DE9306556U1 - Device for separating objects - Google Patents

Description

Device for separating objects

The invention relates to a device for separating objects with a conveyor device, an air-permeable drum and at least one air flow device.

A device is known for separating objects in which the objects to be separated are fed into an air-permeable drum via a conveyor device. In the middle of this drum is a

A conveyor belt is attached to the drum, which is intended to transport the separated parts away. Air is blown into the rotating drum and sucked out, which is then intended to bring about the separation. However, the individual objects in the drum are moved like a mass on the

lowest point of the drum is only rolled back and forth. Heavier objects remain on top of the lighter ones. The air flowing in and sucked out from several sides is not able to divide this moving mass in such a way that a separation can be carried out.

Another known method is to pour the objects to be separated onto a conveyor belt. Sorters sitting on both sides of the conveyor belt can then carry out the appropriate sorting by hand.

The disadvantage is that manual sorting is very time-consuming. The speed and accuracy of the

Sorting is determined by the belt speed and the number of sorters.

The invention is based on the object of eliminating the above-mentioned disadvantages in a device for separating objects of the type mentioned at the outset and of creating a device for separating objects which is simple and safe in its operation.

According to the invention, the object is achieved by

that the conveyor is mounted above the air-permeable drum,

that the air flow device acts as an intake hood

and a blow-out hood and

that the intake hood with its intake opening is positioned opposite an exhaust end of the conveyor and the exhaust hood with its exhaust opening is positioned at an angle opposite the intake hood in the air-permeable drum

, o. . ,

are arranged.

The items to be separated include in particular the waste collected in the yellow bag of the Dual System Germany, such as body-shaped

Materials such as plastic bottles, packaging containers etc. or flat materials such as films, bags etc.

The items are separated as follows: 30

a) Impact of objects on the rotating drum,

b) Carrying and sucking the individual objects through the rotating drum depending on their

° Type of object, characterized by severity, flatness or the like,

c) Blowing off objects adhering to the outer surface of the drum and

d) Collecting the items depending on their subject

-Type of objects transported to different distances by the rotating drum.

The advantages achieved with the invention are in particular that the objects to be sorted are poured onto the outer surface of the drum. The rotating drum ensures that the objects are distributed into specific types of objects. In this way, heavier objects are sorted differently from light and flat objects.

, _ sticky objects due to the suction, the rotation

tion movement of the drum and the blowing out from the center of the drum. They are therefore subject to different fall curves and thus reach the designated collection areas safely.

It is advantageous if a nozzle is arranged above the air-permeable drum, the air flow of which is directed at a striking surface of the objects. This reduces the air pressure emanating from the suction hood.

__ Air flow supported and ensured that in particular 25

Smaller or flat objects stick to the surface of the drum as if they were attracted by an invisible magnet. It is advantageous if the intake and exhaust hoods are connected to a fan device. The fan device creates a negative pressure in the intake hood and an overpressure in the exhaust hood due to its circuit. In order to ensure that the individual objects are separated effectively, it is necessary that the strength of the air flows from the intake hood, the nozzle and the exhaust opening are precisely measured.

It is advantageous if the ejector of the

Conveyor device and the impact surface of the air-permeable drum are essentially opposite each other. As well as setting the air flows described above

includes the precise adjustment of the ejection end against -5

above the impact surface of the air-permeable drum to the measures that bring about a safe separation of the individual objects.

It is advantageous if the conveyor system consists of a conveyor belt and an oscillating conveyor trough underneath. The objects transported by the conveyor belt fall onto the oscillating conveyor trough underneath. The oscillating movements ensure that the objects, regardless of their size, 15

This prevents smaller objects stuck together from being treated like one large object when separated.

It is advantageous if the exhaust hood with its 20

Exhaust opening arranged at a first angle of -25° to +25* to a diagonal passing through the center of the intake opening and the center of rotation of the air-permeable drum opposite the intake hood

This angle determines that the drum upper 25

Objects adhering to the surface land on the intended pickup area either underneath or slightly further away from the drum.

It is advantageous if the intake hood is compared to a 30

Horizontal plane between 0° and 180°, preferably between 20° and 40° and 100* and 120*. If the suction hood is in the range between 20° and 40*, the discharge end of the vibrating conveyor trough is in front of the center of rotation of the drum.

The heavy objects arriving at the discharge end fall into the designated receiving area in front of the rotating drum. The lighter or flat objects

Objects that stick to the drum are drawn onto the surface of the rotating drum and then fall either due to their own weight or due to the

_ Air flow exiting from the exhaust hood outlet opening 5

to the intended receiving area. If, however, the suction hood is moved to the 100* and 120* area, the ejection end is behind the center of rotation of the drum. The heavier objects that hit the drum are accelerated by the drum and fly into the intended receiving area with a parabola that corresponds to their weight. The lighter or flat objects behave as already described. The position of the suction hood when separating the individual objects depends on the type, size and other operating conditions of the objects to be separated.

