DE3938566C2 - Method and device for separating cleaning bodies from a cooling water stream - Google Patents

Description

The invention relates to a method for separating Cleaning bodies from a flow of cooling water downstream a tubular heat exchanger, which is from the cleaning body is flowed through in the circuit, in which the cleaning body caught on a sieve by means of a lifting device direction lifted off the sieve and one with a room down rigere pressure connected outlet opening be, the screen and lifting device motor relative to each other be moved. The invention also relates to a Device for performing the method, consisting of a substantially circular cylindrical pipeline cut as a housing with at least one arranged therein Sieve and at least one outlet opening for removing the deposited cleaning body in the housing wall attached and connected to a space of lower pressure is, and with at least one lifting device that with the The outlet opening is connected, whereby the sieve and lifting device device are arranged movable relative to each other.

With the mentioned method and the device used for it Separation and recovery processes for cleaning Bodies from the cooling water flow are not just cleaning body caught on the seven, but also Verun cleaning in the form of coarse materials of various types and dimensions. Therefore, the sieves have to be replaced from time to time can be cleaned of these coarse materials.  

A device for performing the method is for Example from DE 85 26 836 U1 known. In this device, the lifting device is whose job is to keep the ones on the sieve Lift the cleaning body off the sieve as a suction device executed. The part of the suction device that the Has water inlet opening, and the strainer are relative arranged movably to each other. The takeoff of the Reini The body from the sieve is made by sucking off cooling water into the water inlet opening of the suction device, the one Part of the screen covered and at a certain distance is arranged above the screen surface. The distance of the Water inlet opening to the screen surface determines whether there is a flow reversal in the suction area comes through the sieve or, at a greater distance, rather to a lateral inflow of the cooling water tangential to the sieve surface in the water inlet opening. The flow reversal is necessary to include the above Lift contaminants off the screen surface and then off suck in while for lifting and suction the moving usually no spherical cleaning body complete flow reversal is required, and already the more tangential inflow is sufficient.

This separation effect for cleaning bodies and ver dirt, i.e. the sole suction of cleaning products pern, is thereby begun in the known device that in the immediate vicinity of the water inlet opening by shading the cooling water flow a dead water area or a vortex area is formed, which reduces the contact pressure on the cleaning body. This allows the cleaning body in the dead water area be kept in motion and with the suction arm moved a certain entrainment effect for the cleaning body on while the pollution is on the seven remains. For cleaning the pollution from the Seven is either the distance between water ingress  to reduce the opening and the screen surface or to reduce the screen Swivel flow reversal. It is also an operating possible, where the suction arm rotates without suction and collects the bullets by the deadweight, while the pollution remains on the sieves, and too at another time the suction arm is switched on Suctioning the pollution by reversing the flow from the sieve takes off. This serves to separate dirt and cleaning more physical and also by the on-off operation of the suction Reduction of the suction device and further over the total discharge amount of waste water discharged, during the discharged waste water volume flow, i.e. the waste amount of water per unit of time does not decrease.

The known device has the fundamental disadvantage that the waste water to be discharged through the outlet opening volume flow is very large, which is correspondingly great effort for the piping and the provision of the pump energy requires. This applies even if Reini alone body should be lifted from the sieve, and completely especially when lifting off the coarse dirt partial flow reversal from the sieve is required. To generate the partial flow reversal on the sieve in the The area of the water inlet opening must be suctioned off there a sufficiently high negative pressure can be generated. As a result this negative pressure, however, considerable water flows amount unintentionally into the side of the suction device at least such a large gap to the screen surface must indicate that the cleaning body can pass through light becomes. These additional amounts of water must be taken into account additional energy are dissipated.

All in the known device for reducing the measures called feedwater flow have other disadvantages:  

A side seal is only possible through chamber formation possible. The chambers then take up when the suction is rotating directions the shape of circular segments and thus very large screen areas for which a flow reversal again requires a large flow of waste water.

Used to reduce the extracted cooling water flow also an embodiment of the known device that only at a predetermined point of the swept suction area has a water inlet opening, wherein in remaining area an area to form a dead water zone and a deflector to gather the Rei Cleaning body is arranged. The one not described in detail The deflector can, if at all, only move easily body towards the water inlet opening drive, but do not lift any dirt off the sieve.

This remains in the known device for lifting the Contamination from the sieve is only a reverse flushing of the sieves by drawing off a considerable flow of water or a pivoting of the screen surface itself for the purpose of return rinsing.

