EP3600676A1 - Device for comminuting and drying waste materials, slags, rocks and similar materials - Google Patents

Abstract

A device (1) for comminuting and drying waste materials, slags, rocks and similar materials (M) is described, which comprises a substantially funnel-shaped tank (2) with a cylindrical attachment (4). On the cylindrical attachment (4) there are arranged at least two air inlets (5) which are distributed over the circumference and which serve for the introduction of compressed and possibly heated air (L). The base of the funnel-shaped tank is equipped with an outlet opening (3) for comminuted material (G). At that end of the tank which is situated opposite the outlet opening (3) and which is of relatively large diameter, an air outlet opening (7) is arranged on the cylindrical attachment (4). A feed device (9) for the material (M) for comminution opens into the cylindrical attachment (4). At the at least two air inlets (5) which are distributed over the circumference of the cylindrical attachment, there is arranged in each case one supersonic nozzle (10) with Venturi function, such that the fed air (L) can be introduced in a circumferential direction of the cylindrical attachment (4) and of the funnel-shaped tank (2).

Description

 Apparatus for shredding and drying of waste materials,

 Slags, rocks and the like materials

The invention relates to a device for comminution and drying of waste materials, slags, rocks and the like materials according to the preamble of patent claim 1.

Waste and the like materials are still often disposed of in landfills. Since landfills have only a limited uptake capacity, it is desirable to comminute the waste before it is deposited. However, the comminution of the waste materials can also be used for treatment for the generation of energy by a subsequent combustion or degassing plant. By crushing waste materials or pulverizing slags and rocks, such as ore stones, valuable raw materials can be separated and recovered more easily. A known problem in the treatment of waste materials such as municipal waste, industrial sludges such as cement, lime industry and sewage sludge is the relatively high moisture content often associated with these wastes. This moisture content, which is usually difficult to separate from the waste materials, is a problem that should not be underestimated in landfills as landfill water. In incineration plants, the high moisture content leads to a lower calorific value of the waste material used. The high moisture content in the waste and the material size generally have a negative impact on the energy and transport balance (C0 ₂ emissions). The known from the prior art grinders or the like for the comminution of waste materials have a relatively poor efficiency and are not sufficiently suitable for a reduction of the moisture content. Also known from the prior art is a milling apparatus which has a substantially funnel-shaped vessel with a cylindrical attachment. Compressed air is injected circumferentially into the cylindrical cap to create an air vortex within the funnel-shaped vessel. This known device requires up to 100 m ^{3 of} compressed air per minute, which is a great disadvantage for the energy balance and for the efficiency of the device. At the entrance openings for the Compressed air mounted baffles divert the air in the circumferential direction of the boiler. The material to be crushed is required via a feed line in the cylindrical attachment and exposed to the air vortex. In the air vortex, the introduced material is to be crushed. The baffles also serve as baffles and are designed to protect the air inlets from swirling material around. The crushed material sinks to the ground due to gravity and is discharged through an opening at the bottom of the funnel-shaped vessel. A cylindrical chimney arranged at the opposite, larger diameter end of the boiler on the cylindrical top ensures removal of excess air. By the preheated air is preheated, a certain drying of the introduced material should be achievable. The baffles are subject to high wear and must be changed relatively often. Since always material bounces against the walls of the funnel-shaped vessel or the cylindrical attachment, these device components are subjected to a relatively high wear and must be designed to be robust. The achievable in the boiler air vortex has only a relatively small speed. As a result, the device has only a relatively small comminution effect on the introduced material.

The object of the present invention is therefore to provide a device for crushing and drying of waste materials, slags, rocks and the like materials, which takes into account the above-described disadvantages of the devices of the prior art. The device should be less prone to wear and allow for sufficient size reduction, even pulverization, and / or drying of the waste used. In this case, the device should be as uncomplicated as possible and have proven and structurally simple components, as well as inexpensive to manufacture and in operation.

