EP0265422A1 - Process and device for mechanically removing the surface of lumped goods. - Google Patents

Abstract

PCT No. PCT/DE85/00553 Sec. 371 Date Feb. 19, 1988 Sec. 102(e) Date Feb. 19, 1988 PCT Filed Dec. 21, 1985 PCT Pub. No. WO87/03826 PCT Pub. Date Jul. 2, 1987.A process and an apparatus for mechanically removing a sulphur containing layer from lumped lime, wherein the lumped lime is accelerated from a bottom member by a mechanical impulse and projected from the bottom member against a processing surface having profiles provided over partial sections thereof to remove the sulphur containing layer, when the lumped lime returns to the bottom member and the process is repeated along a conveying path for the lumped lime for a determined length of time, or for as long as it takes to achieve the desired removal of the sulphur containing layer.

Description

 Method and device for the mechanical removal of surfaces of lumpy goods

The invention relates to a method and a device for the mechanical removal of surfaces of lumpy goods.

The surface of lumpy goods must be treated mechanically in the most varied fields of technology. In part, it is a matter of completely or partially removing a shell or skin. This skin or shell can be of the same material quality as the "core" of the respective piece, but it can also be the other way around, to remove the surface made of a different material.

The peeling of fruit or the cleaning of potatoes may be mentioned in this context as an example.

Spare sheet Likewise, the term "removal of surfaces of lumpy goods" also includes the removal of surfaces which as such do not form an independent component, but for example have a different chemical or mineral composition compared to the rest of the material (the core). The surface of lump lime made with sulfur-containing fuels is mentioned as an example of this field of application.

For the production of lime, high amounts of energy are necessary for the management of the pyro process. In principle, a wide variety of energy sources, such as coal, coke and / or natural gas or oil, come into question. In addition to its high calorific value, natural gas is characterized in particular by the fact that it is almost sulfur-free. Fuels such as coke or lignite products (lignite dust), on the other hand, have a considerable sulfur content, which means that lime products from lignite firing, for example, are two to three times higher in sulfur than those from natural gas firing.

Further tests have shown that the sulfur load of the calcined lime product is extremely high, especially in the surface area, and decreases significantly with increasing layer depth.

Lump limes with an S0 ₃ content of less than 0.1% by weight, often less than 0.05% by weight, are required for use in the steelworks sector. Such concentrations cannot be achieved with solid (sulfur-containing) fuels without an appropriate (mechanical) aftertreatment. A reduction in the sulfur content of the fuel is technically possible, but too expensive. Because of the concentration gradient across the grain cross section described above, it is generally sufficient to remove only a relatively thin surface layer. The biggest problem, however, is that the lump of lime is not in spherical or other symmetrical form, especially with a smooth surface, but in a wide variety of configurations, so that certain (especially past) surface areas are difficult to access.

A (unpublished) proposal has become known for achieving "mechanical desulfurization" by treating the material in a drum screen which may be provided with internally acting abrasive components. However, such a device has considerable disadvantages. On the one hand, an autogenous grinding is caused to a large extent, which leads to an undesirable generation of fractured surfaces (the steel industry demands lime in a certain grain spectrum).

Furthermore, considerable amounts of solids have to be removed in order, for example, to free the grain zones, which cannot be reached directly through indentations or dents, slits or sack pores due to the increased adjacent areas, from the surface zones of increased sulfur content. In the case of particularly irregular goods, as is actually the rule in lime production, this can mean that up to 50% by weight or more must be removed.

On the other hand, the use of the sulfur-containing fuels mentioned should be made possible, inter alia for cost reasons. Another (likewise unpublished) proposal provides for mechanical processing of the grain surfaces by means of sandblasting. In the case of a mass product such as lime, in addition of a relatively small piece size (steelworks lime is usually in the size range between 10 and 60 mm), such a method cannot be implemented, and the uniform surface treatment is also difficult.

The invention is based on the object of demonstrating a possibility of mechanically treating lumpy goods in such a way that a largely uniform removal of material is achieved over the entire surface. Thus, regardless of the shape of the piece and, in particular, its geometrical surface design, a layer of the same thickness as possible should be removed over the surface, or in other words: a way should be shown, with as little material loss as possible, a uniform material removal over the entire surface Seen surface of the piece to reach. The invention is also intended to offer the possibility of being used in the industrial field.

In particular, an application should also be easily and safely made possible in the case of bulk goods.

In addition, the demand is made to present a proposed solution which, based on the same principle, enables adaptation to the product to be treated in each case and is therefore adaptable to the particular application.

The focus is on the surface treatment of lumpy lime. The invention is based on the knowledge that - regardless of the design of the surface - uniform removal can be achieved in that the piece goods to be treated in each case with a certain kinetic energy along an adjustable transport route and / or over a certain time interval between a floor and one of these treatment surfaces assigned at a distance is flung back and forth.

