EP0597335B1 - Process and apparatus for renerating used foundry sand - Google Patents

Description

The invention relates to a method for the regeneration of foundry sand by circulating the old sand in a processing room and thereby bringing about the friction forces breaking up the binder shell and releasing the grain of sand from the old sand particles, and the resulting mixture of sand and binder particles being physically cleaned while enriching the sand content. Furthermore, the invention relates to a device for the regeneration of foundry sand with a processing container, which has a controllable inlet, an outlet on its circumference close to the floor and at least one rotating tool rotating above the floor.

The processing of foundry sand has become an imperative due to environmental protection regulations in order to reduce the volume of landfills of foundry sand. All known processes aim to recover the molding sand and either destroy the binders without polluting the environment or with small volume to make landfill capable. The main problem with the processing of used sands is the large number of different binders, organic and inorganic, which have led to the development of different processing methods. In the case of organic binders, thermal processes are particularly suitable, since these binders are not thermally stable. On the one hand, these thermal processes require a large amount of energy, on the other hand, they lead to gas emissions, which requires additional effort in the removal of environmentally harmful gases. For this reason, mechanical friction and abrasion processes have been increasingly investigated in the past, which are anyway the only effective way of removing the binder shell on the grain of sand with inorganic binders.

Combined thermal-mechanical methods are also known, in which, for example, the old sand is circulated in a single processing container and simultaneously or batchwise exposed to a burner flame and is further mechanically loaded by means of mechanical friction and scouring tools in order to break the binder casing (EP 0 125 384 A1) . In another known method (EP 0 343 272 A1), the thermal pretreatment and the mechanical aftertreatment take place in separate rooms. In the mechanical processing room, the thermally pretreated old sand is circulated using rotating tools and at the same time fluidized using compressed air coming in from below and this fluidizing air is drawn off above the sand surface. The binder casing is to be separated from the sand particles by the rotating tools, unless already done in the thermal pretreatment. The detached binder particles are to be constantly removed with the fluidizing air will. Apart from the problematic thermal pretreatment, the efficiency in the mechanical stage is poor.

In another, purely mechanical process (DE 41 06 737 A1), the used sand is only subjected to a mechanical treatment by being circulated in a scrubbing drum. Here, too, the binder dust that is produced is pneumatically conveyed away, which in turn requires fluidization, or at least strong aeration, of the batch of containers. This method is mainly only suitable for old clay-bound sands.

The invention has for its object to effectively regenerate old sands with mixtures of different binders, especially problematic binders such as bentonite and / or water glass, in a purely mechanical way.

On the basis of the method mentioned at the beginning (EP 0 343 272), this object is achieved in that a part of the mixture of substances is drawn off from the processing space into a separate cleaning space and cleaned after passing through the friction zone, and the pre-cleaned old sand is returned to the processing space.

In the method according to the invention, which does not require thermal pretreatment of the old sand, the old sand in the processing room is only subjected to friction and pressure forces, the sand batch contained in the processing room bearing its own weight on the friction zone, so that intensive mechanical pressure is exerted by the processing tools on the particles, but also intense friction and abrasion forces between the particles, which on the one hand to rub off the binder shell, and on the other hand to shred of the particles of the binder casing so that two relatively sharply separated grain spectra, sand particles on the one hand and binder particles on the other hand, are present in the mixture of substances leaving the friction zone. This mixture of substances is drawn off from the friction zone of the processing area and transferred to a separate cleaning area, in which the binder particles are largely separated. The used sand pre-cleaned in this way is transferred again from the cleaning chamber into the processing room in order to rub off any adhering binder in a further treatment. These circulation cycles are carried out several times if necessary and the finally sufficiently binder-free regenerated sand is returned to the production process. It is essential for the method according to the invention to separate the processing and cleaning stages, so that each can be carried out under optimal conditions. It is particularly important to note that there is no fluidization in the processing area and that the batch contained in the processing area has the lowest possible pore volume in order to allow the friction and abrasive forces to act on the largest possible surface of the sand particles.

This can be supported by reducing the pore volume in the material mixture in the area of the friction zone. This in turn can be done in various ways, for example by additional mechanical pressure on the sand batch, in particular in the area of the friction zone, in order to obtain a compaction of the bed. It has also proven to be very effective if air is sucked out of the friction zone when the substance mixture is removed from the processing space. The method according to the invention is almost a step ahead of the prior art contrary way, in that not air is added to the processing space, but the processing space, in particular the friction zone, is as free of air as possible.

In a preferred embodiment, it is provided that the old batch of sand moves under gravity from top to bottom into the friction zone in the processing space and the material mixture is drawn off essentially horizontally in the area.

