DE19502800A1 - Mechanical cleaning device for liq.(s), esp heat exchanger cooling water - Google Patents

Abstract

Mechanical purification device for liq., esp. cooling water for a heat exchanger. The liq. flow into a pipework (10) having a rotation symmetric conical filter body (12) essentially the same size as the pipe dia. There is also a suction device (20) on the same axis and on the impinged side of the filter body (12), which can rotate and with the help of a drive (26,28,30) swivel continually or with pauses during a cleaning interval. The device (20) has an inlet nozzle (22), and sucks repeatedly over the entire filter body surface during the cleaning interval. The filter body is divided into regions (37,38,39) and the nozzles (e.g. 22) can cover each region. In each area of the actual filter surface and the suction device there is a hollow space for temporary storage of contaminants (52). On the impinged side the filter body (12) is subdivided into sectors forming the regions by elements (e.g. 36) forming the hollow spaces. The inlet nozzle (22) is shaped such that when it exactly cover a region (e.g. 38), the neighbouring regions (e.g. 37,39) is free, and the gap (a) between the free element edges (50) and the nozzle edge is bridged by flexible sealing lips (e.g. 44) of at least the height of the gap. The cone point (61) has no pins (36), so that chutes (63) appear, and the fitting (24) near the cone point (61) has an opening (62).

Description

The invention relates to a device for mechanical cleaning of liquids, in particular from a heat exchanger cooling water to be supplied in a Flow pipeline with a rotationally symmetrical, conical sieve body in the essentially in the size of the pipe diameter and a coaxial, on the inflow side of the screen body arranged suction device, which is rotatable stored with the help of a drive for the duration of a cleaning interval swiveling continuously or intermittently and with an inlet nozzle is provided and gradually the entire during the cleaning interval Aspirates surface of the screen body on the upstream side, the screen body in Areas are divided, the inlet nozzle of the suction device each area can cover and in each area of the actual screen area and the Suction device a cavity for the temporary reception of Contamination is present, the screen body on the upstream side by in essentially radial webs forming the cavities into individual areas forming sectors, the inlet nozzle of the suction device is one Form that it has at the time the inlet nozzle is just a sector covers, leaves adjacent sectors essentially free, and the gap between the free web edges and the edges of the inlet nozzle of the suction device flexible sealing lips are bridged by at least the height of the gap.

Such a device is already known from EP 0 268 752 B1.  

With cooling water filters, it is advantageous to have a large storage capacity for deposited To reach dirt, so that the strainer in the event of a sudden large amount of dirt is not mechanically overloaded and the cooling water flow to the condenser is not is greatly reduced or even interrupted. Such an interruption is at Operation of power plants intolerable.

A relatively large dirt capacity is achieved by means of a conical sieve, as is shown, for example, in FIG. 6 of the European patent specification. By blunting this conical sieve, the total achievable sieve area is reduced. You can increase the sieve area by letting the truncated cone taper to a point, but the segments in the cone tip become so narrow that coarse dirt such as wood, stones, shells can get stuck between the ridges and then no longer be vacuumed off. On the other hand, for power plant reasons, the segments and thus the amount of water suction cannot be chosen to be arbitrarily large, because the suctioned water cannot be extracted from the cooling process at any height.

The object of the invention is to design the known device in such a way that that these disadvantages are avoided. The task is solved in that the Cone tip has no webs and the front sides of the rest of the area Arrange arranged webs at no limit, so that funnel-shaped Slides arise that are open on the upstream and downstream sides, so that hard Contamination such as stones, shells along the sieve surface into the non-web The cone tip slips and there from the opening in the suction rotor be sucked off.

An advantageous embodiment is that the conical screen body in Area of the web-free cone tip has no sieve openings. This will make one improved removal of the impurities accumulated in the cone tip reached. By collecting the hard impurities in the cone tip remains the sieve body clean for a long time, so that the rinsing intervals are extended can and it saves water.  

It is also advantageous to use the flexible seal as a flexible hollow body, preferably as Form hose and additionally support with sheet metal. Sealing with Hose has the advantage that manufacturing inaccuracies are better compensated can be with a correspondingly high rigidity against the negative pressure when Suction.

The arrangement according to the invention enables a conical sieve relatively sharp, so that the blunting of the cone resulting reduction in screen area remains relatively small.

The conical sieve formation has considerable cost advantages over all other versions. This shape is easy to manufacture, even with large ones Screen area, and can withstand the pressure and flow forces without additional, expensive Support structures, as described in the prior art, record. Since the Cooling water filters mostly used for sea water cooling must be there highly corrosion-resistant expensive special metals are used. By eliminating the Support structure, as the state of the art deems necessary, is reduced the material and manufacturing costs by at least 50%.

The arrangement according to the invention also avoids, despite the relatively pointed cone shape, that through the accumulation of stones, wood, shells, etc., the suction nozzle during the rotary movement is blocked and the screen surface can no longer be suctioned off can. This danger still exists in the prior art, since this is the second There is no suction for the sieve bottom.

