DE8811160U1 - Device for cleaning liquids - Google Patents

Description

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Patent Attorneys 2101.2 &Kgr;&Agr;/Be

Wenzel s Kalkoff FiaBkuhle 6 PO Box 2448 5810 Witten/Ruhr

Applicant: Taprogge GmbH

5802 Wetter, Ruhr 4

Description: Device for cleaning liquids

The invention relates to a device for cleaning liquids, in particular for the cooling water flowing into a heat exchanger, with a pipe section as a housing, with a sieve body covering the inside width of the pipe section and with an oscillating suction unit. direction on the inflow side for area-specific suction and thus for cleaning the sieve body.

Ww Such devices have been known for a long time. In the

US Patent 2,275,958 shows a corresponding device in which the actual filtering typically takes place in a housing that is usually cast and mounted so that it is accessible via a cover in order to provide a sufficient screen surface for rotating suction units.

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As a result of this special design, the known devices are complex to manufacture and, especially for large nominal diameters, so expensive that they are still not used today for filtering large quantities of water per unit of time have not been used.

It is therefore the object of the invention to improve a device of the type mentioned at the outset so that it can be manufactured much more cheaply and the advantages are essentially retained.

To solve this problem, the invention proposes that the sieve body is essentially designed as a semi-rotational body, the frontal boundary plane containing the axis of rotation essentially coinciding with a cross-sectional plane of the tubular housing.

The invention therefore dispenses with a complicated housing and instead teaches the use of half of a rotating body as a sieve arrangement, with its lateral boundary plane approximately corresponding to the cross-sectional shape of the tubular housing. Consequently, the sieve arrangement can also be conveniently inserted into the tubular housing from one side.

The specific advantages of such a device, namely the arrangement of a suction pipe on one side of the rotation axis and the arrangement of a shaft to the oscillating movement of the suction device on the opposite side, remain fully intact. This also applies to those designs in which the sieve body is not a hemisphere, but is made up of sections that, for example, have the shape of a truncated cone. semi-rotary body or a cylindrical semi-rotary body. Furthermore, the sieve arrangement can be self-supporting or can be designed as a frame with sieve elements placed on top, which have no supporting function or are partially

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can be equipped with a supporting function.

Particularly in the case of a self-supporting construction of the sieve arrangement, this can be mounted in the pipe housing with the aid of lateral pins, so that the sieve can be pivoted by at least 90° for cleaning purposes or in emergencies, or even by 180° for flushing. The pins can be hollow, so that the usual arrangement of the suction pipe for the suction device and the shaft for the movement of the suction device can be retained.

In certain applications, an emergency passage is essential, but the construction effort for a pivoting screen arrangement is too great. In this case, the invention proposes, for example, that plate-like seals are provided between the peripheral edge of the screen arrangement and the pipe housing, in which flaps are arranged so that they can pivot, or whole plates of which are pivotably mounted, which are held in place with the aid of a shear pin or the like and automatically release these emergency passages if the pressure difference across the screen arrangement is too great.

In another variant, the lateral boundary of the outermost truncated cone-shaped semi-rotation body is formed by a semi-circular plate that is either liquid-tight or belongs to the suctioned sieve body, i.e. is perforated. Regardless of the design, these lateral, semi-circular plates can be arranged so that emergency passages are opened up at this point in an emergency. If these semi-circular plates are designed as a sieve arrangement, it can be achieved with skillful positioning of the shaft that these semi-circular plates are flushed through in emergency operation, i.e. the direction of the flow is reversed.

Since the achievable screen area is limited due to the constraints imposed by rotational symmetry, it is advisable in certain cases to choose an inner diameter of the pipe casing that is larger than the clear diameter of the connecting pipes. This is achieved in a particularly simple manner by providing the pipe casing with inner flanges that are combined with the outer flanges present on conventional pipe sections. In this way, a diameter increase of up to 20% is achieved compared to the inner diameter of the connecting pipes.

A particular advantage of the device according to the invention is that it is extremely short, meaning it can be accommodated in extremely confined spaces. The actual space required is determined by the size of the lateral passages for the suction pipe or the shaft for the suction device, including a certain distance from the connecting flanges; a sieve arrangement that protrudes beyond the flanges is harmless as long as the adjoining pipe sections do not have any extreme bends or built-in components that could collide with the sieve arrangement.