The solution of these objects consists in a device for crushing and drying of waste materials, slags, rocks and the like materials, which has the features listed in claim 1. Further developments and advantageous and preferred embodiments of the invention are the subject of the dependent claims. The invention proposes a device for crushing and drying waste materials, slags, rocks and the like materials, which comprises a substantially funnel-shaped vessel with a cylindrical attachment. At least two air inlets distributed over the circumference for introducing compressed and possibly heated air are arranged on the cylindrical attachment. The bottom of the funnel-shaped vessel is equipped with a discharge opening for crushed material. At the outlet opening against overlapping, larger diameter end of the boiler, an air outlet opening is arranged on the cylindrical attachment. A feeder for the material to be crushed opens into the cylindrical attachment. At each of the at least two air inlets distributed over the circumference of the cylindrical attachment, a supersonic nozzle with venturi system is arranged such that the supplied air can be introduced in the circumferential direction of the cylindrical attachment and the funnel-shaped vessel.

Through the use of supersonic nozzles, the supplied, preferably heated, air at the entry into the cylindrical attachment on the funnel-shaped vessel reaches very high flow velocities, which can achieve the scarf and can exceed it several times over. Characterized a heated air vortex is generated in the cylindrical attachment and in particular in the direction of its bottom funnel-shaped narrowing boiler. The high flow rates are achieved by supplying the air under a pressure of about 4 6 bar. Depending on the altitude of the sea, the air volumes can reach about 30 to 50 mVmin. For example, these amounts of air can be generated and promoted by means of a controllable oil-free screw compressor. In this case, a nozzle is understood as meaning, for example, a nozzle which has a cross-sectional profile corresponding to a Laval nozzle. The formation of the supersonic nozzle as a Laval nozzle makes it possible to significantly reduce the required air consumption, for example by up to 50%. This has a great influence on a positive energy balance. Due to the high air velocities, the introduced materials are severely minced, even pulverized. As a result of the pulverization of the materials used, valuable raw materials contained in the materials can easily be returned to the industry. Due to the high degree of comminution, the loading capacity of transport facilities can also be utilized much better, which in turn can have a positive effect on the environment (reduction of C0 ₂ emissions). The materials to be shredded, with the help of a Venturi system, enter the generated air vortex and experience an enormous acceleration. The venturi system serves to "break up" the air vortex created by the supersonic jets.The materials introduced into the air vortex do not withstand the forces that occur during sudden command and are therefore broken down into very small components petalkräfte, shear and friction forces, as well as negative pressure and cavitation support the comminution of the materials contained in the moisture, such as in sewage, - and industrial sludge contained and bound in the solid particles water is thereby separated and with the air in the vortex warming air through the The temperature of the exhaust air can be, for example, up to 100 ° C. The arrangement of at least two supersonic nozzles in the device results in a constant air flow produced, which results in an air vortex, which separates from the Innnnwandun- gene of the device. As a result, impact of the materials on the inner walls of the cylindrical attachment and the funnel-shaped vessel can be prevented.

An embodiment variant of the device according to the invention can provide that the supersonic nozzles with venturi system arranged at the air inlets are arranged on the funnel-shaped vessel at the same axial height of the cylindrical attachment.

As a result, the uniformity of the air vortex can be improved and higher flow velocities can be achieved with the same energy input. In one embodiment variant of the device according to the invention, the supersonic nozzles can have an outlet which has a cross-sectional shape deviating from the circular shape. By selecting the flow cross section at the outlet, the tangential and the vertical components of the air flow can be influenced in the sense of better generation of the air vortex.

An embodiment of the invention may provide that the cross section of the outlet of the supersonic nozzles is rectangular. As a result, the formation of cavitation and negative pressure can be promoted inside the generated air vortex. In a further embodiment variant of the device according to the invention, the supersonic nozzles can each have a narrowest flow cross-section, which can be changed as required. By changing the flow cross section, the flow velocities at the outlet of the supersonic nozzles can be influenced in a targeted manner. The adjusting screws or the like mechanical adjusting means may be arranged so that they are accessible to the user during operation of the device.