It is therefore an object of the invention, a method and a Device for performing the method of the beginning to improve the type described so that a lift off Cleaning bodies and contaminating coarse substances from the Seven and their discharge through the outlet openings with one low wastewater flow can be achieved, and thus the dimensions of the discharging components, pipes, Pumps etc as well as the pump capacity can be reduced.

To achieve this object, the invention proposes a Ver drive in front of one with the lifting device Flow guide elements generated, essentially parallel to the screen surface arranged roller-shaped vortex the cleaning body from Sieve lifts, rotates around the vortex core and over  one by suction in at least one part of the vertebra generated axial flow component of the suction opening and the outlet opening connected to it that the Whirl with the relative movement of the Lifting device moves over the sieve and that the vortex extends into the sieve openings and thus besides the Cleaning bodies also remove all coarse material from the sieve takes off.

The vortex according to the invention is guided by flow elements from the energy of the cooling water flow itself generated, does not require cooling water extraction. Since he is Extending into the sieve openings, he lifts next to the Rei also remove all dirt from the sieve both rotate around the vortex core. Will be at one point of the A small water flow is sucked off, so about an axial flow component is superimposed on the vortex, the cleaning body and coarse material on the suction opening moved there. Thus, a take off and removal, so ins a separation of cleaning bodies and the sieves polluting coarse materials with an extremely low ab flow of water possible.

During the rotation of the cleaning body and coarse material around get the vortex core on its way to the suction opening this due to the turbulence of the vortex according to statistical Laws very often in the immediate vicinity of the screen surface, where local flow components pass them through the screen openings want to pull. Coarse substances of elongated shape and one Cross section smaller than the sieve openings (e.g. grass and other fibers, sticks, smaller conch shells) to a large extent pass through the sieve openings, while coarse materials with overall larger dimensions and Cleaning bodies are carried forward by the vertebra. By this effect becomes a big part of the dirt problem loosely discharged through the sieves.  

The axial transport of cleaning bodies and coarse substances in the vortex can be improved by the fact that the Sieve surface and the parallel roller-shaped Vortex not arranged orthogonal to the direction of flow but at an angle of attack. With that comes to mind vectorial portion of the flow forces in the longitudinal vertebrae direction and moves the whirling roller and with it cleaning body and coarse material on the downstream Ab suction opening. The screen area does not have to be under all same angle of attack to the flow direction of the cooling water flow can be arranged. In many cases it is enough if this only happens in certain areas.

For the separation of cleaning bodies and soiling Coarse materials it is advantageous if before the start of cleaning circulating body, i.e. before feeding the cleaning body, sieve and lifting device with activated Ab water flow, i.e. moved against each other with suction be, and thus the sieve a cleaning of adherent Experiences pollution.

Procedurally, the sieve against the fixed Ab lifting device to be moved or vice versa. However, it is advantageous to firmly arrange the larger component sieve and to move the lifting device.

With regard to the device, the invention proposes that the lifting device from at least one elongated Vortex space consists essentially of one in Strö direction arranged limiting element, a so connected vortices arranged transversely to the direction of flow element and from the screen surface is formed, the Vortex element towards the sieve a cleaning body passage gap leaves open, and that at least one A suction opening is arranged at the location of the vortex chamber, which is connected to the outlet opening.  

It is advantageous to use only one lifting device Form vortex space, then the limiting element almost up to the sieve surface to prevent the To prevent vortex. The direction of movement relative to Sieve is through the arrangement of the cleaning body leave gap specified.

However, the invention also includes an arrangement of two vertebral spaces in parallel with one another seed limiting element that is not up to the sieve surface must suffice. This arrangement makes it possible to take off Direction and sieve against each other in both directions move.

Limiting element and vortex element can be used in many ways Way to be designed and arranged. Advantageous is the limiting element and also the vortex element form as flat plates and the vortex element for Formation of the vortex space obliquely against the flow put.

From a fluidic point of view, it is advantageous to use the limiting element ment by extension to the upstream side of the lifting device direction as a flow divider and there with one to provide a larger cross section. This makes a special broad swirl space for cleaning bodies and coarse materials created of large dimensions without the flow too very disturbing. Disruptions to the flow are transformed into one Area moved away from the vortex generator.

The operational safety is to use the limiting element in Elastic design close to the sieve to avoid seldom occurring To be able to master problems with jammed coarse parts. These would then deform the limiting element just run over and in one of the next rounds from Vertebra captured.  