In the method according to the invention, therefore, the entire sand batch of the processing space is loaded on the friction zone with the previously described advantage of high particle density and low pore volume in the friction zone. In addition, the mixture of substances is drawn off directly from the area of the friction zone in order to feed it for pre-cleaning (separation of the binder particles).

In a further advantageous embodiment it is provided that the mixture of substances is mechanically displaced outward in the region of the friction zone and pneumatically conveyed away at the periphery of the processing space.

The mixture of substances is displaced in the area of the friction zone by the pressure and circulation forces. The pneumatic conveying away of the mixture of substances at the periphery of the processing space creates a negative pressure near the friction zone, which contributes to reducing the pore volume of the bed in the friction zone.

To achieve the object in terms of device technology, the invention is based on the device mentioned at the beginning (EP 0 343 272), which according to the invention is characterized in that outside the processing container a cleaning chamber for separating sand and binder particles is provided, which is arranged in a conveyor circuit connecting the outlet of the processing container with its inlet.

In terms of device technology, the processing container and the cleaning chamber are in a closed conveyor circuit. After the untreated old sand has been placed on the processing container, it may pass through the cleaning chamber and the processing container several times and is continuously cleaned of the binder particles accumulating in the friction zone.

If necessary, a buffer container can be arranged between the cleaning chamber and the processing container in order to obtain a homogenization of the mixture of substances in front of the processing zone and to ensure that the bulk material column in the processing container is always the same.

According to a preferred embodiment, it is provided that the reaming tool rotates directly above the bottom of the processing container and the drain is arranged in the rotating plane of the reaming tool. The mixture of substances is therefore removed directly from the friction zone.

The reaming tool can have two or more rice arms which extend into the region of the circumference of the processing container.

If necessary, the pressure on the friction zone can be increased in that a pressure generating element acting on the sand filling, for example a worm, acts above the grinding tool. is arranged.

In a preferred embodiment it is provided that the conveyor circuit is formed by a pneumatic conveyor device which has an injector at the outlet of the processing container and a conveyor line leading from there into the cleaning chamber.

In this way, a negative pressure acts directly on the friction zone, which leads to a reduction in the pore volume in the friction zone.

The cleaning chamber can basically have any structure. In connection with a pneumatic conveying device, a design is recommended in which the cleaning chamber is designed as a centrifugal separator and has a dust extraction.

Finally, the processing container can have a plurality of processes distributed around the circumference in order to increase the circulation quantity, and possibly also to be able to control it. In such a case, a pneumatic delivery line is connected to each outlet.

Figur 1:

Eine schematische Ansicht einer Vorrichtung zum Aufbereiten von Altsand und

Figur 2:

eine schematische Ansicht einer Gesamtanlage.

The invention is described below using an exemplary embodiment. The drawing shows:

Figure 1:

A schematic view of a device for processing used sand and

Figure 2:

a schematic view of an overall system.

In Fig. 1, a processing container 1 can be seen, which has an inlet 2 on its top, the is controllable by means of a flap 3. Immediately above the bottom 4, the processing container 1 has an outlet 5. The outlet 5 opens into a pneumatic conveyor line 6 with a rising conveyor. The pneumatic delivery line 6 connects the outlet 5 to a cleaning chamber 7 (see FIG. 2), which in the exemplary embodiment shown is designed as a centrifugal separator and is placed on a buffer silo 8. The buffer silo 8 in turn is connected to the processing container 1 via the inlet 2, so that a closed conveyor circuit is produced from the outlet 5 of the processing container 1 via the riser 6, the cleaning chamber 7, the buffer container 8 and the inlet 2 of the processing container.

As shown in FIG. 2, the used sand accumulating in the foundry is collected in a silo 9 and, from there, pneumatically or mechanically, as indicated by the conveying line 10, it is fed to the cleaning chamber 7 and from there via the buffer silo into the processing container 1, to be recirculated into the cleaning chamber 7 after it has passed through the outlet 5 and the riser 6. A branch line 11 is connected to the riser 6, which leads into a silo 12, in which the regenerated sand is conveyed after a certain number of working cycles in the processing container 1. The sand is drawn off from the regenerated silo 12 into the sand preparation and / or into the core production of the foundry. The cleaning chamber 7 and the silos 9, 10 are in turn connected to the suction line 13 of a dedusting system 14.