The change of at least the narrowest flow cross section of the supersonic nozzles can be done mechanically, for example by means of adjusting screws or the like. An expedient embodiment variant of the invention can provide that the narrowest flow cross section of the supersonic nozzles is automatically adjustable via servo motors. The motor adjustability allows adjustment of the narrowest flow cross-section of the nozzles without, for example, having to open or even disassemble a housing receiving the funnel-shaped vessel and the cylindrical attachment.

In conjunction with a motor adjustability, the narrowest flow cross-section of the supersonic nozzles can be controlled as a function of the material to be comminuted. The control data can thereby, preferably in tabular form, be stored in an external control unit, which is connected to the device. The control data for adjusting the narrowest flow cross-section of the nozzles can be determined and compiled empirically. An advantageous Ausiührungsvariante the invention may allow the user of the device to select the correct control data for the adjustment of the supersonic nozzles depending on the material used. The control unit preferably comprises an electronic data processing system. This can simplify parameter acquisition, control and selection.

A further embodiment variant of the invention can provide that the supersonic nozzles at the air inlets on the cylindrical attachment each open into an air guide plate, which is inserted into a recess in the inner wall of the cylindrical attachment. The Luttführungsplatte delimits the outlet of the supersonic nozzle and is mounted so that they the inner wall of the cylindrical attachment at least in the region of the outlet surmounted above. As a result, the supplied compressed air can be introduced tangentially along the inner circumference of the cylindrical attachment.

In one embodiment of the erfmdungsgemässen the air guide plates can be rotated relative to a nozzle body of the supersonic nozzle by 180 °. As a result, the device is very easy to adapt to different conditions in the northern and the southern hemisphere of the earth. While in the northern hemisphere a cyclonic, i. In the southern hemisphere, an anticyclonic air vortex may be sought in the device rather than a counter-clockwise rotating air vortex. As a result, the efficiency of the device with regard to comminution and drying can be improved. An embodiment of the invention may provide that the Luftführungspl atte is firmly connected to a mounting plate and the nozzle body of the supersonic nozzle is flanged to the mounting plate. The mounting plate is used to mount the supersonic nozzle on the outer wall of the cylindrical attachment. The nozzle body can be flanged to the mounting plate in two positions rotated by 180 °. As a result, the position of the supersonic nozzle and the air inlets with respect to the circumference of the cylindrical attachment can remain unchanged. In an alternative embodiment of the invention, the air guide plate, the mounting plate and the nozzle body but also be rigidly connected to each other. In order to change the direction of rotation of the generated air vortex, the entire supersonic nozzle unit can then be mounted turned by 180 ° together with the mounting plate and the air guide.

A further embodiment variant of the device according to the invention can be connected to a control device which is connected to a global network, for example the Internet, in such a way that the operating parameters of the device can be remote-readably and preferably the device can be controlled remotely. The connection of the control device, which may also include the control unit for the cross-sectional change of the supersonic nozzles, to the Internet can be used, for example, for maintenance purposes, for remote diagnostics and for a remote control of the device.

A still further embodiment variant of the device according to the invention can provide that more than two supersonic nozzles are arranged at the same angular distance from one another on the circumference of the cylindrical attachment. The number of required Sound nozzles can be selected depending on the size and diameter of the funnel-shaped boiler including the cylindrical attachment in order to optimize the flow velocities in the generated air vortex.

Further advantages and embodiments of the invention will become apparent from the following description of exemplary embodiments with reference to the drawings. It shows in not to scale representation:

Fig. 1 is a schematic representation of an inventive device in axial section;

Fig. 2 is an enlarged schematic representation of a device on the

 attached supersonic nozzle;

3 is a perspective view of a supersonic nozzle with a view of a mounting plate on its input side.

4 shows a perspective view of the supersonic nozzle according to FIG. 4, looking onto an air guide plate; and

Fig. 5 is a perspective view of another embodiment of the invention.

