DE3610355A1 - Process and device for the processing of waste fluorescent tubes - Google Patents

Abstract

Used fluorescent tubes are comminuted to give broken glass material. In a chamber closed so as to be as far as possible airtight and dust-tight, air is blown through the broken glass material. From the air removed from the closed chamber, the dust contained therein is separated out in a dust-separation device. The dust contains the coating material of the fluorescent tubes. The useful materials and pollutants contained therein can in this manner be recovered or disposed of, whereas the remaining broken glass is as free as possible of such useful materials and pollutants and can be sent for glass reclamation.

Description

The invention relates to a method for processing waste of fluorescent tubes and devices made of glass to carry out the procedure.

Fluorescent tubes have a coating on the inside of the tube, the mercury and other heavy metals or their Contains compounds and / or other environmentally harmful substances. Used fluorescent tubes or when they were removed accruing glass waste is therefore environmentally harmful Hazardous waste, the disposal of which is therefore complex and is difficult.  

The contained in the coating of the fluorescent tubes Substances are at least partially recyclable materials Recovery is of economic interest.

The object of the invention is therefore to provide a method for Waste treatment of fluorescent tubes to create that on the one hand, a significant reduction in hazardous waste the amount of waste to be classified and on the other hand a Recyclable material recovery possible.

This object is achieved with the method according to the invention, which is characterized by the procedural steps:

• a) the fluorescent tubes become broken glass smashed;
• b) in a largely airtight and dustproof closed space becomes air through the broken glass material blown;
• c) from the air discharged from the enclosed space the dust contained therein is separated.

Surprisingly, it has been shown that after a Smashing the fluorescent tubes into broken glass material does not contain large amounts of glass dust, in very simple Way, namely by passing an air stream through it complete separation of the dusty coating material of the glass is possible. The dusty Coating material is discharged together with the air and then in a conventional dust removal process deposited. The resulting dust, which largely comes from the Coating material of the fluorescent tubes can either be disposed of as hazardous waste, the comparatively small amount of dust disposal without allows greater effort, or it can expediently be recycled. The  remaining broken glass material is largely free of Dust residues of the coating material and can therefore like conventional glass waste can be treated, for example can also be recycled.

The air is expediently removed after the separation of the Dust in a closed cycle through the Broken glass material. This has the advantage that the The degree of separation of the dust separation process is not very high Requirements must be made because of the still in the Air remaining dust is harmless as it is in the Circuit is led back into the processing chamber.

It is particularly advantageous during the glass breakage material of blowing the air loose and moving hold. This can either be through the blown or air drawn through itself happen, the layer of Broken glass material in the manner of a fluidized bed and is ventilated, or the broken glass material can be mechanical by means of a conveying surface which is excited to oscillate be relaxed and moved.

A preferred device for performing the method is characterized in that in one with a lockable loading opening and a lockable Discharge opening provided, closed processing room lowerable by means of a stamp drive device Shattering stamp is arranged that the processing room a perforated base provided with sieve-like openings with air supply holes has that air outlet openings of the processing space over an air line connected to a dust collector are, from which an air line in a closed circuit leads the air supply holes of the perforated bottom, and that in Air circuit a compressor is arranged. This device is of simple construction and enables with the preparation of a relatively small amount of time large amount of fluorescent tubes. Harmful influences  the environment is largely excluded by the fact that the Smashing process and the subsequent separation process executed in the same, closed processing room will.

Further refinements of the inventive concept including a further embodiment of an inventive Device are the subject of further subclaims.

The invention is explained in more detail below using exemplary embodiments explained, which are shown in the drawing. It shows:

Fig. 1 is a device for waste recycling of fluorescent tubes in section,

Fig. 2 shows a section along the line II-II in Fig. 1 and

Fig. 3 shows another embodiment of a device for waste treatment of fluorescent tubes in section.

The device shown in FIGS. 1 and 2 has a lockable processing space 2 in a frame 1 , next to which a loading chamber 3 is located. The flat loading chamber 3 , which is open at the top, can be closed with a hinged lid 4 and has a fixed base 5 and a movable frame 6 . After the fluorescent tubes 7 to be removed (indicated by dashed lines) have been placed in the loading chamber 3 and the cover 4 has been closed, the frame 6 can be moved into the processing space 2 by means of a pressure-actuated cylinder 8 through a loading opening 9 . A closure plate 10 closing the loading opening 9 is connected to the frame 6 and opens as soon as the frame 6 is moved into the processing space 2 .