With smaller dimensions of the device according to the invention is a suction opening at one of the two ends of the we sufficient space. With longer lengths of the vertebral space there will be a suction opening at both ends of the vortex provide for. It can also be advantageous e.g. B. more than two suction openings across the axis of the vertebrae order and summarize them in a manifold, which forms a unit with the lifting device. In In this case it is already to avoid a high current tion resistance expedient, the suction openings on the side of the vertebral space opposite the sieve to arrange.

The design of the device according to the invention is of the sieve and the type of movement between sieve and lift-off basically any device. With rectangular ge designed sieve would one or more lifting devices linearly over the screen area to the entire To capture area. It is particularly advantageous to use the sieve to be rotationally symmetrical and the lifting device to design as a radial arm that around the longitudinal axis of the Siebes is rotatably mounted. It can also be more than one Arm are used, e.g. B. for reasons of balance.

The arm rotates around the longitudinal axis of the rotationally symmetrical Siebes, so it is particularly advantageous, a suction opening - possibly several - at the central end of the vertebral space to be provided, which opens into a central tube that with the outlet opening is connected. It is useful to rotate the pipe with the lifting device. The However, the tube can also be fixed and the lifting device serve as storage. In the latter case, the Ab would also be suction opening fixed and designed as a circular area, whose central axis lies in the longitudinal axis of the sieve.

It is advantageous to close the sieve as a cone or spherical cap design, the screen preferably in flow direction  tung bulges. In special installation conditions, it can happen be partaking of the sieve against the flow direction of the Domed cooling water flow, however, from strength establish larger wall thicknesses of the sieve requires. Depending on Dome is a suction opening at the downstream end of the vertebral space.

The sieve must be made of perforated sheet. However, there is also a Construction from sieve bars possible as a concentric circle rings or are to be arranged parallel to each other. these are only a few preferred of the many possible designs to form.

The device according to the invention can be motorized drive, e.g. B. with a mounted in the sieve axis Hydraulic motor or via an external rotation shaft, where necessary the rotation vector of the lift device and that of the outside of the housing horizontal rotary drive with reversing gear, a flexible one Shaft, a cardan shaft or with many other things known drive elements are to be arranged differently.

This is preferably necessary for the rotation of the lifting device torque from the flow energy of the cooling water flow itself. This happens through Water flow inclined surfaces or through a appropriate profiling of the lifting device.

In the event of a malfunction, it can be advantageous in individual cases at least parts of the sieve pivotable to this to be able to open for the cooling water flow. You can also do that Design the device so that the ge in the center of the sieve stored lifting device together with the sieve a total forms together with swiveling unit, whereby then the connection must be made movable to the outlet opening.  

The advantages achieved by the method according to the invention and the device according to the invention are in any case therein to see that the cleaning body caught by the sieve and contaminating coarse material safely from the screen surface lifted off and with a very small amount of wastewater and ge from the cooling water flow to be divorced.

In the following the invention with reference to drawings he clarifies that only represent exemplary embodiments. It show in a schematic representation:

Fig. 1 shows an axial section through an inventive device for separating cleaning bodies from a cooling water flow with a conical sieve with a lifting device rotatable about the longitudinal axis.

Fig. 2 shows the section AA through the object of FIG. 1 on an enlarged scale.

Fig. 3 shows a cross section through the article of FIG. 1.

Fig. 4 shows the section BB through the object of FIG. 3 on an enlarged scale.

Figs. 5 to 10 sections similar by the lifting device in a layer-section AA in FIG. 1.

Fig. 11 shows the section through the outlet water chamber of a tubular heat exchanger in a section with built-in device according to the invention, also shown in section.

The embodiment shown in FIG. 1 of a device according to the invention for separating cleaning bodies from a cooling water flow is arranged, for example, downstream of a tube heat exchanger or a turbine condenser, the cooling pipes of which are flowed through by the cooling water. The cleaning bodies are fed upstream of the heat exchanger to the cooling water flow, pass through the cooling tubes for the purpose of cleaning them and are separated from the cooling water flow by the device according to the invention in order to be returned to the heat exchanger inlet by means of a pump or to be kept in a cleaning body collector outside the cleaning periods.

