DE9415023U1 - Device for separating bulk particles - Google Patents

Description

Device for separating bulk particles

It is known to separate bulk material according to the type of its components by exposing it to an air stream and at the same time to gravity or centrifugal force, whereby the heavier particles travel different paths than the lighter and more floating particles, which can be used to direct them to different destinations and thereby separate them from one another. This principle has the disadvantage that high flow speeds are required for high separation accuracy, which cause high energy requirements. The energy requirements are particularly high when coarser particles are present. The invention seeks a device for separating bulk material particles according to their density and/or shape properties, which has sufficient separation accuracy with low energy expenditure, even with relatively coarse bulk material particles.

The solution according to the invention consists in that a relative to the horizontal direction, inclined in the ascending direction

Dresdner Bank AG Hamburg 04 03*0*448 00 (B*l2 2*0*0* 800* OO^VosftJank Hamburg 1476 07-200 (bank code 200 100 20)

moving, gas-permeable and pressurized from the underside, essentially impermeable to the bulk material conveying surface is provided and that means for feeding the bulk material onto the conveying surface as well as devices for picking up, on the one hand, the particles slipping off the conveying surface in the opposite direction to the conveying direction and, on the other hand, the particles carried along by the conveying device are provided.

The particles that have reached the conveyor surface are, on the one hand, subject to gravity, which tends to make them slide against the conveyor movement. On the other hand, they are subject to friction, which tries to take them along with the conveyor surface. The friction is not only dependent on their weight, but also on the strength of their suction onto the conveyor surface, which is caused by the fact that the particles each cover a part of the gas-permeable conveyor surface and are therefore exposed to the negative pressure acting underneath. The larger a particle is, the larger the area it covers on the conveyor surface and the greater the force exerted on it by the negative pressure. Therefore, the rough rule is that particles that are small in relation to their weight slide off, while particles that are lighter in relation to their size are taken along by the conveyor. It is also shown that particles that lie flat against the conveyor are more exposed to the suction effect and are therefore more easily carried along by the conveyor than particles with an irregular surface structure. The device is therefore also suitable for separating particles with different surface structures. The components of bulk material often differ not only in their density, but also in a typical way in their surface structure. The separation accuracy is therefore increased by the invention, particularly in those cases in which the specifically heavier particles have an irregular surface structure and the specifically lighter particles are flat or elongated. For example, typical components of building rubble are, on the one hand, mineral, heavy components

with a compact, irregular surface shape and, on the other hand, flat or elongated plastic and wood particles. The device according to the invention is highly suitable for such cases.

It is advisable for the angle of inclination of the conveying surface to increase in the opposite direction to the conveying direction and decrease in the conveying direction, as is primarily the case with the surface of a drum rotating on a horizontal axis. As soon as a particle has started moving in one direction or the other after impact, the tendencies that reinforce it in this direction of movement increase, thereby increasing the stability of the process. It is advisable for the angle range of the drum within which the bulk material is placed on its surface to be between 60 and 20° above the horizontal direction (tangent direction). The means for feeding the bulk material onto the conveying surface are formed, for example, by a conveyor that ends at a distance from the conveying surface, so that the material falls freely from the conveyor onto the conveying surface. Depending on the speed and direction of the conveyor, the bulk material can be given a movement component parallel to or against the direction of movement of the conveying surface, thereby utilizing the inertial effect of the particles in connection with the separation process.

According to a particularly important feature of the invention, a device is provided for generating a blowing stream that passes through the bulk material that is being fed in, i.e. that is still in free flight to the conveying surface and/or has just reached the conveying surface. This blowing stream should be guided in an upward direction in order to strengthen the tendency of the specifically lighter particles to separate.