A device according to the invention, shown schematically in axial section in FIG. 1, bears the reference numeral I as a whole. The device has a funnel-shaped vessel 2 with an outlet opening 3. At its end facing away from the outlet opening 3, the funnel-shaped vessel 2 has a cylindrical attachment 4. At least two air inlets 5 for compressed and possibly heated air are provided on the cylindrical attachment 4 and distributed over the circumference of the cylindrical attachment 4. A projecting through a cover 6 in the cylindrical cap 4 chimney 7 has a Luftausströmöffnung. The cross section of the Luftausströmöffnung the chimney 7 is variable as needed, which is indicated in Fig. 1 by an adjustable aperture 8 and the arrows PI. A feeder Direction 9 for to be crushed and dried materials M passes through the lid 6 and projects into the cylindrical top 4th

At the at least two air inlets 5 distributed over the circumference of the cylindrical attachment 4, a supersonic nozzle 10 is arranged in each case. Compressed and optionally heated air L is introduced via the supersonic nozzles 10 in the cylindrical attachment 4. Under a supersonic nozzle 10 according to the invention, a nozzle to understand, for example, has a cross-sectional profile corresponding to a Laval nozzle. Through the use of supersonic nozzles 10, the supplied, preferably heated air L at the inlet into the cylindrical attachment 4 and the funnel-shaped vessel 2 reaches very high flow velocities, which can reach the speed of sound and can even exceed that by a multiple. As a result, a heated air vortex W is generated in the cylindrical attachment 4 and in particular in the direction of its outlet opening 3 in a funnel-shaped constricting vessel 2. The high flow rates are achieved by supplying the air L at a pressure of about 4 6 bar. Depending on the level of the sea, the air volumes can be from 30 to 50 m ³ / min. For example, these amounts of air can be generated and promoted by means of a controllable oil-free screw compressor. Depending on the location on the northern or the southern hemisphere of the earth, the direction of rotation of the air vortex W generated in the device 1 is adaptable. While in the northern hemisphere, a cyclonic, ie a counter-clockwise rotating air vortex may prove to be appropriate, in the southern hemisphere rather an anticyclonic air vortex is desirable in the device. For this purpose, the inflow direction of the supersonic nozzles 10 at the air inlets 5 is variable, in particular rotatable by 180 °. This is indicated in Fig. 1 by the curved arrows P2.

The materials M to be comminuted via the feed device 9 into the device 1 are introduced into the generated air vortex with the assistance of a venturi system provided on the supersonic nozzles 10. The Venturi system serves for the short-term "breaking up" of the air vortex W generated by the supersonic nozzles 10. The materials M introduced into the air vortex W are disposed immediately after

Release into the air vortex W very high speeds. The materials M do not withstand the forces occurring during the sudden acceleration and are therefore broken down into smaller components. Within the air vortex W occurring high centrifugal and Zentripetalkräfte, shear and friction forces, as well as negative pressure and cavitation support the comminution of the materials M. In the materials M contained moisture, for example, in sewage, - and industrial sludge contained and bound in the solid particles water is separated and heated with the in the air vortex W Exhaust air A through the fireplace-like air outlet 7, whose outlet cross-section can be adjusted, transported away. The temperature of the exhaust air A can be up to 100 ° C, for example. The arrangement of at least two supersonic nozzles 10 with Venturi function in the device 1, a constant air flow is generated, resulting in an air vortex W, which detaches from the inner walls of the device 1. As a result, impacts of the materials M on the inner walls 41 and 21 of the cylindrical attachment 4 and the funnel-shaped vessel 2 can be prevented. The crushed material passes as granules G along the inner wall 21 of the funnel-shaped vessel 2 to the outlet opening 3 of the device and trickles to the ground. In Fig. 1, this is indicated by an accumulation of granules G on the substrate F.