Embodiments of the invention, which are shown in the drawing, are explained in more detail below; in the drawing:

Figure 1 is a side view of a device for cleaning liquids according to

the invention in a first embodiment,

Figure 2 is a plan view of the device according to Figure 1,

Figure 3 a side view: according to Figure 1

of another embodiment

The

the invention with enlarged housing

due to internal flange surfaces,

Figure 4 is a plan view of the embodiment according to Figure 3,

Figure 5 is a view according to Figure 1 of a

further embodiment of the invention and 10

Figure 6 is a plan view of the embodiment according to Figure 5.

Figure 1 shows a pipe housing 1 with front-side !5 external flanges 2, which is screwed into the supply line to a heat exchanger in a power plant, for example. The low height of the actual pipe housing 1 is striking, which has advantages in confined spaces and of course also has a positive effect on costs. Above a level 3, which coincides with a cross-sectional area of the pipe housing 1, there is a sieve body 4, which consists of several frustoconical sieve sections 5. There are a total of six such sections, two of which are similar in shape.

Since the envelope curve of the sieve body 4 is a polygon, within the plane 3 between the ends of the sieve sections 5 and the housing wall, there are built-in components (not shown).

3Ö) which form a liquid-impermeable bridge between each sieve section and the housing wall. These bridges can contain plates or consist of plates which can be pivoted to provide an emergency passage and are thus permeable to the liquid to be cleaned. The operation of such flaps or plates can be automatic with the help of shear pins or motorized.

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Below the sieve body 4 there is a suction device 10, which is essentially made up of a stepped pipe 9, two guide pipes 11 and a suction ring 12. The suction ring is a semi-open structure adapted to the contour of the sieve body 4 , the inside of which is connected to the guide pipes 11. The front edges of the suction ring pointing towards the sieve body are aligned with webs on the inside of the suction body 4 in the individual cleaning positions, so that in the

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iitellungen a segment-like structure of the sieve body is captured, namely subjected to cleaning.

The suction device 10 can be pivoted around a central axis, which is located within the plane 3 and is at the same time the central axis of flange bushings 7 and 8, which are attached to the side of the pipe housing 1. The larger flange bushing 8 accommodates the connection and bearing of the step pipe 9, while the smaller flange bushing 7 is crossed by a shaft 15, via which the pivoting movement of the suction device 10 is gradually carried out over the entire area of the sieve arrangement 4. For this purpose, a corresponding drive 16 is provided, which is usually driven by an electric motor 18, but can be operated with the help of a handwheel 17 in the event of a power failure. The flange bushing 8 is connected to a suction line, via which a suction effect can be applied to the suction ring 12.

During normal operation, the suction device 10 is in its middle position shown in Figures 1 and 2, in which it offers the least resistance to the liquid flow passing through the tubular housing 1.

The liquid flows into the housing 1 from below and passes through the sieve arrangement from bottom to top. At regular intervals or as required, which is determined by a

Pressure difference measurement via the sieve arrangement 4 can be determined, the suction device 10 is activated, which causes a flow reversal through the sieve arrangement within the area covered by the suction ring 12. As a result of this flow reversal, all the contaminants collected on the underside of the sieve arrangement 4 are released and leave the device via the step pipe 9. The suction device 10 is moved to another area after a certain cleaning period. area, which is now cleaned. This process is repeated until all areas of the sieve arrangement 4 have been reached. The suction device 10 then returns to its starting position, unless the load caused by contamination of the cooling water to be filtered requires continuation of cleaning in a quasi-continuous operation.