The invention accordingly proposes a method for the mechanical removal of surfaces of lumpy goods, in which the lumpy good, starting from a floor, is thrown against a treatment surface, from there returns to the floor, and the process along a transport path for the lumpy good and / or is repeated over a certain time interval until the desired surface removal has been achieved, the material being accelerated by a mechanical pulse.

Accordingly, a device is proposed which has at least one floor for receiving the good and a treatment area assigned to it at a distance and a device for exerting a mechanical impulse on the good to be treated.

This device can be provided in various ways. In a first simple embodiment, a pulsating, movable plunger is guided against the floor in a certain cycle, which thus exerts an impulse on the material carried over it. An advantageous embodiment of the invention provides for a forced agitator to be arranged on the floor and / or the treatment surface. However, the device can also be arranged in such a way that it

Spare bill speaking intermediate organs acts on them.

Another embodiment of the invention provides for the floor and the treatment surface to be connected to one another via rigid connecting elements, so that a kind of treatment space is created and the forced agitator is attached to one of the connecting elements. The forced agitator can be a vibrator, preferably an electric vibrator.

In a particularly advantageous embodiment, the invention provides that the forced agitator is formed by an unbalance device which is seated on a rotatably driven shaft. A circular or involute movement path for the floor, the treatment area and the material to be treated can be achieved in this way. At regular or irregular intervals (depending on, for example, the design of the unbalance disk, the speed of the drive unit and the design of the floor and treatment area), an impulse is exerted on the piece goods lying on the floor, which then accelerates towards the ^" treatment area ^" and hits it before it falls back onto the floor surface, usually at a different angle.

The material is preferably guided against a treatment surface provided with profilings at least over partial sections. The surface design of the treatment area plays an important role in relation to the quality and quantity of the surface removal. Although a closed flat surface is fundamentally conceivable for certain areas of application, certain geometric designs are proposed in preferred embodiment variants. The profiles can have, for example, a cone, pin, ball, hemisphere, quarter ball, wave, saw tooth or pyramid shape. The corresponding surface can, however, also be designed like a brush, for example. The invention further provides for forming individual sections of the treatment area with different profiles. Such an arrangement should be chosen depending on the goods to be treated.

The "surface tools", especially the projecting sections, mean that - as soon as the goods are thrown against them - not only do protruding edges and corners break off or smooth surfaces are rubbed or brushed off, but in particular recessed surface parts can also be removed if for example, a pyramid-like protrusion comes into the region of a depression on the surface.

Optimization in the sense of a uniform surface removal is achieved in particular if the piece to be treated is guided from the floor against the treatment surface along the transport path and / or during a certain time interval in as different directions as possible and there, if necessary, to different surfaces. sections of the treatment area.

In a particularly preferred embodiment of the invention, this aim can be achieved in that the material is guided over a deformable floor and / or against a deformable treatment surface, the deformability preferably being carried out by an elastic material of the floor and / or the treatment area is reached.

Ersa The piece goods are then not only flung back and forth between the floor and the treatment surface due to their irregular surface and / or inclination of the treatment line consisting of the floor and the treatment surface, but this effect is further reinforced by the elastic surfaces, the respective geometrical alignment of which is further influenced by the forced agitator. Similar to a trampoline, the parts are then caught and flung away, reinforced by the additional impulse from the forced agitator. Counter-vibrations are set up with variable frequency distribution. The process is preferably selected so that the acceleration of the goods when the treatment area is reached is a multiple of the acceleration due to gravity, preferably three to six times.

An optimization of the surface removal can be achieved in that the floor is also designed with profiling in an analogous manner to the treatment area and thus also acts as an "active area".

In the sense of a uniform and effective surface removal with as little material loss as possible, it has proven to be advantageous to drive "in co-flow". The direction of movement of the goods is the same as the direction of the applied impulse. This creates a kind of role effect.

With regard to the arrangement of the floor and treatment surface, it is proposed in an advantageous embodiment of the invention to increase the distance between the two depending on the size of the piece goods being carried out choose, a distance of less than twice the largest general cargo diameter has proven to be particularly advantageous. Within this range, a distance that is 20 to 40% larger than the largest diameter is preferred. The effect of the corresponding treatment surfaces is then particularly high. With an adjustable pulse frequency and amplitude, a large number of touch contacts can be achieved over relatively short treatment distances and / or time intervals, as a result of which a corresponding surface layer is not only removed more quickly, but also - as described in detail above - more uniformly.