Preferably, the blowing stream is directed at an acute angle to the conveying surface or parallel to it, so that it follows the drum surface due to the Coanda effect and

on the particles on the drum surface. It modifies the separation mechanism described above in that those particles that offer a greater flow resistance in relation to their weight are pushed in the conveying direction. The influence of the surface shape and the suction on the drum surface described above is thereby pushed back in favor of the influence of the density of the particles. By appropriately selecting the flow speed on the one hand and the suction force acting on the conveying surface on the other hand, it is therefore possible to adjust the influence of the surface shape of the particles in relation to their density in the separation process. In this way, the device can be largely adapted to different properties of the bulk material components. The separation accuracy can be increased considerably. It can be increased further by connecting several devices of the type according to the invention in series, which can then also be adjusted differently (for example specifically with regard to certain bulk material components) with regard to the desired influence of the shape or density of the particles.

It is not necessary for every single particle to actually reach the surface of the conveyor during the separation process. Rather, the device can be set up so that particularly heavy and compact particles fall off before they reach the conveyor surface, while particularly light particles are simply carried along by the air flow and over the conveyor surface. It can also be a conscious effort to ensure that as large a proportion of the bulk material as possible is already separated by this type of air sifting before a smaller, less easily separated proportion of the bulk material reaches the conveyor surface.

The negative pressure under the conveying surface is preferably selected in the range of 5 to 15 mbar. The appropriate values can be easily determined by trial and error. Depending on

•« at it W ♦ « * * ft-

Depending on the type of bulk material, values outside this range may also be considered. The perforation or porosity of the conveying surface is as fine as possible in relation to the bulk material. In some cases, for example, a perforated sheet metal drum is used in which the individual holes have a diameter in the range of 1 to 3 mm, while the average center distances between the holes closest to each other are in the range of 1.5 to 4 times the hole diameter. In some cases, a finely porous surface may be useful, which can be obtained, for example, by stretching a fiber fleece over a support surface, which can be formed by a metal sieve or a perforated sheet metal surface.

In practical tests, blowing stream speeds in the range of 5 to 40 m/s have proven to be effective. The flatter the conveying surface is inclined relative to the horizontal in the area in which the blowing stream is effective, the lower the blowing speed can be. This means that the energy requirement can be reduced to a low value even with comparatively coarse bulk material.

According to a special feature of the invention, the blowing flow is not greater than the flow sucked out by the conveying surface, whereby the blowing and suction air are circulated. This eliminates the need to remove potentially dust-laden air and the device can be encapsulated to prevent dust from escaping.

The effectiveness of the device according to the invention is particularly good when the bulk material being treated does not have too wide a grain spectrum. Depending on the type of starting material to be treated, it may therefore be expedient to install a classifying device upstream, which is designed as a sieve, for example.

When using a drum as a conveying surface, it is advisable to provide dividing walls inside the drum, which

allow the suction pressure to act only on a part of the drum circumference. It is sufficient to allow it to begin shortly before the treatment zone, which is in front of the highest circumferential point of the drum. It can end immediately behind the highest point; in any case it should end before the lowest circumferential point of the drum, so that the lightest pieces held to the drum surface by the suction pressure can still be released in the receiving area for the light material. In a circumferential area of the drum not subject to negative pressure, a device should be provided for detaching adhering particles. Furthermore, in such an area, a device should be provided for ejecting particles that have reached the inside of the drum. Both purposes can be achieved by a device for generating an internal overpressure in a limited angular range of the drum circumference.

The higher separation accuracy in terms of density and shape properties of the bulk material components makes it possible to drastically reduce the proportion of rubble and garbage that has to be sent to the landfill compared to conventional systems. Since the light materials can be removed without the carrier air having to be led outside and dusted, no expensive filter systems are required. There is also no need to wash out fine particles from the carrier air, so that the portion to be landfilled is dry and the landfill costs are reduced due to the lower weight compared to wet waste.

The invention is explained in more detail below with reference to the drawing, which schematically illustrates an embodiment of the invention. Therein: Fig. 1 shows a plan view of the entire system and Fig. 2 shows a partial view of the core part according to the invention.

The bulk material to be treated, in particular construction rubble, is fed to a screening drum 1 by means of the conveyor belt 2. The coarse portion is fed to a sorting belt 3 for manual sorting.