2 schematically shows an axial section of a supersonic nozzle 10 mounted on the cylindrical attachment 4. The supersonic nozzle 10 has approximately the cross-sectional profile of a Laval nozzle, for example. On the input side, the supersonic nozzle 10 is connected to an air supply line 16. The amounts of air required for the generation of the air vortex can be generated and promoted, for example by means of a controllable oil-free S chraubenkompressors. The supersonic nozzle 10 has a nozzle body 1 1, which are formed for example in several parts. The parts of the nozzle body 1 1 are connected to one another in such a way that they are adjustable relative to one another in order to be able to change at least one narrowest flow cross-section 12 of the supersonic nozzle 10. The adjustment of the parts of the nozzle body 1 1 against each other, for example, via one or more

Set screws. In the schematically illustrated embodiment, a motor adjustability of the narrowest flow cross-section 12 is indicated by means of a servomotor 18. The motor adjustability allows automatic adjustment of the narrowest flow cross-section 12 of the supersonic nozzle 10 without, for example, having to open or even disassemble a funnel-shaped vessel and the cylindrical attachment receiving housing. In conjunction with a motor adjustability, the narrowest flow cross-section 12 of the supersonic nozzle can be controlled as a function of the material to be comminuted. The control data can preferably in tabular form, stored in an external control unit, which communicates with the device. The control data for adjusting the narrowest flow cross-section 12 of the overflow nozzle 10 nozzles can be determined and compiled empirically. An advantageous embodiment of the invention may allow the user of the device to select the correct control data for the adjustment of the supersonic nozzles 10 as a function of the material used. The control unit to asst preferably an electronic data processing system (Fig. 4). This can simplify parameter acquisition, control and selection. The supersonic nozzle 10 has a venturi function. For this purpose, a Venturi bore 13 is arranged at the narrowest flow cross-section 12 of the nozzle body 1 1, which can be opened and closed again when needed. By opening the Venturi bore 13 ambient air is sucked into the supersonic nozzle 10. As a result, the air flow within the supersonic nozzle 10 is disturbed. This effect can be used to selectively "break up" the air vortex created by the inflowing air within the funnel-shaped vessel and the cylindrical attachment, for example, to feed materials into the air vortex.

The nozzle body 11 of the supersonic nozzle 10 opens into an air guide plate 14, which terminates in the mounted state substantially flush with the inner wall 41 of the cylindrical attachment 4. The air guide plate 14 is inserted into the air inlet 5 of the cylindrical attachment such that it projects beyond the inner wall 41 of the cylindrical attachment 4 at least in the area of an air outlet 15 of the supersonic nozzle 10.

As a result, the compressed air can be introduced essentially tangentially along the inner wall 41 of the cylindrical attachment 4. The limited by the air guide plate 14 air outlet 15 has a deviating from the circular cross-section. For example, the air outlet 15 has a substantially rectangular cross-section. The flow cross-section at the outlet deviating from the circular shape can influence the tangential and the vertical components of the air flow in the sense of better generation of the air vortex. This can favor the formation of cavitation and negative pressure in the generated air vortex. For mounting the supersonic nozzle 10 on the cylindrical attachment 4, the nozzle body 11 is connected to a mounting plate 17. The mounting plate 17 is connected to the air guide plate 14 and arranged so that it is in Luftström ungsri direction of the Luftfüh- tion plate 14 surmounted. The mounting plate 17 is fastened by means of screws to an outer wall 42 of the cylindrical attachment 4.

The mounting plate 17 and the associated with this air guide plate 14 may be rigidly connected to the nozzle body 1 1. To change the direction of rotation of the air vortex generated in the device then the entire supersonic nozzle unit including nozzle body 1 1, mounting plate 17 and air guide plate 14 must be rotated by 180 °. However, the mounting plate 17 and the associated with this air guide plate 14 may also, as shown in particular in Fig. 3, relative to the nozzle body 1 1 to be rotatable by 180 °. For this purpose, the nozzle body 1 1 flanged from the mounting plate 17 and be flanged again after turning and mounting the mounting plate 17 and the air guide plate 14 on the cylindrical attachment. Due to the rotatability of the nozzle body 11 relative to the mounting plate 17 and the Luftfüh rungspl atte 14, the position of the supersonic nozzle 10 and the air supply lines with respect to the circumference of the cylindrical attachment 4 remain unchanged. FIG. 3 shows a perspective view of a supersonic nozzle 10 according to the invention with a view of the mounting plate 17. The same components bear the same reference numerals as in FIG. 2. The nozzle body 11 is flanged onto the mounting plate 17. At eingangssei ti gene end of the supersonic nozzle 10, the air supply line 16 is indicated. The mounting plate 17 is surmounted in the air flow direction of the air guide plate 14, which terminates in the mounted state of the supersonic nozzle 10 is substantially flush with the inner wall of the cylindrical attachment.