The invention thus proposes a completely new type of mechanical surface removal, and in particular a completely new kinetics of the material to be treated. In this way, together with special geometrical designs of the treatment surface (s), surface areas can also be removed which previously were not accessible using known methods, in particular recessed surface parts. In addition, the forced agitators described require only relatively little electrical energy when generating strong mechanical impulses and high efficiency. Furthermore, for example, by changing the configuration of the floor and / or treatment area, the pulse strength and direction, the distance and the alignment of the floor and treatment area, their inclination, movement to one another and / or material properties, changes in the sense of a different one are easily made Good stress possible, whereby one and the same device can be adapted to the most varied piece goods to be treated.

A further optimization of the method according to the invention or the device according to the invention allows

Spare sheet to optimize the distance between the floor and the treatment area in particular, taking into account the given measure, by dividing the material flow into different grain fractions and feeding them to their own device, according to an advantageous embodiment of the invention the corresponding plant is designed in such a way that a separation according to different grain sizes is carried out by sieving, and the material flow with the finer material that falls downwards is fed to a device that is below, but essentially parallel to, a common feed area is arranged first device for the coarser fractions. The system is particularly compact. A forced agitator can act on both devices or their parts together, for example, in that the treatment lines are connected to one another, for example via a fixed mechanical linkage, and are seated on a common spring bearing.

The individual device or the complete system is preferably encapsulated in a dust-tight and sound-absorbing manner and, as a further advantageous embodiment of the invention provides, is kept dust-free by connecting a suction device.

The device according to the invention, optionally in combination with other devices, is particularly suitable for the mechanical desulfurization of lump lime (steelwork lime), since, among other things, the advantages according to the invention are particularly clear due to the irregular surface properties of lime lime. The The mode of operation of the method according to the invention can be additionally improved for such an application by spraying a moisture mist (water mist) onto the material in the application area for the material, a superficial hydration occurring which makes the material somewhat softer and therefore less abrasion-free. Of course, this advantage applies to the processing of all hydratable substances.

It has been found that the energy with which the

Particles bounce against the treatment surface (s), which is decisive for the surface removal. It has been shown that large grains experience greater surface removal than small grains with the same throughput time. The invention therefore proposes, in an advantageous embodiment, to subdivide the material stream to be treated into partial streams of different grain fractions, as has already been explained above, but also to send different treatment lines, for example with the inclination, according to the desired surface removal, so that - regardless of the grain size - an approximately equally thick layer is always removed.

Due to the completely new treatment, the mechanically desulfurized material also differs in its external habit from the material sent through a drum screen. Accordingly, the invention also comprises a lumpy good, in particular lump lime, which is produced using the method according to the invention and / or in the device according to the invention. Such a product has a particularly uniform surface.

The mechanical desulfurization according to the invention is not only particularly effective, but the process and the device is also particularly easy to handle and enables quick and effective processing of the goods.

This applies not only to the above-mentioned lump of lime, but also to the other areas of application mentioned at the beginning.

Further features of the invention emerge from the remaining claims and the further description documents.

The invention is described below with reference to an exemplary embodiment. This shows a system for the mechanical surface treatment of lump lime for use in the steelworks area, where only lime qualities with a particularly low sulfur content can be used. The system accordingly serves for the mechanical desulfurization of the lime in the surface area.

The drawing shows schematically in

Figure la: A longitudinal section through a plant according to the invention for the mechanical surface treatment of lime.

Figure lb: An enlarged view of the task area of the system according to Figure la.

Figure 2: A cross section through the system of Figure 1.

Figure 3: An enlarged sectional view of the treatment area of the system according to Figures 1, 2 seen against the transport direction.

Figure 4: An enlarged sectional view of the treatment area perpendicular to the direction of transport.

Figure 5: A top view of the floor of a treatment line of the system according to Figure la.

Figure 6: A flow chart to illustrate the individual process steps in the treatment of lump lime according to a preferred embodiment. The plant according to FIGS. 1 to 5 ^" consists of two treatment lines 10, 12 arranged at a distance from one another. Each of the treatment lines has a base 14 or 16. A so-called treatment surface 18, 20 is arranged above and parallel to each base.

The floors 14, 16 and the treatment surfaces 18, 20 have the shape of elongated rectangles when viewed from above and are rigidly connected to one another and to one another at their opposite longitudinal edges by side walls 22, 24.

Each floor 14, 16 consists of a circumferential metal frame 26, the longitudinal sides of which are connected to one another at a distance from one another via transverse struts 26a. On the metal frame 26 and the ^'cross braces 26a, a blanket is stretched be¬ 28 and solidifies, (not shown), for example, via a tensioning device in the frame area or suitable Schraubver¬ compounds. The blanket shows over its surface in the longitudinal direction and perpendicular to it at a distance from each other closed strips 28a, which include rectangular areas 28b. The areas 28b are provided with a plurality of through openings 28c.

The rubber blanket can, for example, consist of a hard rubber material.