In areas 4, 5 and 6, grain fractions of, for example, 0-8, 8-32 and 32-80 mm are removed by means of conveyors 7 and fed to two light material separators 8, 9. The light materials separated here are fed onto a conveyor belt 10 to be sent to landfill, for example, while the heavy fraction is fed onto a conveyor belt 11, where it can be subjected to manual re-sorting if necessary. Fraction 0-8 is fed to a separate treatment.

The principle of the lightweight separators 8, 9 is shown in Fig.2.

The respective bulk material fraction passes from the conveyors 7 to a conveyor 12, which in the example shown is shown as a conveyor belt but can also be formed by a chute, a vibrator or the like. Its task is to throw the bulk material as evenly as possible towards the drum 13, which is driven to rotate continuously around its horizontal axis in the direction of the arrow and whose peripheral surface forms the conveying surface mentioned at the beginning and in the claims. In a tested example, which does not limit the scope of the invention, the conveying speed of the conveyor was about 0.5 m/s and the peripheral speed of the drum 13 was about 0.5 m/s. The drum diameter was 0.6 m. The adjustable distance of the discharge point of the conveyor 12 from the circumference of the drum was 20 to 80 mm. This resulted in the bulk material thrown off by the conveyor 12, when no blowing stream was switched on, hitting a peripheral point 14 of the drum 13, the tangential angle of which was inclined between 40 and 50° relative to the horizontal direction.

A blowing nozzle 15 is arranged below the conveyor 12, which directs an air flow indicated by an arrow at a speed of, for example, 5 to 40 m/s approximately tangentially onto the surface of the drum, namely onto the impact area 14 or an area located slightly above it. In the example tested, the nozzle angle relative to the horizontal direction was approximately 30°.

Inside the drum 13, an area 18 is separated by partition walls 16 and 17, which is connected to the suction side of a blower 20 by means of a line 19 and in which a negative pressure, indicated by a minus sign in the drawing, therefore prevails. The drum shell is formed by a perforated steel sheet with a hole diameter of 3 mm and a center distance of the closest holes of approximately 8 mm. The negative pressure in the space 18 therefore leads to a suction flow through the drum surface from the outside to the inside.

Below the drum 13, on the feed side, a receiving device 21 is provided, which can be formed by the conveyor belt 10 shown in Fig. 1, by a chute leading to this conveyor belt, a container or the like. A corresponding receiving device 22 is arranged below the drum 13 on its rear side, which can be the conveyor belt 11 or any other suitable device.

Dense and compact objects thrown off by the conveyor 12 are little affected by the blowing stream of the nozzle 15 and either fall down without reaching the peripheral part of the drum 13 subject to suction pressure, or slide off this part of the drum surface because they cannot be lifted by the blowing stream or by the increased friction on the drum surface caused by the suction force. They reach the receiving device 21.

Another, particularly light or particularly floating part of the particles, as indicated at 24, is caught by the air flow and carried over the drum 13. These particles fall beyond the drum into the receiving device 22. Another part of the bulk material reaches the drum surface and is carried along by it, because the increased inclination of the drum surface due to the drum suction force on the one hand and the blowing flow of the nozzle 15 pushing in the same direction on the other hand are stronger than the downward weight. They are carried along over the top of the drum to fall down on its back and reach the receiving device 22.

In the case of construction waste, the receiving facility 21 primarily contains mineral components and metal pieces, provided the latter have not previously been magnetically separated, while the receiving facility 22 mainly contains plastic parts, wood, paper, cardboard, foams, aerated concrete pieces, insulation materials and the like. The product accruing in the receiving facility 21 is a marketable building material, for example for roads and substructures. The light materials accruing in the receiving facility 22 can, depending on their type, be deposited, incinerated as waste or (if necessary after further sorting) recycled.

