such a speed that the soft material does not have time to follow in free fall. The soft material thus "lifts" from the elements 1. As this soft material falls, the sieve element 1 moves so far in its rotational movement that the soft material will have moved to a position further to the left of the sieve elements 1 as seen in figure 1. The sieve element 1 has time to pass the lower turning point before the soft material hits the sieve element 1 again.

This is then repeated until the soft and flexible material has been discharged at the upper end 5.

The third fragment, which consists of crushed material, organic material, etc. and which is of such a size that it falls through the openings 8 received on the respective sieve element 1, is discharged via the outlet 7 arranged under the shaking table. Through the rotational movements of the screen elements 1, this fragment will be moved until it falls down through an opening 8 if it does not fall directly into an opening 8 when it has left the conveyor 18. The size of the openings is today 10-70 mm, but can be made larger. The hole size is chosen according to the type of material that is to be screened out at the outlet 7. There is thus a screening based on heel size. Although four sieve elements are shown in the drawings, a person skilled in the art realizes that in other embodiments several sieve elements 1 are used.

The waste separator is primarily designed to be used as a construction waste separator, but it is obvious that it can be used for many different material separations. For example for demolition materials, industrial waste and commercial waste. -won

Claims (1)

Ballistic separator, which separator comprises an inclined shaking table with at least four sieve elements (1) and two or more crankshaft arrangements supporting the sieve elements (1), where all crankshafts (12 ) are interconnected and driven as a synchronous unit and each individual crankshaft (12) does not support more than two sole elements (1), characterized in that each crankshaft arrangement comprises at least two crankshafts (12) operatively connected via an intermediate shaft (13). ) and a transmission, and that the crankshafts (12) are arranged offset relative to each other. Ballistic separator according to claim 1, characterized in that a drive motor (10) drives all crankshafts (12) either directly or indirectly. Ballistic separator according to claim 1 or 2, characterized in that the transmission (14) is a chain drive, toothed belt or gear. Ballistic separator according to any one of the preceding claims, characterized in that the motor (10) drives only one crankshaft arrangement directly, and that the drive movement to the other crankshaft arrangement or arrangements is transmitted via the sieve elements. Ballistic separator according to one of the preceding claims, characterized in that each individual sole element (1) performs a rotational movement in which the sole element (1) is given an acceleration in vertical direction which exceeds the acceleration in free fall. Ballistic separator according to any one of the preceding claims, characterized in that adjacent saddle elements (1) are variably mounted at different levels on the crankshafts (12), that the saddle elements (1) are supported by holders (16) rotatably mounted on the crankshafts (12). via bearings (17) and that each sieve element (1) has a strip (9) extending along at least the larger part of the sieve element (1) in longitudinal direction. 15 5. 513 451 ß,: _ Baiiist separator according to claim 6, characterized in that the irons (9) are sawtooth-shaped seen from the side. Baiiist separator according to any of the preceding claims, characterized in that the sàiieiementen (1) are chained with a damping matter), at least in the area receiving the avfaiiet. Baiiist separator according to any one of the preceding claims, characterized in that the sowing elements (1) have a greater inclination in relation to the horizontal at the lower end (6) than at the upper end (5). A biological separator according to claim 9, characterized in that the wafer is received in the region of the breaking point with different apertures of the seed elements (1).