The fluorescent tubes 7 carried along by the frame 6 fall into the lower part of the processing space 2 . A box-like cover 11 is in its raised position during the loading process, which is shown in FIGS. 1 and 2. The cover 11 is provided with pressure medium-actuated cylinders 12 attached to the frame 1 . Through this, it can be sealingly lowered onto the lower part 13 of the processing space 2 after the loading process has been carried out and the loading opening 9 has been closed again.

On the cover 11 fluid-actuated cylinders 14 are mounted, which form a punch drive device for a disposed in the processing space 13 smashing punch which in the illustrated embodiment, a punch plate 15, which extends substantially over the entire bottom of the treatment space 2 and can be raised inside the processing chamber 2 and lowerable is. The stamp plate 15 has a plurality of air openings 16 and carries on its upper side a fine-mesh sieve 17 covering these air openings 16 .

Air outlet openings 18 lead via telescopic air lines 19 to a dust separator device, which is shown schematically in FIG. 2, for example as a filter 21 . An air line 22 leads from there via a compressor 23 and a compressed air reservoir 20 to a plurality of wind chambers 24 below the processing space 2 . A perforated floor 26 provided with numerous air supply holes 25 forms the ceiling of the wind chamber 24 and at the same time the floor of the processing space 2 .

After loading the processing space 2 with fluorescent tubes, the stamp plate 15 is lowered. The lower surface of the stamp plate 15 is provided with regularly distributed stamp projections 27 which, in the exemplary embodiment shown, are flat but sharp-edged ribs. When the stamp plate 15 hits the fluorescent tubes accumulated in the processing space 2 , they are shattered into broken glass material, expediently into fragments of 5-15 cm ² . The broken glass material is loosened and aerated by the air entering the processing space 2 from below through the air supply holes 25 , the dust-like coating material of the fluorescent tubes being carried along. The dust-laden air passes upward through the air openings 16 of the stamp plate 15 and leaves the processing space 2 , which is otherwise sealed airtight and dustproof, through the air lines 19 . The dust-like coating material is deposited in the filter 21 ; the air is fed back to the processing space via the blower 23 and the wind chamber 24 .

After this process has been completed, an unloading opening 29 which is closed by a flap 28 is opened on a side wall of the processing space 2 . The broken glass material contained in the processing chamber 2, is ejected through an ejection slide 30, which is located in the opposite side surface of the processing chamber 2 by means of a fluid-actuated cylinder 31st The processing space 2 can then be loaded again in the manner described.

As can be seen from Fig. 1, the meeting closing surfaces between the lid 11 and the lower part 13 of the processing space 2 , between the closure plate 10 and the edge of the loading opening 9 and between the flap 28 and the edge of the discharge opening 29 are chamfered to an automatic Centering and thus to achieve an effective mutual sealing of these parts without having to provide expensive and sensitive seals such as rubber sealing lips.

Another embodiment of a device for processing waste from fluorescent tubes is shown in greatly simplified form in FIG. 3.

In a frame 32 an inclined slide 33 is arranged, on which the used fluorescent tubes to be processed are placed. At the lower end of the slide 33 there are two profiled shattering rollers 34 which are driven in opposite directions and shatter the fluorescent tubes between them into broken glass material which falls downward in a shaft 35 . Via an outlet 36 of the shaft 35 , the broken glass material arrives in a loading opening 37 of a chamber 38 , which is movably mounted on inclined springs 39 . Inclined handlebars 40 guide the chamber 38 so that they can perform directional vibratory movements. For this purpose, the chamber 38 is connected to an oscillating drive 42 via an articulated connecting rod 41 . The oscillating movements of the chamber 38 are directed so that the broken glass contained in the chamber 38 executes micro-throwing movements, through which it is conveyed to an unloading opening 43 of the chamber 38 .

Via air supply lines 44 , which are only indicated schematically in FIG. 3, the chamber 38 is charged with air, which is passed through the swirled, moving bed of broken glass material and leaves the chamber 38 again via air discharge lines 45 . The escaping air entrains the dusty coating material of the fluorescent tubes in the manner already described in connection with FIGS. 1 and 2, flows through a dust separator and re-enters the chamber 38 through the air supply line 44 .