It is advantageous if the air-permeable drum is a perforated sheet drum. It is best to use non-rusting sheets made of stainless steel, titanium or similar. Of course, it is also possible to make the drum out of hard plastic. By choosing a very strong material, it is ensured that

the drum surface is not damaged by the impacting objects. The shape and size of the holes in the drum casing allow the air flow for suction and blowing out to be measured in terms of quantity.

It is advantageous if the air-permeable drum is connected to a controllable drive unit, for example a controllable gear motor.

possible to adjust the rotation speed of the drum in steps-35

to change it freely and thus optimally adapt it to the objects to be separated.

It is advantageous if the perforated sheet drum is open on the side opposite the drive unit. This makes it possible to easily and safely accommodate the intake hood and the exhaust hood with the connecting lines leading to the fan device inside the drum.

The invention is explained in more detail below using an exemplary embodiment. The following schematic representation shows

Fig. 1 a side view of a separation plant and

Fig. 2 a separation system according to Fig. 1 from the front 15

seen.

A separation system according to Fig. 1 and 2 consists of a rotating perforated sheet drum, which is driven by a controllable drive unit, e.g. a gear motor.

The perforated sheet drum is preferably made of stainless steel, titanium or plastic sheet. The shape and size of the holes in the drum shell can be selected in different sizes

Inside the perforated drum, which is in Quadran-25

tens I to IV, there is an intake hood 3 in the II. quadrant. Its intake opening 3' is located opposite a striking surface 2' of the perforated sheet drum 2. Opposite it in the IV. quadrant is an inflation hood 5, the exhaust opening of which is directed towards the

inner surface of the perforated sheet drum 2. If a diagonal D is drawn through the middle of the intake hood 5 and a center of rotation M of the perforated sheet drum, the exhaust hood is offset by an angle α . This angle α can be between -25* and +25°, so that the exhaust hood can be swiveled either over to the III. or I. quadrant. The intake hood 3 is also offset by an angle ß

from 0* to 180° pivotable relative to a horizontal plane H. Preferably, the angle ß is between 20* and 40° and 100° and 120°, so that the intake hood is in the _c II. quadrant or in the I. quadrant. The exhaust hood can remain in the IV. quadrant in the manner described. The intake hood 3 and the exhaust hood 5 are connected to a fan device (10). This is possible in particular because the perforated sheet drum is open on the side opposite the gear motor 6.

A conveyor device consisting of a conveyor belt 7 and an underlying vibrating conveyor trough 1 is arranged above the perforated sheet drum 2. An ejector

1' of the vibrating conveyor is located opposite the impact surface 2' of the perforated plate drum 2.

A receiving area 11 and a receiving area for receiving objects of an object type A 8.1, ... 8.&eegr; and an object type B 9.1, ... 9.&eegr; are arranged below the perforated sheet drum. Each receiving area 11 consists of a collecting funnel and a conveyor belt moving underneath. Of course, it is also possible to design the receiving area as a large container.

The separation of items 8.1, ... 8.&eegr; and 9.1, ... 9.&eegr; is carried out by the separation system as follows:
30

First, the perforated sheet drum 2 is put into operation. Then the fan device 10, the conveyor belt 7 and the vibrating conveyor trough l are switched on.

Objects 8.1, ... 8.&eegr; and 9.1, ... 9.&eegr; are poured onto the conveyor belt 7. The objects 8.1, ... 8.&eegr; are to be body-shaped and heavier

Objects of object type A and objects 9.1, ... 9.&eegr; are flat, lighter objects of object type B. Objects 8.1, ... 8.&eegr; and

9.1, ... 9.&eegr; leave the conveyor belt 7 and 5 together

fall onto the vibrating conveyor trough 1. By swinging the vibrating conveyor trough 1 back and forth, objects 8.1, ... 8.&eegr; and 9.1, ... 9.&eegr; that are stuck together are effectively separated from each other. They reach the discharge end 1' of the vibrating conveyor trough 1 and hit the impact surface 2' of the rotating perforated sheet drum 2 in free fall. The objects 8.1, ... 8.&eegr; of object type A fall onto the impact surface 2' due to their weight , slide on the surface of the

Perforated sheet drum down and fall onto the 15

specific recording area 11. The items 9.1, ...

9.&eegr; of object type B are held by the suction hood on the impact surface 2' . This adhesion is further supported by a

Vibrating conveyor trough 1 and perforated plate drum 2 arranged 20

Nozzle 4. The intake opening 3' is chosen to be large enough so that the intake air flow can flow through the incident surface 2' . The negative pressure generated by the intake hood 3 and the air flow of the nozzle 4

ensure that the items 9.1, ... 9.&eegr; of 25

Object type B is held on the perforated sheet drum. The rotational movement of the perforated sheet drum 2 transports them further and then either by their own weight or with the help of the

The air stream exiting the exhaust hood is blown off into the 30

to fall into the receiving area 12 intended for them. In order to be able to carry out the decisive separation into objects 8.1, ... 8.&eegr; and 9.1, ... 9.&eegr; in the area of the incident area 2' , the separation system must be adjusted accordingly. On the one hand, the position

tion of the discharge end 1' relative to the incident surface 2' . In addition, the rotation speed of the perforated sheet drum, the negative pressure of the suction hood 3'

and the overpressure of the blow-out hood 5. Through precise adjustment, a safe and optimal separation of the objects 8.1, ... 8.&eegr; and 9.1, ... 9.&eegr; is possible.