The treatment surfaces 18, 20 each consist of a metal sheet, preferably a steel sheet. The steel sheet has a plurality of openings 30 arranged side by side and one behind the other, which are arranged in the direction the associated base 14 or 16, expressed and opened only in the sports direction of the material to be treated (arrow direction A), are designed. The openings 30 are therefore not produced by simply punching them out, but by pressing them out, similar to a grater. The passage openings 30 are preferably small and arranged at a close distance from one another. FIGS. 3 and 4 show a front view or a side view of the treatment surfaces 18, 20, wherein, in particular, FIG. 4 shows a sawtooth shape of the individual expressed sections 32 in longitudinal section, which are open in the direction of transport (arrow A).

In the exemplary embodiment shown, the treatment areas 18, 20 are designed over their entire area in the manner described. However, it is also possible in the sense of the invention to design only partial areas in this way, while other areas are either unprofiled or have projections and recesses of other configurations, for example a cuboid shape, pyramid shape, hemisphere or quarter ball shape. Likewise, the surface of the treatment surface 18, 20 facing the respective floor 14 or 16 can also be designed with pins projecting downwards, similar to a brush. It is also particularly advantageous if the projections and recesses have a different overall height (depth), that is to say project more or less downwards in the direction of the associated floor 14, 16.

Shoulders 34a, b projecting vertically on the ends are welded to the side walls 22, 24, which are parallel and at a distance

^• stand to an associated foundation 36a, b. A pair of compression springs 38a, b is arranged between each shoulder 34a, b and the associated foundation 36a, b, the associated compression springs resting against the shoulder 34a, b or the foundation 36a, b under tension. To mechanically support the shoulders 34a, b, associated angles 40a, b are welded to the side walls 22, 24.

As can be seen in particular from FIG. 2, the distance between the floor 16 and the associated treatment area 20 is somewhat smaller than the distance between the floor 14 and the treatment area 18. The corresponding distances are dependent on the item to be treated, as explained above has been.

The distance between the treatment surface 20 of the treatment line 12 and the floor 14 of the treatment line 10 arranged above it is a multiple of the last-mentioned distance between the components 14, 18.

The floors 14,16 can in the same manner as the Behand¬ lung surfaces 18,20 be designed, in particular profiles can also on the trays 14, ^'16 is provided to wer¬.

FIG. 1 a shows that the treatment lines 10, 12 or the associated components are provided with a slope, specifically from a feed area 44 to a removal area 46. The loading area 44 has a device 48 which essentially has the shape of a shaft and is shown in an enlarged (schematic) representation in FIG. 1b.

At its upper end, the device has a receiving funnel 50, to which two slide sections 52, 54, which run at an angle to one another with a slope toward the floor 14, are connected, which pass over steps 56, 58 into lower slide sections 60, 62. Starting from steps 56 and 58, the slide sections 60, 62 run with a shape that widens trapezoidally when viewed from above. Correspondingly, vertically extending lamellae 64 are arranged on the slide sections 60, 62, the distance from one another of which is smaller in the area of the step 58 than at the opposite end. The bottom of the slide sections 60, 62 is designed as a sieve bottom 66. The front end of the sieve plate 66 in the direction of transport A merges into the initial area of the plate 14 and is arranged somewhat above it.

Below the sieve bottom 66, the device 48 continues with a free-fall section 68 which, as shown in FIG. 1b, is also divided into vertically extending chambers 72 with vertical slats 70.

The bottom of the free-fall section 68 is again designed as a sieve plate 74, with a smaller mesh size than the sieve plate 66. The front edge of the sieve plate 74 in the transport direction A is arranged somewhat above the plate 16, which adjoins the sieve plate 74 directly A funnel-shaped discharge 76 is arranged below the sieve bottom 74.

Below the treatment line 12, two further collecting funnels 78, 80 are arranged one behind the other in the transport direction A, which are directed together with the discharge 76 onto a common (not shown) conveyor belt.

The upper side of the handling line 10 is closed off with two cover plates 82, 84 arranged in a vault-like manner in the transport direction A, each of which has a suction device 86 on the upper side.

At the removal area 46, two downwardly angled channels 88, 90 adjoin the treatment lines 10 and 12, respectively, which are directed towards a conveyor belt (not shown).

Approximately in the middle of the treatment lines 10, 12 (seen in the transport direction A), a shaft 92 projects through the side walls 22, 24 in which it is rotatably mounted. On the outside there is an imbalance disk with variable mass on the shaft ends. Each imbalance disk 94 is rigidly connected to the shaft 92. On the free end assigned to the side wall 24 there is a pulley 96 on the shaft 92 which serves to receive a belt (not shown) which is guided at a distance from the pulley 96 around a further pulley which is seated on a motor shaft . The belt drive thus serves to rotate the shaft 92.

