EP0257446A2 - Process and apparatus for wet-regenerating used foundry sand - Google Patents

Abstract

Used foundry sands, in particular clay-bound used sands, are wet- regenerated by preliminary scouring of the used sand mixed with water, treatment of the used sand/water mixture in several successive attrition stages of a friction washing plant, drawing off and scouring the mixture at each attrition stage, feeding the scoured mixture into the next attrition stage in each case and finally draining and drying the regenerated sand obtained. A device for carrying out the abovementioned process comprises at least two friction washing plants with up to three attrition cells and a grader between each two successive friction washing plants, to which the mixture accruing in the preceding friction washing plant is fed for scouring and from which the scoured mixture is fed to the next friction washing plant.

Description

The invention relates to a method for wet regeneration of foundry sands, in particular clay-bound sands, by pre-desludging the water-mixed old sand, the pre-desludged mixture is fed to a friction washing system in which the binders and contaminants adhering to the old sand grain are separated off by attraction, then the mixture is desludged and the regenerated sand obtained is dewatered and dried. Furthermore, the invention is directed to an apparatus for performing the method.

Up to now, clay-bound (bentonite-bound) old sands have only rarely been reused and mostly deposited in landfills. Since both the costs for new sand and for the separation of the old sand, the transport and storage of which now make up a significant part of the molding costs, many attempts have already been made to regenerate old sand and to feed it back to the foundry instead of new sand. Essentially three methods are known for this. With the pneumatic Regeneration, the old sand is directed against impact surfaces and the individual particles are further guided in countercurrent, so that the undesirable shell on the individual grain is blasted off by impact effects and mutual friction. The same goal is pursued in thermal regeneration, in which the used sand in the fluidized bed is heated to approx. 800 degrees Celsius to remove the combustible components. Pneumatic and thermal regeneration do not lead to satisfactory results, but a combined pneumatic / thermal process can be used to obtain regenerated sand with relatively little contamination. However, this procedure is relatively expensive in terms of equipment and energy. The wear on the grain of sand is also very large, so that the yield of regenerated sand of sufficient quality is relatively low. This procedure could therefore only be put into practice in individual cases.

The third known method is wet regeneration, in which the old sand mixed with water is set in motion, the cleaning effect being achieved exclusively by the abrasive frictional forces between the moving sand particles. For example, the sand / water mixture is agitated by a stirrer (e.g. US Pat. No. 2,783,511). In order to improve the yield, part of the regenerated and desludged sand is returned to the stirrer, in order to take advantage of the greater abrasive effect of the processed sand compared to the used sand. Due to the high proportion of returned sand (up to 85%), the performance of such regeneration is relatively poor. Otherwise, like all known methods of wet regeneration, it has the disadvantage of a large water requirement and the accumulation of large amounts of waste water. A better yield can be obtained with such wet regeneration processes (DE magazine "Giesserei" 1972, pages 593 to 615 and "Giesserei-Praxis" 1984, pages 206 to 211), in which the used sand is first desludged in a classifier, then in a multicellular one Attritions machine treated and then desludged again. With this method, however, the efficiency of the regeneration remains unsatisfactory, so that this method has hardly proven itself in practice.

The invention has for its object to provide a method for wet regeneration of old sand, in which a greater yield of regenerated sand, with a quality equivalent to that of new sand, is obtained and the costs of the water balance can be reduced.

On the basis of the process mentioned at the outset, this object is achieved in that the used sand / water mixture is treated in several, spatially separate, one after the other, the switched attraction stages, the mixture of each attraction stage is removed and desludged and the desludged mixture is fed to the next attraction stage.

Practical tests have shown that the yield of regenerated sand leads to a high degree of purification with a multistage process and intervening slurry. The reason for this can be seen in the fact that, in the case of a single-stage and multicellular attraction machine, the separated impurities hinder the friction effect between the sand particles, which are harder than the impurities, so that no or no noticeably positive effects can be achieved by extending the attraction time. The impurities obviously act as lubricants and therefore reduce the effectiveness of the rubbing. Because of the de-sludging which is switched on according to the invention between each attraction stage, the impurities separated off in each stage are removed from the mixture, so that they do not impair the friction wash in the subsequent stage. The regenerated sand obtained with the process according to the invention can be fed to the sand cycle of the foundry as a substitute for new sand.