It is of course also possible if the suction hood is moved from the second quadrant to the first quadrant. This means that the discharge end of the vibrating conveyor is adjusted either exactly above the center of rotation M of the perforated sheet drum 2 or protruding beyond it. In this case, the objects 8.1, ... 8.&eegr; of object type A are accelerated by the rotational movement of the perforated sheet drum 2 in such a way that they hit the receiving area 11, which is then located next to the receiving area 12, with a certain flight parabola. The lighter or flat objects 9.1, ... 9.&eegr; of object type B behave as already described when the discharge hood 5 is at its

If the exhaust hood 5 moves its 20

Position in the direction of the III. Quadrant, the remaining

objects 9.1, ... 9.&eegr; adhering to the perforated sheet drum approximately under the center of rotation M of the perforated sheet drum. Due to the different arrangement of the intake hood 3 and the exhaust hood 5 in the various Qua-25

Different separation and rotation parameters can be defined for the individual drums I to IV inside the perforated drum 2. For example, it is possible to use two separate drums instead of the two receiving areas 11 and 12.

these by one or more recording areas to 30

expand. Because of the different acceleration, adhesion and falling behavior of the individual objects 8.1, ... 8.&eegr; and 9.1, ... 9.&eegr; they hit different places, which can simultaneously be designed into recording areas.

Do the objects to be separated 8.1, ... 8.&eegr; and 9.1, ... 9.ri have their designated receiving areas

10

11, 12, they can be transported further using the conveyor belt belonging to the receiving area 11 or 12. It is possible to carry out further sorting either manually or with another separation system located at the end of the conveyor belt. This cascading of separation systems further refines the separation process on the one hand, and on the other hand accelerates it even further.

LIST OF REFERENCE SYMBOLS

1 Vibrating conveyor 1' Ejectors 2 Perforated sheet drum 2' Conspicuous area 3 Intake hood 3' Intake opening 4 jet 5 Blow-out hood 5' Exhaust opening 6 Gear motor 7 Conveyor belt &ogr; · J. f · · · &ogr; · &eegr; Item, Item Type A 9.1, . . .9.&eegr; Item, Item Type B 10 Fan setup 11 Recording area 12 Recording area I; II; III; IV quadrant &agr; angle &bgr; angle D diagonal H Horizontal plane M Center of rotation

Claims (10)

Al protection claims: 1. Device for separating objects with a conveyor device (1; 7), an air-permeable drum (2) and at least one air flow device (3; 5), characterized in that - that the conveyor device (1; 7) is mounted above the air-permeable drum (2), - that the air flow device is designed as an intake hood (3) and an exhaust hood (5) and that the suction hood (3) with its suction opening (3') opposite an exhaust end (1') of the conveyor device (1; 7) and the blow-out hood (5) with its blow-out opening (5') of the suction hood (3) are arranged at an angle opposite one another in the air-permeable drum (2). 2. Device according to claim 1, characterized in that above the air-permeable drum (2) a Nozzle (4) is arranged, the air flow of which is directed to a 25 incident surface (2') for the objects (8.1, ... 8.n; 9.1, ... 9.n). 3. Device according to claim 1 or 2, characterized in that the intake and exhaust hoods (3; 5) are connected to a fan device (10). 4. Device according to one of claims 1 to 3, characterized in that the ejection end (1 ^# ) the conveyor device (1; 7) and the impact surface (2') 35 substantially opposite the air-permeable drum (2). A2 5. Device according to one of claims 1 to 4, characterized in that the conveying device consists of C a conveyor belt (7) and an underlying vibrating conveyor trough (1). 6. Device according to one of claims 1 to 5, characterized in that the blow-out hood (5) with its blow-out opening (5') is arranged at a first angle (α) of minus 25° to plus 25° to a diagonal (D) passing through the center of the intake opening (3') and the center of rotation (M) of the air-permeable drum (2) opposite the intake hood (3). 7. Device according to one of claims 1 to 7, characterized in that the suction hood (3) can be changed relative to a horizontal plane (H) by a second angle (ß) between 0° and 180°, preferably between 20° and 40° and 100° and 120°. 8. Device according to one of claims 1 to 7, characterized in that the air-permeable drum (2) is connected to a controllable drive unit, for example a controllable gear motor (6). 9. Device according to one of claims 1 to 8, characterized in that the air-permeable drum is a perforated sheet drum (2). 10. Device according to one of claims 1 to 9, characterized in that the perforated sheet drum (2) is open on the side opposite the drive unit (6).