Instead of the described unbalance drive, an eccentric drive can also be provided, for example. As well the invention provides the possibility of placing a vibration device directly on one or both side walls 22, 24 and / or the floors 14, 16 or treatment surfaces 18, 20.

FIG. 6 shows an example of a flow diagram for the mechanical treatment of quicklime with a plant according to the invention.

In the introduction, it was pointed out that the mechanical treatment of steelwork lime is about achieving a product with the lowest possible sulfur content. The plant according to the invention is used for this purpose, with the aid of which the surface area of the lump lime, which is particularly loaded with a high sulfur concentration, is to be removed.

As FIG. 6 shows, the material flow first passes through a sieve, on which the grain fraction larger than 50 mm is separated. It has been found that the proportion of the sulfur-laden surface to the total volume of these pieces is relatively small, so that when considered as a mass, the sulfur content is within the permissible range, so that this material is shown in the figure Embodiment does not need to be desulfurized mechanically.

The remaining material flow (less than 50 mm) passes through the desulfurization plant according to the invention.

For this purpose, the material reaches the chutes 52, 54 via the receiving funnel 50 and divides into two equally large streams. Due to the slope of the slide sections

tt (Schurren) 52.54 the material slides further down. It arrives at the slide sections 60, 62, where each material flow is further divided into five partial flows by the lamellae 64. Due to the geometrical arrangement of the lamellae 64, the partial flows are guided such that they are evenly distributed over the entire width of the system at the transition to the floor 14.

A sieving also takes place along the paths 60, 62, the material reaching less than 30 mm down through the sieve bottom 66 and the free-fall path 68 to the sieve bottom 74, where further sieving takes place and only the material smaller than 10 mm is let through becomes. The latter is fed to a screen via the discharge 76 without mechanical surface treatment, which will be described in more detail below.

The two grain fractions 30 to 50 mm and 10 to 30 mm then reach the associated bottoms 14 and 16 from the screen surfaces 66, 74 either due to their inclination and / or due to connected vibration devices. With mechanical connection to the side walls 22, 24 said device 48 can be set in motion by the unbalance drive 92, 94.

As soon as the individual piece of lime has reached the bottom 14 or 16, the mechanical surface removal begins.

Due to the circumferential unbalance 94 (here at a speed of 750 rpm), a short-wave oscillating movement is transmitted via the rigid side walls 22, 24, the height of the corresponding oscillation amplitude being determined, among other things, by the design and arrangement. unbalance mass 94 is adjustable. In the exemplary embodiment shown, an oscillation amplitude of 20 mm is selected. The forces transmitted by the mass 94 are absorbed by the compression spring pairs 38a, b. The device as a whole is moved on an approximately circular movement path, with a movement direction as indicated by the arrow B.

It has proven to be particularly advantageous to operate the system "in co-flow", that is to say to allow the unbalanced mass 94 to rotate in the direction of transport of the goods (arrow direction A).

It is readily apparent that the material lying loosely on the floor 14 or 16 is initially carried lying down on the respective floor 14 or 16 during a first upward movement of the unbalanced mass 94.

Subsequently (during the downward movement (return) of the unbalanced mass 94), the device parts themselves are guided downwards again due to the rigid connection to one another. However, the pieces previously lying on the shelves 14, 16 experienced such an acceleration during the upward movement that they were detached from the associated shelf 14 or 16 and flung against the corresponding treatment surface 18, 20 from where they hit the shelf 14 or 16 bounce back. Depending on the mass of the individual parts, their surface design, their impact and rebound angle with respect to the treatment surface 18 or 20 and the vibration amplitude set on the drive side, each piece of lime becomes flung back and forth in rapid succession between floors 14 and 16 and associated treatment areas 18 and 20, respectively. It is important here that, based on the parameters specified, the individual piece of lime is moved back and forth each time with a slightly different orientation between the floor and the treatment surface, so that always different surface sections come into contact with the abrasion elements. This effect is reinforced by the selection of an elastic floor 14 or 16. It is readily understandable that the elastic base undergoes deformation as a whole during the oscillating movement of the device, so that the distance between the base and the associated treatment surface is additionally dependent on the respective deformation of the elastic oscillating base 14 or 16. As a result, however, the individual pieces of lime meet again at differently inclined surfaces, which means that they are returned at a new angle.

Due to the constant spinning of the solid particles against the treatment surface 18 or 20, but also when they hit the corresponding floor 14 or 16, surface abrasion takes place, so that the high-sulfur-containing outer skin is gradually removed. The scraped-off fine material can be discharged downward through the openings in the bottom 14 or 16. The fine material from the treatment line 10 will first fall through the space between the treatment lines 10, 12 and then be fed to the collecting funnels 78, 80 via the openings in the treatment surface 20 and the openings of the associated base 16. Due to the inclination of the device as a whole or, in particular, the floors 14, 16, but also reinforced by the direction of rotation of the unbalance drive, the individual pieces of material between the floor 14, 16 and the associated treatment surface 18, 20 are "prancing" from the task area 44 leads to the removal area 46, the high pulse rate resulting in a large number of surface contacts between material and treatment surface 18, 20 or bottom 14, 16.