As shown in FIG. 1, a revolving reaming tool 15 is arranged within the processing container 1 directly above its bottom 4, which several to Rough arms 16 reaching approximately to the circumference of the processing container 1. The reaming tool 15 is rotated by a drive shaft 17 mounted beneath the floor and penetrating it. At the level of the rotating grinding tool 15, the processing container 1 is equipped on the inside with a wear layer 18.

The sand column located within the processing container 1 bears on the friction zone 19 swept by the reaming tools 15. The used sand mainly runs into the friction zone 19 in the central region. The sand particles in the friction zone are exposed to intense frictional forces, which rub off the binder shell adhering to them. The sand particles and the particles of the binder casing migrate outward from the friction zone 19 into the outlet 5 and are transported there by the conveying air blown in at 20 via the riser 6 into the cleaning chamber 7. The pneumatic conveying creates a negative pressure at outlet 5, which leads to a reduction in the pore volume in the friction zone 19. In the cleaning chamber 7, the sand particles are separated by centrifugal and gravitational forces, while the binder particles reach the dedusting system 14 via the suction line 13. The pre-cleaned used sand arrives from the cleaning zone 7 into the buffer tank 8 and after a corresponding dwell time back into the processing tank 1. After several passes, binder-free regenerated sand is finally obtained, which is drawn off into the silo 12 via the conveying line 11.

Claims (18)

1. Method for cleaning used foundry sand, in that the used sand is circulated in a treatment container and frictional forces are applied to the used sand particles which break open the binder shell and release same from the sand grain and the resulting material mixture of sand and binder particles is physically cleaned, whilst concentrating the sand fraction, characterized in that, after passing through the friction zone, part of the material mixture is drawn off from the treatment container into a separate cleaning container and cleaned and the precleaned used sand is returned to the treatment container.
2. Method according to claim 1, characterized in that the material mixture or the precleaned used sand is recirculated several times between the treatment container and the cleaning container.
3. Method according to claim 1 or 2, characterized in that the pore volume in the material mixture is reduced in the vicinity of the friction zone.
4. Method according to one of the claims 1 to 3, characterized in that the material mixture is compacted by mechanical pressure in the vicinity of the friction zone.
5. Method according to one of the claims 1 to 4, characterized in that in connection with the drawing off of the material mixture from the treatment container, air is sucked out of the friction zone.
6. Method according to one of the claims 1 to 5, characterized in that the used sand batch in the treatment container is moved under gravity from top to bottom into the friction zone and in the vicinity thereof the material mixture is drawn off substantially horizontally outwards.
7. Method according to one of the claims 1 to 6, characterized in that, in the vicinity of the friction zone, the material mixture is mechanically outwardly displaced and pneumatically removed at the treatment container periphery.
8. Apparatus for regenerating used foundry sand having a treatment container (1), which has a controllable inlet (2), on its circumference, just above the bottom (4), an outlet (5) and at least one friction tool (15) circulating above the bottom (4), characterized in that, outside the treatment container (1), is provided a cleaning container (7) for separating sand and binder particles and which is located in a feed cycle linking the outlet (5) of the treatment container (1) to its inlet (2).
9. Apparatus according to claim 8, characterized in that a buffer container (8) is positioned between the cleaning container (7) and the treatment container (1).
10. Apparatus according to claim 8 or 9, characterized in that the friction tool (15) circulates directly above the bottom (4) of the treatment container (1) and the outlet (5) is located in the circumferential plane of the friction tool (15).
11. Apparatus according to one of the claims 8 to 10, characterized in that the friction tool (15) has two or more friction arms (16) extending into the vicinity of the circumference of the treatment container (1).
12. Apparatus according to one of the claims 8 to 11, characterized in that above the friction tool (15) is positioned a pressure generating member, e.g. a worm acting on the sand filling.
13. Apparatus according to one of the claims 8 to 12, characterized in that the feed cycle is formed by a pneumatic feed mechanism, which has in the outlet (5) of the treatment container (1) an injector and a feed line (6) leading therefrom into the cleaning container (7).
14. Apparatus according to one of the claims 8 to 13, characterized in that the cleaning container (7) is constructed as a centrifugal separator and has a dust exhaust fan.
15. Apparatus according to one of the claims 8 to 14, characterized in that the treatment container (1) has several circumferentially distributed outlets (5).
16. Apparatus according to one of the claims 9 to 15, characterized in that the buffer container (8) receives 5 to 50, preferably 10 to 20 batch volumes of the treatment container (1).
17. Apparatus according to one of the claims 8 to 16, characterized in that several treatment containers and cleaning containers (7) are connected in series.
18. Apparatus according to one of the claims 9 to 17, characterized in that several treatment containers (1) are connected by means of one or more cleaning containers (7) to a buffer container (8).

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