The mounting plate in turn bears the reference numeral 17. From the figure it can be seen that the air guide plate 14 facing side of the mounting plate 17 is concave curved to follow the curvature of the cylindrical attachment. The air outlet 15 of the supersonic nozzle 10 is arranged on the side facing away from the observer side of the air guide plate 14. He has one of the circular shape deviating cross-section on. Preferably, it is formed substantially rectangular. The nozzle body of the supersonic nozzle 10 is indicated by the reference numeral 11.

FIG. 5 shows a schematic perspective illustration of a further embodiment of a device according to the invention for comminuting and drying waste materials and similar materials, which in turn bears the reference number 1 in its entirety. The same components of the device 1 are with the same reference numerals as in Fig. 1. The device in turn has a funnel-shaped vessel 2 with an outlet opening 3. At its end facing away from the outlet opening 3, the funnel-shaped vessel 2 is connected to the cylindrical attachment 4. Supersonic nozzles 10 for compressed and possibly heated air are mounted on the cylindrical attachment 4 and are preferably distributed at the same angular distance from each other over the circumference of the cylindrical attachment 4. In the illustrated embodiment, in particular four supersonic nozzles 10 are provided, two of which are visible in the figure. The supersonic nozzles 10 are mounted at the same height of the cylindrical attachment 4. By the lid 6, which verschliesst the cylindrical top, protrudes a fireplace-like extension 7, the outlet cross-section can be adjusted. A feeding device 9 for materials to be crushed and dried M passes through the lid 6 and likewise projects into the cylindrical attachment 4.

The supersonic nozzles 10 are connected to an approximately annular air supply line 19, which in turn via another central air line (not shown) may be connected, for example, with an oil-free screw compressor. The air supply lines can be designed according to a temmel arm system. This means that the pressure loss coefficients of the supply lines to the individual supersonic nozzles 10 are the same for all supersonic nozzles, so that a uniform flow is ensured. The pressure losses of the supply lines consist essentially of the pipe friction, i. the internal roughness, the diameter and the length and the Druckverlustbei- values of the tubular elements together. The pressure loss coefficients of the pipe elements can be determined empirically and are usually taken from the literature.

With the aid of the controllable oil-free screw compressor the air can reach the supersonic nozzles 10 under a pressure of approx. 4 - 6 bar and with a volume of 30 to 50 m ³ / min be supplied. The supersonic nozzles 10 allow flow velocities which exceed the speed of sound. As a result, an air vortex is generated within the device 1, which is again provided with the reference symbol W in the partially cutaway view of the device 1 in FIG.

The materials M to be comminuted, which are introduced into the device 1 via the feed device 9, are introduced into the generated air vortex and are accelerated very high immediately after delivery into the air vortex W. The materials M do not withstand the forces occurring during the sudden acceleration and are therefore broken down into smaller components. High centrifugal and centripetal forces, shearing and frictional forces, as well as negative pressure and cavitation occurring within the air vortex W assist the comminution, for example pulverization, of the materials M. Moisture contained in the materials M, for example water contained in sewage sludge and bound in the solid particles thereby separated and transported away with the air warming at W exhaust air A through the chimney-like air outlet 7. The temperature of the exhaust air A can be up to 100 ° C, for example. The air vortex W generated in the device dissolves from the inner walls of the device 1. As a result, bulges of the materials M on the inner walls of the cylindrical attachment 4 or of the funnel-shaped vessel 2 can be prevented. The crushed material passes as granules G to the outlet opening 3 of the device and trickles to the ground.