The choice of the length of the system or the set pulse rate as well as the other aforementioned parameters are set depending on the piece goods to be treated in each case. Likewise, in individual cases, the geometric design of the tools on the underside of the treatment surfaces 18, 20 or - as an alternative embodiment provides - also be set on the corresponding floors 14, 16. In the exemplary embodiment, the treatment surfaces 18, 20 have the same design over the entire conveying path, in a manner similar to a grater with projections which are pressed downwards and open in the direction of arrow A. The material abrasion thus takes place by an entrainment of the individual grain over the expressed surface section, whereby a "softer" material abrasion is achieved than if the individual parts were thrown against the openings 30 of the expressed sections 32, as is done by reversing the direction of rotation of the Unbalance mass 94 would be possible.

It has been shown that with a treatment such as in

Exemplary embodiment shown, a very smooth surface of the individual pieces of lime is reached, which indicates a particularly gentle treatment.

In particular, the surface areas of troughs on the surface of a piece of lime are rubbed in almost the same way and at the same depth, since, due to the material guide according to the invention, abrasion knobs, such as the expressed sections 32, can also get into such troughs.

The rubbed-off fine material is drawn off via the collecting funnels 78.80 and fed to the same sieve into which the fine stream drawn off from the feed area also reaches.

The mechanically desulphurized coarse grain (grain fraction 10 to 50 mm) passes through the channels 88, 90 from the plant, for example, into a silo (not shown). A partial flow of the grain fraction 10 to 50 mm also flows into this, which is drawn off at the end of a roll crusher system into which the initially branched oversize (larger than 50 mm) is fed.

The fine material (less than 10 mm) that is drawn off from the desulfurization system, together with the fine material that is obtained at the end of the roller crusher, reaches a screening system, where it is divided into further grain fractions, for example 3 to 10 mm and less than 3mm, in order to be bunkered or filled elsewhere.

An example illustrates the mode of operation of a system according to the invention, as shown in the drawing.

A quicklime is included as the starting material a SOg content of 0.13 percent by weight in the grain fraction 10 to 50 mm is available. The material was then fed into the system in accordance with the drawing and passed through it in cocurrent. Approx. 15 percent by weight of material was removed along the treatment section, that is, 15 percent by weight of the quantity flow was withdrawn via the removal devices 76.78.80. The remaining 85 percent by weight in the grain size range from 10 to 50 mm then had an S0 “content of only 0.05 Percent by weight, which corresponds to a reduction of about 60 percent. A drastic reduction in the S0 ,, content could thus be achieved with very low material losses.

Numerous further developments and alternatives are possible within the scope of the invention. Instead of guiding the material flow along a treatment section, as explained above with reference to the exemplary embodiment, the material can also be placed on a defined (horizontal) surface and hurled against a treatment surface arranged above it, among other things via the setting of a specific time interval and the applied pulse the intensity of the surface abrasion 'can be controlled. If a particularly gentle surface removal is desired, it can be sufficient to design the treatment area without profiling or only roughened or to push the sheet outwards (away from the floor), so that only "negligible" discontinuities are formed in the treatment area for the material guided against it become.

Spare roast

Claims

 Method and device for the mechanical removal of surfaces of lumpy goods

P a t e n t a n s r u c h e

1. A method for the mechanical removal of surfaces of lumpy goods, characterized in that the lumpy good, starting from a floor (14,16) against a treatment surface, accelerated by a mechanical impulse, is thrown from there onto the floor (14,16) returned and the process along a transport route for the lumpy good and / or a certain time interval is repeated until the desired surface removal is achieved. 2. The method according to claim 1, characterized in that the material is thrown against an at least over sections with profiles (32) provided treatment surface (18, 20).

Method according to Claim 1 or 2, characterized in that the material lying on the transport base (14, 16) is acted upon by mechanical pulses applied in close succession and the pulses are preferably applied via a base (14, 16) and / or the treatment surface (18, 20) vibrating, impacting or vibrating device acting on the goods.

Method according to one of claims 1 to 3, so that the acceleration of the material applied by an impulse is so great that when the treatment area (18, 20) is reached it is a multiple of the acceleration due to gravity.

5. The method of claim 4, d a d u r c h g e k e n n z e i c h n e t that the good acceleration is 3 to 6 times the Erd¬ acceleration, preferably 4 to 5 times.