Within a circular cylindrical Rohrleitungsab section 1 , which is flowed through by the cooling water flow in the direction of a drawn arrow 2 , there is a sieve 3 , which is conically shaped from perforated sheet metal and is curved in the direction of the cooling water. A lifting device 4 is rotatably mounted with a central tube 5 in the longitudinal axis of the sieve 3 and the pipe section 1 . The two bearings 6 are in the center of the sieve 3 and in a connec tion pipe 7 to the outlet opening 8 attached. To drive the lifting device 4 by the cooling water flow carries the same surfaces 9 , which are inclined to the direction 2 of the cooling water flow mes.

The real thing. Housing 10 of the device according to the invention is shortened in this embodiment. The conical sieve 3 is attached to the outlet flange 11 of the Ge housing 10 and protrudes into the subsequent pipeline device 12 . A very short overall length is achieved, which is a great advantage in many cases. However, it is also part of the invention that the device according to the invention protrudes into subsequent components, such as. B. strain compensators or water chambers. It is self-evident that the housing can also extend over the entire length of the device according to the invention and the sieve is then clamped with an intermediate flange or fastened with a clamping ring fastened in the housing.

Fig. 2 shows on an enlarged scale the angedeu ended in Fig. 1 section AA through the lifting device. 4 This consists of an elongated vortex chamber 13 , which is formed from a limiting element 14 , a vortex element 15 and the sieve surface 16 . The limiting element 14 extends almost to the screen surface 16 , while the vortex element 15 to the screen surface 16 leaves a cleaning body through the gap 17 open. The limiting element 14 is extended to the upstream side of the lifting device 4 and out as a flow divider 18 with a thickened cross section 19 .

The drawn current threads 20 show how a roller-shaped vortex 21 is formed by a flow of cooling water into the vortex chamber 13 , which reaches through the sieve openings 22 and both cleaning body 23 and also coarse dirt 24 lifts off the sieve 3 and rotates around the we belkern .

Fig. 3 shows the cross section of the embodiment of FIG. 1. You can see the circular cylindrical pipe section 1 with the sieve arranged therein. 3 In the center of the sieve 3 , the lifting device 4 is rotatably mounted, which in this embodiment is designed as a radially arranged arm 25 . The vortex element 15 can also be seen. The connecting tube 7 , which opens into the outlet opening 8 , is connected to the central tube 5 , around which the lifting device 4 rotates. On the screen 3 cleaning body 23 are deposited.

In FIG. 4, on a larger scale the section B-B through the article of Figure is shown. 3,. You can see the sieve 3 , which carries the bearing 6 , in which the central tube 5 of the lifting device 4 is rotatably mounted. The sieve 3 has openings 22 .

Furthermore, with the help of a current thread 20 , it can be seen how water passes through the suction opening 26 , which opens into the central tube 5 . Due to the suction of water through the suction opening 26 is formed for the eddy 21 is an axial flow component in the direction of the voltage Absaugöff 26 represented by the helical formation of the current thread 20th With the slow axial movement of the vortex 21, cleaning bodies 23 and Grobver dirt 24 migrate in the vortex chamber 13 to the suction opening 26 . This effect is strengthened by the oblique arrangement of the screen surface 16 to the direction 2 of the cooling water flow.

In Fig. 5 of the swirl chamber 27, an existing likewise from a flat sheet swirl element 28 and the screen surface 16 formed by a 13 formed as a flat plate-limiting element. Between the swirl element 28 and the screen surface 16 , the cleaning body passage gap 17 remains open. The screen 3 is shown un perforated for simplification of the drawing. Limiting element 27 and swirl element 28 are connected to one another, for example, by a weld seam 29 .

In Fig. 6, the delimiting element is designed as a flat sheet 30 , and the swirl element is designed as a sheet 31 bent in a circular arc. Both together again form the swirl space 13 together with the sieve surface 16 . Limiting element 30 and We belelement 31 are connected to each other for example by welding.

Fig. 7 shows a section through an embodiment of the lifting device 4 , the two adjacent We belraume 32 and 33 has a common separating element 34 and formed as angled plates vortex elements 35 and 36th Two roll-shaped vortices 37 and 38 are formed which rotate in the opposite direction, identified by current threads 39 .

Fig. 8 shows an embodiment of the lifting device in section, in which the limiting element 40 is formed by Ver extension to the upstream side as a flow divider 41 . Otherwise, the lifting device is designed as in FIG. 5.

In Fig. 9, 42, the limiting element in the region of the flow divider 43 to a thickened cross-cut 44.