In a further embodiment of the method according to the invention, it can be provided that the regrind sand which is obtained after desludging after the last attraction stage is washed, then dewatered and dried. With the final washing process, a regenerated sand with a particularly high degree of regeneration is obtained.

In order to keep the costs of the water balance as low as possible, according to one embodiment of the invention, the sludge obtained at each desludging step and the sludge that may arise when washing the regenerated sand is clarified and the clarified water is returned to the old sand in the cycle.

With this water recovery, part of the clarified water can optionally be used to wash the regenerated sand. However, the fresh water to be supplied to the water circuit to compensate for the lost water is preferably used for washing the regenerated sand.

Due to the above-mentioned exemplary embodiments, the majority of the water is circulated. Essentially, only the water losses occurring during desludging and the evaporation losses when drying the regenerated sand need to be supplemented by fresh water.

The sludge that accumulates during classification, washing and clarification can - like the old sand - be deposited in landfills. However, since this sludge often contains organic compounds that result from the various binders and additives of the molding and core sand, it may be advisable to subject the sludge to a thermal cleaning process in order to separate or burn the organic constituents. The dust-like residue then obtained can be landfilled without further notice.

To carry out the method according to the invention, the invention is based on a known device (DE- Magazine "Giesserei" 1972, page 596), which consists of a classifier pre-desludging the old sand / water mixture, at least one rubbing washer with several attraction cells, one of these downstream classifiers and a dryer which absorbs the desludged and, if necessary, washed regenerated sand. According to the invention, such a device is characterized in that at least two friction washers, each with a maximum of three attraction cells, are connected in series and a classifier for desludging the mixture is arranged between successive friction washers. Practical investigations have shown that a friction washing system with a maximum of three attraction cells leads to optimal results in each individual stage and that a larger number of attraction cells does not bring any additional effects. The classifiers can be designed as trough classifiers or upflow classifiers (hydrose parators), optionally also in combination with one another.

The friction washer system preferably consists of two attraction cells, and preferably two or more such washer systems are connected in series.

Spiral classifiers have proven to be particularly favorable for achieving an effective desludging and for setting an optimal solids content, which ensures an efficient friction effect.

In an advantageous further development of the device, the classifier arranged behind the last friction washing system is followed by a scrubber for the regenerated sand, from which the processed sand then reaches the dryer in order to be subsequently fed to the sand cycle. The scrubber can be a washing centrifuge, which also performs the dewatering.

In a further advantageous embodiment of the device according to the invention, this is behind the last rubbing wash System arranged classifier or the scrubber for the regenerated sand downstream of a clarification device, the water drain is connected to the used sand feed before the first classifier and possibly the scrubber for the regenerated sand. The fresh water compensating for the water losses is expediently added to the scrubber.

The sludge obtained in the classifiers, the washer and the clarifier can be fed to a rotary kiln after drying, where it can be thermally cleaned at temperatures between 800 and 1500 degrees Celsius and the residue deposited.

The method according to the invention is described below with reference to an embodiment of an overall system.

In the drawing, I schematically indicates a sand preparation in which the old sand is crushed in a conventional manner and cleaned of metal parts by means of magnetic separators. The old sand pretreated in this way is temporarily stored in a silo 1, from which it reaches a mixing container 3 by means of a metering screw 2. The old sand is mixed with water in the mixing container 3, suctioned off by means of a pump 4 and fed to a first spiral classifier 6 via a line 5.

The pre-desludged used sand arrives in a first two-cell attrition machine 7. In the embodiment shown, these, as well as all subsequent attraction machines, each have three sets, each with six paddles, which set the used sand / water mixture in an intensive stirring motion, so that binders and others Residues can be rubbed off from the grain of sand. From this first two-cell attraction machine, the mixture is again fed to a spiral classifier 8, water still being supplied in small quantities and the thin sludge excreted in the spiral classifier, while the wet old sand in the second attraction machine 9 is forwarded to repeat the scrubbing process. The resulting fine fraction is removed in the third spiral classifier 10 as thin sludge. After this desludging, the regenerated sand passes through an intermediate container 11, in which water may optionally be added, and from there by means of a pump 12 into a washing centrifuge 13. Here, water is again supplied in order to wash out the regenerated sand.