Depending on the design of the sieve arrangement 4, the suction device 10 is either in continuous suction mode I or step by step with interrupted if necessary Suction effect during the swivel movement. The first operating mode is selected when the surface of the sieve body 4 to be suctioned is smooth, i.e. there is sufficient sealing at every point between the suction ring 12 and the

Sieve body 4 is present. The second operating mode is

selected if the sieve body 4 has webs which must first be aligned with the boundary walls of the suction ring 12 before a satisfactory suction and thus cleaning effect can be achieved. Of course ribs or webs on the underside of the sieve body 4 must be matched to the shape of the suction ring 12, i.e. they must be designed to be congruent with it. This also applies to the areas close to level 3/whereby only the contact contour must match, which §

Further design of the webs is free. An inclination | of the webs in the areas close to level 3 in the direction |of the fluid flow to reduce the resistance | is therefore easily possible. |

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The embodiment according to Figures 3 and 4 differs from the one described above essentially in that the pipe housing is provided with an inner flange 20, while the connection to the adjacent

Pipelines in the usual way with the help of external

flanges 21 on the pipes. This results in an increase in the cross-sectional area by approximately the flange width, which brings with it a welcome increase in the screen area.' Since surface areas are already present at the transition zone to the pipe housing wall must remain unused as a screening area because they are not accessible to the extraction, the aforementioned enlargement can be used to compensate for these loss areas.

In Figures 1, 3 and 5, two flanges 22 (Figure 3) can also be seen, through which access to the flowing medium is available before and after the sieve body 4. At these points, the static pressure measured and the degree of contamination of the filter device can be determined. Appropriate processing of this signal initiates a suction cycle, determines the duration of the suction or activates flaps or plates to open emergency passages. In this regard the invention follows familiar paths.

In the embodiment according to Figures 5 and 6, the screen surface consists of two opposing, koi ic sections 5, an intermediate, cylindrical section 28 and two lateral, semi-circular plates 24, of which the plates 24 are each designed to pivot about a shaft 26. Emergency passages can therefore be opened at these points. The suction device is of course connected to this adapted to the changed contour so that all areas of the sieve arrangement are covered.

The lateral, semicircular plates 24 are fixed with the aid

of ribs25 to form a stable unit, which is held solely by the shaft 26. The position of the shaft 26 is selected in such a way that when the shaft is swung out - a corresponding position is indicated in the right half of Figure 5 - the sieve areas of the plates 24 are flushed in reverse, so that cleaning that is not successful in conjunction with the suction may be successful by means of reverse flushing. In addition, these plates 24 can be used in In individual cases, the plates can also be designed to be impermeable to liquids, which depends on the specific case. Below the semi-circular plates 24 there are guide elements 29, which are always designed to be impermeable to liquids. They bridge the gap between the individual sieve sections and the pipe housing.

The position of the shafts 26 can be clearly seen from the figure ϑ, which are pivotably mounted within the bushings 27. Depending on the equipment of the direction, shear pins hold the semicircular plates 24 in their desired position, or motorized adjusting means are attached to the shafts 26 so that the shafts 26 can be pivoted as desired. From Figure 5 it can be clearly seen that the shafts 26 and thus the The axis of rotation is located in the lower part of each plate 24, so that with the corresponding fluid pressure on the inside a moment in the opening direction is created. This is used to create an emergency passage in conjunction with shear pins when the filter elements are too dirty. to release when the moment has increased so much that the shear pins release the movement.

In the embodiments shown, the guide tubes 11 or the suction ring (Figure 5) are sucked off via a stepped tube that is led out on one side of the tube housing. Of course, if there is a corresponding requirement, each guide tube II or each side of the suction ring (Figure 5) can be connected to a separate,

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The suction takes place via a pipe stump1 that extends laterally from the pipe housing. Both pipe stubs are then connected to one another with a relatively thin shaft to ensure synchronous movement. The pivoting then takes place via one of the pipe stubs, which is driven in the manner described instead of the shaft 15 in Figure 1. A corresponding design has the advantage that the cross-sectional constrictions in the middle area due to built-in components are very small.