In FIG. 10, the limiting element 60 has an elastic part 61 near the screen. The swirl element 62 is partially designed as a tube 63 shown in cross section, in which one or more suction openings 64 are provided. The tube 63 could, for example, open into the central tube 5 in FIG. 4, which is not shown in FIG. 10.

Fig. 11 shows in the cutout section of the tubing of the outlet and the water chamber of a tubular heat exchanger with built therein according to the invention device. The cut is limited by the break lines 45 . One can see the heat exchanger or condenser tubes 46 , which are carried by the tube plate 47 and are generally rolled there. Cleaning body 23 pass through the condenser toro tubes 46 , get into the outlet water chamber 48 of the condenser or heat exchanger (the arrows 49 show the direction of flow of the cooling water) and are collected by the sieve 50 . The spherical dome-shaped in this embodiment and shown unperforated, but in reality perforated sieve 50 is fastened to the support ring 51 on the outlet nozzle 52 of the outlet water chamber 48 be. The support ring 51 also supports the bearing 53 in which the lifting device 54 is mounted with the central tube 55 . In the center of the screen 50 , a pot 56 is attached, which is also designed as a bearing for the central tube 55 of the lifting device 54 . A connecting pipe 57 ver binds the pot 56 to the outlet opening 8 , through the cleaning body 23 and the Grobver not shown use leave the device according to the invention. The lifting device 54 is driven, for example, via an articulated shaft 58 , which is mounted in the drive connection 59 and is there, for example, connected to a gear motor (not shown).

In this embodiment, the subject matter of the invention for separating cleaning bodies 23 into the outlet nozzle 52 of the outlet water chamber 48 is built in such a space-saving manner that it protrudes only insignificantly beyond the outlet flange 60 of the outlet nozzle and so subsequent components such as, for. B. Butterfly valves are not affected.

With the overall design of the device for separating cleaning bodies from a cooling water it becomes downstream of a tubular heat exchanger made possible according to the task, with very little Waste water volume flow cleaning bodies and impurities to be lifted off the sieves and removed safely. A additional advantage of the device according to the invention is the short overall length.

Claims (30)