Method according to one of claims 1 to 5, characterized in that the goods along the transport path and / or during a certain time interval during its movements between the floor (14, 16) and the treatment surface (18, 20) with different angles against the floor (14, 16) or the treatment area (18, 20) is guided.

Replacement 7. The method according to claim 6, characterized in that the material is guided over a deformable, preferably elastic bottom (14, 16) against a deformable, preferably elastic treatment surface (18, 20).

8. The method according to any one of claims 1 to 7, d a d u r c h g e k e n n z e i c h n e t that the good is moved along a slope.

Method according to one of Claims 1 to 8, that the material is guided in a rotating manner between the floor (14, 16) and the treatment surface (18, 20).

10. The method according to any one of claims 1 to 9, so that the starting material is divided into streams of different particle size fractions and these are treated separately from one another.

11. The method according to any one of claims 1 to 10 for the treatment of lump lime.

12. The method according to claim 11, so that the starting material is brought into contact with a substance which reacts with the surface before being introduced into the space between the floor (14, 16) and the treatment surface (18, 20).

13. Device for the mechanical surface treatment of lumpy goods with at least one transport floor (14, 16) for the goods and a treatment surface (18, 20) assigned to them at a distance, and a device for exerting a mechanical impulse on the goods to be treated . 14. The apparatus according to claim 13, characterized in that the device for exerting the mechanical pulse on the material to be treated on the floor (14, 16) and / or the associated treatment surface (18, 20) and / or on the floor (14 , 16) is arranged with the associated treatment surface (18, 20) connecting elements (22, 24) or acts on them via corresponding intermediate members.

15. The apparatus according to claim 13 or 14, characterized in that the bottom (14,16) and / or the treatment surface (18,20) directly or indirectly, preferably on springs or silent blocks, resiliently mounted and by a forced agitator (92,94) is (are) movable.

16. The apparatus of claim 15, d a d u r c h g e k e n n z e i c h n e t that the forced agitator is a vibrator, preferably an electric vibrator.

17. The apparatus of claim 15, so that the positive agitator (92, 94) is formed by an unbalance device (94) which is fixed in place on a shaft (92) rotatably driven by a motor.

18. Device according to one of claims 13 to 17, that the floor (14, 16) and / or the treatment surface (18, 20) is (are) movable on a circular or involute path of movement.

19. Device according to one of claims 13 to 18, d a d u r c h g e k e n n z e i c h n e t,

Replacement bill that the bottom (14, 16) and the treatment surface (18, 20) can be moved asynchronously to one another.

20. Device according to one of claims 13 to 19, 5 d a d u r c h g e k e n e z e i c h n e t that the floor (14, 16) and / or the treatment surface (18, 20) is (are) adjustable in its (their) angle of inclination to the horizontal.

10 21. Device according to one of claims 13 to 20, characterized in that the bottom (14, 16) and / or the treatment surface (18, 20) are formed with profiles (32) at least over partial sections of their corresponding surfaces .

22. The apparatus according to claim 21, characterized in that the profiles consist of spherical, hemispherical, quarter-0 spherical, cubic, wave, sawtooth and / or pyramid-shaped projections and recesses and / or have a brush shape .

23. The device according to claim 21 or 22, 5 and that the treatment area (18, 20) is divided into zones of different profiles.

24 ". Device according to one of Claims 13 to 23, 0 d a d u r c h g e k e n n z e i c h n e t, that the distance between the bottom (14, 16) and the associated treatment area (18, 20) is smaller than double and larger than the largest diameter of the piece goods. 5

25. Device according to one of claims 13 to 24, characterized in that the base (14, 16) and / or the treatment surface (18, 20) is (are) designed to be deformable, preferably elastic.

26. The apparatus of claim 25, so that the floor (14, 16) and / or the treatment surface (18, 20) consists of a rubber blanket (28), preferably a hard rubber blanket.

27. Device according to one of claims 13 to 26, that a device (48) for distributing the goods over the entire width of the base (14, 16) is formed at the end of the feed side.

28. Device according to one of claims 13 to 27, d a d u r c h g e k e n e z e i c h n e t that at least one collecting device (78.80) is provided below the bottom (14.16).

29. Device to 28, gekennzeichnetdu according to any one of claims 13 ^'rch a sound- and dustproof enclosure (82,84) and at least one suction device connected thereto (86).

30. Plant with at least two devices according to one of claims 13 to 29 for the mechanical surface treatment of lumpy goods of different grain fractions.

31. The system as claimed in claim 30, so that a sieving device (66, 76) is provided on the feed side for separating the material flows.

Replacement sheet 32. Lump of lime, preferably from a fuel unit operated with sulfur-containing fuels, which has been treated with the method according to one of claims 1 to 12 and / or a device or system according to one of claims 13 to 31.