The regenerated sand leaves the washing centrifuge and arrives on a conveyor belt 14 which transports the regenerated sand into a dryer, e.g. B. promotes an oscillating dryer 15. The regenerated sand leaves the oscillating dryer 15 via a sieve 15 a and is pneumatically transported, for example in a line 16, to the new sand bunker.

The thin sludge obtained at the spiral classifiers 6, 8, 10 passes via the line 17 into a thin sludge collector 18, into which the waste water from the washing centrifuge 13 is also fed. In this thin sludge collector 18, the dust accumulating in the oscillating dryer 15 and deposited by wet dedusting in the dust extractor 15 b can also be introduced.

From the collector 18, the thin sludge is pump 19 into a clarifier 20, for. B. transferred a lamella clarifier, the sludge discharge is connected to a decanter 21, 22. This is where the dewatered sludge accumulates, which is brought to landfill 22 a. This sludge can optionally also be dried beforehand and burned out in a rotary tube furnace, not shown, in order to separate off any organic constituents which may still be present and, if appropriate, to afterburn. The residue from the rotary kiln is then deposited in landfill 22 a after cooling. The clarified water obtained at the lamella clarifier 20 and at the decanting device 21, 22 is pumped via line 25 returned to the regeneration system with the addition of fresh water via line 26.

Claims (13)

1. Process for the wet regeneration of foundry sands, in particular clay-bound sands, by pre-desludging the water-mixed old sand, the pre-desludged mixture is fed to a friction washer in which the binders and contaminants adhering to the old sand grain are separated off by attrition, then the mixture is desludged and the Regenerate sand obtained is dewatered and dried, characterized in that the old sand / water mixture is treated in several spatially separate, successively connected attraction stages, the mixture is drawn off and desludged from each attraction stage and the desludged mixture is fed to the next attraction stage. 2. The method according to claim 1, characterized in that the regrind sand obtained during desludging behind the last attraction stage is washed, then dewatered and dried. 3. The method according to claim 1 or 2, characterized in that the sludge obtained at each desludging stage and, if appropriate, during washing of the regenerated sand, and the clarified water is returned to the cleaning process in the circuit. 4. The method according to any one of claims 1 to 3, characterized in that part of the clarified water is used for washing the regenerated sand. 5. The method according to any one of claims 1 to 4, characterized in that the lost water of the cleaning process is supplemented by supplying fresh water into the water cycle and the fresh water is used for washing the regenerated sand. 6. The method according to any one of claims 1 to 5, characterized in that the sludge obtained during wet regeneration and, if appropriate, the sludge obtained during clarification is subjected to a thermal cleaning process. 7. The method according to claim 6, characterized in that the sludge is dried, then heated to 800 to 1500 degrees Celsius, then cooled and then deposited. 8. Device for performing the method according to one of claims 1 to 8, consisting of a pre-desludging the old sand / water mixture classifier, at least one friction washing system with several attraction cells, one of these downstream classifiers and a desludged and optionally washed regenerated sand dryer , characterized in that at least two friction washers (7, 9), each with a maximum of three attraction cells, are spatially separated in series and between each other the following friction washers a classifier (8) is arranged for desludging the mixture. 9. The device according to claim 8, characterized in that each friction washing system (7, 9) has two attraction cells. 10. The device according to claim 8 or 9, characterized in that the classifiers (6, 8, 10) are designed as spiral classifiers. 11. Device according to one of claims 8 to 10, characterized in that the classifier (10) arranged behind the last friction washing system (9) is followed by a scrubber (13) for the regenerated sand. 12. The device according to one of claims 8 to 11, characterized in that a clarifier (20 to 23) is arranged downstream of the classifier (10) or the scrubber (13) for the regenerated sand, which is arranged behind the last friction washing system (9), whose water outlet (25) is connected to the used sand feed (3, 4) upstream of the first classifier (5) and, if appropriate, the scrubber (13) for the regenerated sand. Device according to one of claims 8 to 12, characterized in that the classifiers (6, 8, 10), the washer (13) and optionally the clarifying device (20 to 23) have a dryer which takes up the sludge, this a furnace, in particular a rotary tube furnace , and this is followed by a cooler.

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