The apparatus 1 for shredding and drying of waste materials, slags, rocks and the like materials may be connected to a control device, which is indicated by the reference numeral 100. The controller 100 may be connected to a global network such as the Internet such that the operating parameters of the device are remotely readable, and preferably the device is remotely controllable. The connection of the control device 100, which may also include the control unit for a cross-sectional change of the supersonic nozzles 10, to the Internet can be used, for example, for maintenance purposes, for remote diagnostics and for remote control of the device.

The foregoing description of specific embodiments is merely illustrative of the invention and is not to be considered as limiting. Rather, the invention is This is defined by the claims and the equivalents to those skilled in the art and encompassed by the general concept of invention.

Claims

claims

Device for shredding and drying waste materials, slags, rocks and similar materials (M) comprising a substantially funnel-shaped vessel (2) with a cylindrical attachment (4) on which at least two circumferentially distributed air inlets (5) for introduction of compressed and possibly heated air (L), with an outlet opening (3) for comminuted material (G) at the bottom of the funnel-shaped vessel (2) and an air outlet opening located at the diameter of the outlet opening (3). larger end of the boiler (2) on the cylindrical attachment (4) is arranged, and with a feed device (9) for the material to be crushed (M), which opens into the cylindrical attachment (4), characterized in that the at least two over the circumference of the cylindrical attachment (4) distributed air inlets (5) each have a supervisor nozzle (10) is arranged with venturi function such that the zugef Guided air (L) in the circumferential direction of the cylindrical attachment (4) and the funnel-shaped boiler (2) can be introduced.

2. Apparatus according to claim 1, characterized in that at the air inlets (5) arranged supersonic nozzles (10) in the same axial height of the cylindrical attachment (4) on the funnel-shaped vessel (2) are arranged.

3. Apparatus according to claim 1 or 2, characterized in that each supersonic nozzle (10) has an outlet (15) which has a deviating from the circular cross-section.

4. Apparatus according to claim 3, characterized in that the cross section of the outlet (15) of the supersonic nozzle (10) is rectangular.

5. Device according to one of the preceding claims, characterized in that each supersonic nozzle (10) has a narrowest flow cross-section (12), which is variable as needed.

6. Apparatus according to claim 5, characterized in that the narrowest flow cross-section (12) of the IJberschalldüse (10) is adjustable mechanically via screws or the like.

7. The device according to claim 5, characterized in that the narrowest flow cross-section (12) of the IJberschalldüse (10) automatically, preferably via a servomotor, is adjustable.

8. The device according to claim 7, characterized in that the narrowest flow cross-section (12) of the supersonic nozzle (10) controlled in dependence of the material to be crushed (M) is adjustable, wherein the control data, preferably in tabular form, are stored in an external control unit.

9. Apparatus according to claim 8, characterized in that the control data for adjusting the narrowest flow cross-section (12) of the supersonic nozzle (10) are determined and assembled empirically.

10. Apparatus according to claim 8 or 9, characterized in that the control unit comprises an electronic data processing system.

A device according to any one of the preceding claims, characterized in that each supersonic nozzle (10) on the air inlet (5) of the cylindrical cap (4) is delimited by an air guide plate (14) mounted on the air inlet (5).

12. The device according to claim 1 1, characterized in that the air guide plate (14) with a mounting plate (17) is connected.

13. The apparatus according to claim 12, characterized in that the Luftführungs- plate (14) and the mounting plate (13) are rigidly connected to an outlet of an associated nozzle body (1 1) of the supersonic nozzle (10).

14. The apparatus according to claim 12, characterized in that the nozzle body (1 1) of the supersonic nozzle (10) when required relative to the mounting plate rotated by 180 ° can be mounted.

15. Device according to one of the preceding claims, characterized in that it is connected to a control device (100) which is so connected to an international network, such as the Internet, that the operating parameters of the device are remotely readable and preferably the device remotely controllable.

16. Device according to one of the preceding claims, characterized in that three or more supersonic nozzles (10) are arranged at the same angular distance from each other on the circumference of the cylindrical attachment (4).