1. A method for separating cleaning bodies from a cooling water flow downstream of a tubular heat exchanger, through which the cleaning bodies flow in a circuit, in which the cleaning bodies are caught on a sieve, are lifted off the sieve by means of a lifting device and are supplied to an outlet opening connected to a lower pressure space , wherein the sieve and lifting device are moved by motor relative to each other, characterized in that at least one generated by the lifting device with flow guide elements, arranged substantially parallel to the sieve surface Neter cylindrical vortex, the cleaning body from the sieve, it rotates around the vortex core and through a Suction at least one point of the vortex, he produced axial flow component of the suction opening and the outlet opening connected to it that the vortex with the relative movement of the Abhebevorrich device on the Si eb moves and that the vortex extends into the sieve openings and thus, apart from the cleaning bodies, all coarse material also lifts off the sieve. 2. The method according to claim 1, characterized records that coarse materials with a larger overall measurements as the screen openings from the vortex to the suction opening can be transported.   3. The method according to claim 1, characterized records that coarse materials with an elongated shape and a cross section smaller than the sieve openings the vortex preferably leave through the sieve openings. 4. The method according to claim 1 or 2, characterized records that the screen surface and the roller-shaped Vertebrae at least in some areas at an angle of inclination are aligned with the flow direction orthogonal and by the vectorial part of the flow forces in An additional flow compo in the direction of the vortex axis nente in the direction of the downstream part of the vortex arranged suction opening arises. 5. The method according to any one of claims 1 to 4, characterized ge indicates that before cleaning begins body circulation by relative movement of lifting device and sieve and suction a cleaning of the sieve from coarse fabrics. 6. The method according to any one of claims 1 to 5, characterized characterized in that the lifting device is moved relative to the sieve. 7. Apparatus for carrying out the method according to claim 1, consisting of an essentially circular cylindrical pipe section as a housing with at least one sieve arranged therein and at least one outlet opening for removing the separated cleaning bodies, which are attached to the housing wall and have a low space Pressure is connected, and with at least one lifting device which is connected to the outlet opening, the sieve and lifting device being arranged to be movable relative to one another, characterized in that the lifting device ( 4 ) consists of at least one elongated swirl space ( 13 , 32 , 33 ), which essentially consists of a limiting element ( 14 , 27 , 30 , 34 , 40 , 42 , 60 ) arranged in the direction of flow, an associated vortex element ( 15 , 28 , 31 , 35 , 36 , 62 ) arranged transversely to the direction of flow and is formed from the screen surface ( 16 ), the swirl element to you b ( 3 , 50 ) leaves a cleaning body passage gap ( 17 ) open, and that at least one point of the swirl space has a suction opening ( 26 , 64 ) which is connected to the outlet opening ( 8 ). 8. The device according to claim 7, characterized in that the lifting device ( 4 ) consists of only one swirl chamber ( 13 ), and that the limiting element ( 14 , 27 , 30 , 40 , 42 , 60 ) up to almost the screen surface ( 16th ) enough. 9. The device according to claim 7, characterized in that the lifting device ( 4 ) consists of two adjacent vortex spaces ( 32 , 33 ) which have a common delimiting element ( 34 ), and that the two vortex elements ( 35 , 36 ) extend one side of the limiting element. 10. Device according to one of claims 7 to 9, characterized in that the limiting element ( 14 , 27 , 30 , 34 , 40 , 42 , 60 ) is designed as a flat plate. 11. Device according to one of claims 7 to 9, characterized in that the swirl element ( 15 , 28 ) is ausgebil det as a flat plate inclined to the flow. 12. Device according to claims 7 to 10, characterized in that the limiting element ( 14 , 40 , 42 ) is formed by extension to the upstream side of the lifting device from as a flow divider ( 18 , 41 , 43 ). 13. The apparatus according to claim 12, characterized in that the limiting element ( 14 , 42 ) in the region of the flow divider ( 18 , 43 ) has a thickened cross section ( 19 , 44 ). 14. Device according to one of claims 7 to 10, characterized in that the limiting element ( 60 ) in the immediate vicinity of the screen surface ( 16 ) has an elastic part ( 61 ). 15. The apparatus according to claim 7, characterized in that a suction opening ( 26 ) is arranged at least on one of the two axial ends of the swirl chamber ( 13 , 32 , 33 ). 16. The apparatus according to claim 7, characterized in that the suction openings ( 64 ) are arranged in wesent union transversely to the vertebral axis and there open into a manifold ( 63 ) which device with the Abhebevorrich ( 4 ) forms a unit. 17. The device according to claim 7, characterized in that the screen (3) has a substantially rectangular shape and at least one lifting device (4) is guided on on a straight path on the screening surface (16). 18. Device according to one of claims 7 to 16, characterized in that the sieve ( 3 , 50 ) has a substantially rotationally symmetrical shape, and that the lifting device ( 4 ) from at least one radially directed arm ( 25 ) with a swirl space ( 13 , 32 , 33 ), which is rotatably mounted about the longitudinal axis of the sieve ( 3 , 50 ). 19. The apparatus according to claim 18, characterized in that there is a suction opening ( 26 ) at the central end of the vortex chamber ( 13 , 32 , 33 ) and there in a in the longitudinal axis of the sieve ( 3 , 50 ) arranged tube ( 5 , 55 ) opens, which is connected to the outlet opening ( 8 ). 20. The apparatus according to claim 18, characterized in that the sieve ( 3 ) has a conical shape. 21. The apparatus according to claim 18, characterized in that the sieve ( 50 ) has the shape of a spherical cap. 22. Device according to one of claims 18 to 21, characterized in that the sieve ( 3 , 50 ) bulges in the direction of the water flow and there is a suction opening ( 26 ) in the region of the sieve axis. 23. The device according to any one of claims 18 to 21, characterized characterized in that the sieve against the Water flow arches and there is a suction opening on the outside end of the vertebral space. 24. The device according to claim 7, characterized in that the sieve ( 3 , 50 ) is made of perforated sheet be. 25. The device according to claim 7, characterized in that the sieve ( 3 , 50 ) consists of substantially concentrically arranged sieve bars. 26. The apparatus according to claim 7, characterized records that the sieve is essentially parallel arranged sieve bars there. 27. An apparatus for performing the method according to claim 7, characterized in that the lifting device ( 4 ) is driven by a motor. 28. Apparatus for carrying out the method according to claim 7, characterized in that the lifting device ( 4 ) for water flow inclined surfaces ( 9 ) carries or is itself profiled in such a way that the rotation takes place by the cooling water flow itself. 29. Device according to one of claims 7 to 28, characterized characterized that at least parts of the sieve are pivotally mounted. 30. The device according to claim 29, characterized in that the lifting device ( 4 ) is mounted in the center of the screen ( 3 , 50 ) and forms a pivotable unit with this.