The cleaned glass breakage material passes from the discharge opening 43 into a discharge chute 46 which can be closed by movable and / or elastic flaps 47 in order to prevent air or dust from escaping.

In the area of the loading opening 37 and the discharge opening 43 of the movably mounted chamber 38 , bellows 48 are provided, which likewise prevent air and dust from escaping at these points.

The described procedure, the fluorescent tubes initially To crush broken glass and then the adhering dust containing pollutants by means of a Carrying the air flow carried through can also in be realized in another way. Only two were shown possible embodiments of devices. The Devices described can be used as fixed systems or be designed as portable devices.

Claims (15)

1. Process for waste treatment of fluorescent tubes consisting of glass, characterized by the process steps:

• a) the fluorescent tubes are broken into broken glass material;
• b) in a largely airtight and dustproof room, the air is blown through the broken glass material;
• c) the dust contained therein is separated from the air discharged from the enclosed space.

2. The method according to claim 1, characterized in that the Air after separating the dust in a closed Circuit is again passed through the broken glass material. 3. The method according to claim 1, characterized in that the Broken glass material loosened during process step b) and kept moving. 4. The method according to claim 3, characterized in that the Broken glass material during process step b) by the air passed through from below is whirled up. 5. The method according to claim 3, characterized in that the Broken glass material during process step b) on a conveying surface driven for directed oscillating movement lies. 6. A device for carrying out the method according to any one of claims 1 to 4, characterized in that (2) a lowerable in a vessel equipped with a closable charging opening (9) and a closable discharge opening (29), closed processing chamber by means of a plunger drive device (14) Shattering stamp ( 15 ) is arranged that the processing space ( 2 ) has a perforated base ( 26 ) with sieve-like openings with air supply holes ( 25 ), that air outlet openings ( 18 ) of the processing space ( 2 ) are connected via an air line ( 19 ) to a dust separator ( 21 ) are, from which an air line ( 22 ) leads in a closed circuit to the air supply holes ( 25 ) of the air floor ( 26 ), and that a compressor ( 23 ) is arranged in the air circuit. 7. The device according to claim 6, characterized in that a compressed air reservoir ( 20 ) is arranged in the air circuit. 8.The device according to claim 6, characterized in that the processing space ( 2 ) has a liftable cover ( 11 ) and that the shattering stamp ( 15 ) and the stamp drive device ( 14 ) are attached to the cover ( 11 ). 9. The device according to claim 6, characterized in that a loading chamber ( 3 ) is arranged in front of the loading opening ( 9 ) of the processing space ( 2 ) and that in the loading chamber ( 3 ) lying fluorescent tubes ( 7 ) by means of a feed slide ( 6 ) in the loading opening ( 9 ) can be conveyed. 10. The device according to claim 9, characterized in that the loading chamber ( 3 ) can be closed by a cover ( 4 ). 11. The device according to claim 6, characterized in that the smashing stamp is a substantially over the entire floor ( 26 ) of the processing space ( 2 ) extending stamp plate ( 15 ) having a plurality of air openings ( 16 ), and in that the air outlet openings ( 18 ) of the processing space ( 2 ) are arranged above the stamp plate ( 15 ). 12. The apparatus according to claim 11, characterized in that the lower surface of the stamp plate ( 15 ) is provided with regularly distributed stamp projections ( 27 ). 13. The apparatus according to claim 11, characterized in that on the upper side of the stamp plate ( 15 ) an air openings ( 16 ) covering fine mesh sieve ( 17 ) is attached. 14. The apparatus according to claim 6, characterized in that a movable ejection slide ( 30 ) is arranged in a side wall of the processing space ( 2 ) and that the discharge opening ( 29 ) which can be closed with a flap ( 28 ) is located in the opposite side wall of the processing space ( 2 ) is located. 15. Device for performing the method according to one of claims 1 to 3 and 5, characterized in that at least two counter-rotating, profiled shattering rollers ( 34 ) via a feed shaft ( 35 ) with a loading opening ( 37 ) of a movably mounted chamber ( 38 ) are connected that the chamber is connected to an oscillating drive ( 42 ) and has an unloading opening ( 43 ), and that the chamber ( 38 ) has at least one air supply opening ( 44 ) and at least one air outlet opening ( 45 ), which have a dust separating device Circuit are interconnected.