In theory, it is sufficient to swivel the suction crane 12 within the area specified by the sieve arrangement for suction of the sieve arrangement. arrangements which are arranged on the side facing the suction ring 12 side, but in which the suction ring slides directly over the screen surface, impurities can accumulate on both sides of the suction ring 12, which are removed by the suction ring 12 in the manner of a scraper over the screen surface. In order to capture these contaminants, it is advisable that the swivel range of the suction ring 12 is extended so that in the two extreme positions at least one edge of the suction ring extends over the edge of the screen. This then leads to a direct sucking of the incoming liquid into the suction ring, so that impurities that have accumulated on the outside of the suction ring 12 are also sucked away. In addition, the accounts of the suction ring 12 as a result of the resulting tear-off vortex, so that the overall screen cleaning can be optimized. This is an advantage that cannot be achieved with conventional, closed screen surfaces in the form of a cylinder and a suction rotor rotating in it ⁴ St,

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Claims (16)

* * A &Lgr; ft 4 Patent Attorneys 2101.2 &Kgr;&Agr;/Be Wenzel & Kalkoff Flaflkuhle 6 PO Box 2448 Witten/Ruhr Protection claims 1. Device for cleaning liquids, in particular for the cooling water flowing into a heat exchanger, with a pipe section as a housing, a screen body covering the clear width of the pipe section and with an oscillating suction device on the inflow side for suctioning in certain areas and thus for cleaning the screen body, characterized in that the screen body (4) is essentially designed as a semi-rotary body, the frontal boundary plane (3) of which contains the axis of rotation essentially coincides with a cross-sectional plane of the pipe housing (1). 2. Device according to claim 1, characterized in that the sieve body (4) is divided into at least two sections (5), of which at least the outermost ones are frustoconical semi-rotation bodies. 3. Device according to claim 2, characterized in that the outermost, truncated cone-shaped semi-rotary body (5) is delimited towards the wall of the tube housing (1) by a substantially semicircular plate (24), and that between the straight longitudinal edge of the plate (24) and the tube housing wall there is a space which is unobstructed by the liquid. 4. passable ·< III! ·· 1 («It« · · ·
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any semicircular 5. contraption
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ke &eegr;&eegr;&zgr; e Guide installation (29) according to claim 3, characterized geke &eegr;&eegr; -
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of the extracted sieve body (4). 5 according to claim 3
I &eegr; et that Plate (24) is arranged to pivot about an axis. 10 6. Device according to claim 4 and claim 5/characterized in that the pivot axis of each semicircular sieve plate (24) is arranged in such a way that in the pivot position a reversal of the flow direction and thus a flushing effect occurs. 7. Device according to claim 1 or 2, characterized in that the entire sieve arrangement is self-supporting and is arranged to pivot about lateral pins. 8. Device according to claim 7, characterized in that the pins are designed as hollow pins, and that the suction line of the suction device or the pivot shaft for driving the suction device crosses the pins. 9. Device according to claim 1 or 2, characterized in that in the frontal boundary plane of the sieve body (4) between the circumference of the sieve body (4) and the pipe housing wall seals in the form of non-liquid-permeable plates are attached, and that areas of the plates or at least one plate is pivotally mounted as a hot passage. 10. Device according to one of claims 1 to 6 or According to claim 9, characterized in that the sieve body (4) is formed by a frame onto which sieve elements without a supporting function or with a partially supporting puncture are applied. 11. Device according to one of the preceding claims, characterized in that the sieve body (4) is provided on the side facing the suction device (10) with webs or ribs, which are adapted to the contour of the suction device (10) or a suction ring (12). 12. Device according to claim 10 and claim 11, characterized in that components of the frame take on the web or rib function. 13. Device according to claim 11 or 12, characterized in that the webs or ribs in the region of the zenith of the sieve body (4) are arranged substantially vertically to the sieve surface and towards the edges in an inclined manner to the sieve surfaces in the direction of flow of the liquid. 14. Device according to one of the preceding claims, characterized in that the diameter of the pipe housing (1) is larger than the nominal size of the pipes to be connected. 15. Device according to claim 14, characterized in that the larger diameter of the Pipe housing (1) is formed in that an inner flange (20) is attached to the pipe housing (1), which is paired with an outer flange (21) customary on pipe sections.
35 16. Device according to one of the preceding claims, characterized in that the suction device is connected to two pipe stubs which each lead out laterally from the pipe housing (1), one of which is provided with a drive for the pivoting movement and which are rigidly connected to one another by means of a shaft. 1.7. Device according to one of the preceding claims, characterized in that the suction ring (12) of the suction device projects beyond the boundary plane (3) of the sieve body (4) in at least one extreme turning position. 15 20 25 30 35