CHANGED REQUIREMENTS

[Received at the International Bureau on December 8, 1986 (December 8, 1986); original claim 25 deleted; Claims 1 and 13 amended; 26 to 32 through new demands

25 to 31 replaced; remaining claims unchanged (6 pages)]

1. Method for the mechanical treatment of lumpy goods, the goods being flung back and forth between two surfaces, characterized in that the goods are acted upon by such a mechanical impulse along the transport route and / or during a specific time interval. that, with the greatest possible avoidance of fractured surfaces, a pure surface abrasion takes place to the desired thickness.

7. The method as claimed in claim 6, so that the material is guided over a deformable, preferably elastic base (14, 16) against a deformable, preferably elastic treatment surface (18, 20).

8. The method according to any one of claims 1 to 7, d a d u r c h g e k e n n z e i c h n e t that the good is moved along a slope.

9. The method according to any one of claims 1 to 8, that the material is guided in a rotating manner between the floor (14, 16) and the treatment surface (18, 20).

10. The method according to any one of claims 1 to 9, so that the starting material is divided into streams of different particle size fractions and these are treated separately from one another.

11. The method according to any one of claims 1 to 10 for the treatment of lump lime.

12. The method according to claim 11, characterized in that the starting material is brought into contact with a substance which reacts with the surface before being introduced into the space between the floor (14, 16) and the treatment surface (18, 20). 13. Device for the mechanical treatment of lumpy goods with at least one transport floor (14, 16) for the goods and a treatment surface (18, 20) assigned to them at a distance and a device for exerting a mechanical impulse on the goods to be treated, characterized in that the bottom (14, 16) and / or the treatment surface (18, 20) is (are) deformable, preferably elastic.

14. The apparatus according to claim 13, characterized in that the device for exerting the mechanical pulse on the material to be treated on the floor (14, 16) and / or the associated treatment surface (18, 20) and / or on the floor (14 , 16) is arranged with the associated treatment surface (18, 20) connecting elements (22, 24) or acts on them via corresponding intermediate members.

15. The apparatus according to claim 13 or 14, characterized in that the bottom (14,16) and / or the treatment surface (18,20) directly or indirectly, preferably on springs or silent blocks, resiliently mounted and by a forced agitator (92,94) is (are) movable.

16. The apparatus of claim 15, d a d u r c h g e k e n n z e i c h n e t that the forced agitator is a vibrator, preferably an electric vibrator.

17. The apparatus according to claim 15, characterized in that the forced agitator (92,94) is formed by an Unwuchtin¬ direction (94) which is fixedly seated on a shaft (92) rotatably driven by a motor 3826 PCT / DE85 / 00553

18. Device according to one of claims 13 to 17, so that the floor (14, 16) and / or the treatment surface (18, 20) is (are) movable on a circular or involute path of movement.

19. Device according to one of claims 13 to 18, that the floor (14, 16) and the treatment surface (18, 20) can be moved asynchronously to one another.

20. The device according to one of claims 13 to 19, so that the floor (14, 16) and / or the treatment surface (18, 20) can be adjusted in its (their) angle of inclination to the horizontal.

21. Device according to one of claims 13 to 20, so that the floor (14, 16) and / or the treatment area (18, 20) are formed with profilings (32) at least over partial sections of their corresponding surfaces.

22. The apparatus of claim 21, d "characterized by that the profiles consist of spherical, hemisphere, quarter-spherical, cubic, wave, sawtooth and / or pyramid-shaped projections and recesses and / or have a brush shape .

23. The device according to claim 21 or 22, characterized in that the treatment surface (18, 20) is divided into zones differing profiling. 24. The device according to any one of claims 13 to 23, characterized in that the distance between the bottom (14, 16) and the associated treatment area (18, 20) is less than twice and larger than the largest diameter of the piece goods being fed.

25. Device according to one of claims 13 to 24, so that the floor (14, 16) and / or the treatment surface (18, 20) consists of a rubber blanket (28), preferably a hard rubber blanket.

26. Device according to one of claims 13 to 25, that a device (48) for distributing the goods over the entire width of the bottom (14, 16) is formed at the end on the feed side.

27. Device according to one of claims 13 to 26, so that at least one collecting device (78, 80) is provided underneath the bottom (14, 16).

28. Device according to one of claims 13 to 27, a soundproof and dustproof encapsulation (82, 84) and at least one suction device (86) connected to it.

29. Plant with at least two devices according to one of claims 13 to 28 for mechanical surface treatment of lumpy goods of different grain fractions. 30. Plant according to claim 29, characterized in that a screening device (66, 76) on the feed side

Separation of the material flows is provided.

31. Lump of lime, preferably from a combustion unit operated with sulfur-containing fuels, which has been treated with the method according to one of claims 1 to 12 and / or a device or system according to one of claims 13 to 30.