In order to save energy, the negative pressure area 18 of the drum circumference is not kept larger than necessary. The partition wall 17 can therefore already be provided in the apex area of the drum. However, it is also possible to arrange it further back in the direction of rotation of the drum, for example near the lower apex area. There, a region 27 is separated off by partition walls 25, 26, which is connected to the pressure side of the blower 20 via a line 28 and is thus kept at positive pressure, which is indicated by a plus sign. This creates an air flow from the inside to the outside in the corresponding peripheral section of the drum, through which any air that has passed through the perforation of the drum can be drawn into the drum.

material that has got into the drum is expelled again. In addition, any particles that may have become stuck on the outside of the drum are released. They are collected by a collecting device 29 and used in a way that is appropriate to their type. If the material is essentially mineral fines, it can be collected and sold as a building material, for example.

The line routing indicated in dotted lines shows that the air flow sucked out in the drum 18 is used entirely to feed the nozzle 15 and the pressure area 27. If the required suction flow does not match the amount of pressure flow required, the blower 20 can take in a further portion from the environment or blow it out into the environment. In any case, a closed circuit is maintained by the fact that the system, insofar as it is touched by the described air flows, is enclosed in a housing indicated by the dashed line 30, which has the same pressure as the outside atmosphere or has a slight negative pressure in order to prevent dust from escaping.

Claims (18)

Protection claims 1. Device for separating bulk material particles according to density and/or shape properties, characterized in that a conveying surface (13) is provided which is inclined relative to the horizontal direction, moves in an upward direction, is gas-permeable and subjected to negative pressure from the underside and is essentially impermeable to the bulk material, and the means (12) for feeding the bulk material onto the conveying surface (13) and devices (21, 22) for picking up, on the one hand, the particles which slide off the conveying surface in the opposite direction to the conveying direction and, on the other hand, the particles which are carried along by the conveying device are provided. 2. Device according to claim 1, characterized in that the angle of inclination of the conveying surface (13) increases against the conveying direction and decreases in the conveying direction. 3. Device according to claim 2, characterized in that the conveying surface is formed by the outer circumference of a rotary-driven drum. 4. Device according to claim 3, characterized in that the area (14) for feeding the bulk material onto the drum (13) lies mainly in the angular range of 60-20° (tangential angle) above the horizontal direction. 5. Device according to one of claims 1 to 4, characterized in that the means for feeding the bulk material are formed by a conveyor (12) ending at a distance from the conveying surface (13). 6. Device according to one of claims 1 to 5, characterized in that a device (15) is provided for generating a blowing stream passing through the bulk material being fed. 7. Device according to claim 6, characterized in that the blowing stream is increasing. 8. Device according to claim 6 or 7, characterized in that the blowing stream is directed at an acute angle or parallel to the conveying surface (13) in the bulk material feed area (14) or slightly above it. 9. Device according to claim 8, characterized in that the blowing flow is not greater than the flow sucked off by the conveying surface (13). 10. Device according to one of claims 1 to 9, characterized in that the negative pressure under the conveying surface is between 5 and 15 mbar. 11. Device according to one of claims 1 to 10, characterized in that the speed of the blowing stream is between 5 and 40 m/s. 12. Device according to one of claims 1 to 12, characterized in that it is sealed off from the atmosphere by a capsule (30). 13. Device according to one of claims 1 to 12, characterized in that a classifying device (1) is connected upstream thereof. 14. Device according to one of claims 3 to 13, characterized in that the internal suction pressure on the drum circumference ends before the lowest circumferential point of the drum. 13 * 15. Device according to claim 14, characterized in that a device for detaching adhering particles is provided in a peripheral region of the drum 13 not subjected to negative pressure. 16. Device according to claim 14, characterized in that a device is provided for ejecting particles which have reached the inside of the drum (13). 17. Device according to claim 15 or 16, characterized in that the device for detaching particles adhering to the outside and/or for ejecting particles that have reached the inside is a device (25, 26, 27, 28) for generating an internal overpressure. 18. Device according to one of claims 1 to 17, characterized in that it is part of a plant for sorting waste materials, in particular building rubble,