Mostly you will arrange the webs so that they with their longitudinal axis extension run through the axis of symmetry of the sieve body, but there is also one such an arrangement is possible in which the centers of those formed by the webs Central angles lie outside this axis of symmetry, for example on a this circle arranged around this axis of symmetry.

The invention is explained in more detail below on the basis of exemplary embodiments, which are shown in the drawings.  

It shows:

Figure 1 is an axial sectional view of the basic shape of a device.

FIG. 2 is a view along the section line AA of FIG. 1;

Fig. 3 is a sectional view taken along the section line BB according to Figure 1 for illustrating an improved embodiment.

FIG. 4 shows a sectional view along the section line BB according to FIG. 1 to explain a further improved embodiment;

Fig. 5 is a sectional view taken along the section line BB according to Figure 1 for explaining another improved embodiment.

FIG. 6 shows a sectional view along the section line BB according to FIG. 1 to explain a further improved embodiment;

Fig. 7 is a perspective view of the slide.

From FIG. 1, a cooling water supply pipe 10 can be seen, which preferably leads to a heat exchanger or a condenser of a power plant further comprises a cone-shaped screen body 12 which is mounted within one of the flange 14 of the cooling water supply pipe 10 pipe section 16 is arranged. The cooling water flows through the pipe section 16 and then through the cooling water supply line 10 in the direction of arrow 18 . On the upstream side of the screen body 12 , a suction device 20 can be seen with a suction nozzle 22 opposite the screen body 12 , which is connected to a nozzle 24 coaxial with the pipe 10 or pipe section 16 and via a drive shaft 30 either directly or via a gear 28 with an outside the pipe section 16 arranged motor 26 is driven in rotation. At the rotatable nozzle 24 is a fixed pipe bend 32 , which penetrates the wall of the pipe section 16 radially outwards and z. B. is connected via a slide, not shown here, to a suction line, not shown.

Pipe elbow 32 and connecting piece 24 are connected via a bearing coupling 34, which is not described in more detail and which permits mutual rotation. Such as B. from the top view of the screen body 12 (view AA of FIG. 1, correspondingly also FIG. 2) and FIG. 3, the section along the section line BB of FIG. 1, the development of the screen area on an enlarged scale, apparent, are radial inflow side on the screen body 12, provided against the flow direction (arrow 18 in Fig. 1) projecting webs 36, the screen surface into individual 12, as shown in FIG. 2 equal portions 37, 38 is divided. 39 A suction nozzle 22 is designed in the same way as the regions 37 , 38 , 39 , the two radial silk walls 40 and 42 of the nozzle 22 here having the same central angle 60 to one another as the webs 36 forming the regions 37 , 38 , 39 .

Fig. 3 shows that the ends of the radial side walls 40 , 42 of the suction nozzle 22 form a distance from the webs 36 and thus leave a gap a. According to the embodiment shown in FIG. 3, this gap a is bridged by flexible sealing lips 44 which are fastened to the ends of the walls 40 , 42 in a suitable manner, these sealing lips being somewhat longer in the embodiment shown than the gap width a , so that in the direction of rotation shown, arrow 46 comes to the fact that the free ends of the sealing lips 44 lie laterally against the webs 36 , with further movement in the direction of arrow 46 they bend away elastically, as can also be seen in FIG. 3 is, and with still further movement in the direction of arrow 46 are so strongly bent away that they can slide past the end face 50 of the webs 36 with their end face 48 and thus come free. During the period in which the sealing lips 44 abut against the webs 36 and remain in contact therewith, the suction nozzle 22 forms above the area 38 of the screen body 12 a space which is flow-separated in front of the adjacent areas 37 , 39 .

On the upstream side of the sieve body 12 , impurities deposited in the course of the operating time, for example grass, leaves, plastic, occasionally stones, shells, wood residues and the like, which lie within the region 38 , are removed during this period by the action of in the suction line 22 generated backflow 54 from the inflow side 56 of the screen body 12 back into the area 38 and from there transported into the suction nozzle 22 , and from there finally via the nozzle 24 , the pipe bend 32 in z. B. transported a swamp.

As a result of the sealing of the gap a by the lip 44 (and, if appropriate, corresponding lips on region walls lying transversely thereto, not shown here), shunt paths impairing the flow force are interrupted.

The movement of the suction device 20 arranged on the inflow side of the screen body 12 can either be continuous, with a brief backflow occurring during the abutment of the sealing lips 24 on the webs 36 , or else with interruptions, for example in order to move to and through the individual areas in cycles particularly long backwashing processes to clean the sieve particularly intensively.

After a complete, 360 ° rotating movement, the entire surface of the screen body 12 can be suctioned off on the upstream side. The direction of rotation can then be reversed, which benefits the even loading and wear of the sealing lips.

The webs 36 create receiving spaces for deposited material 52 due to their web dimension projecting beyond the screen surface 56 , so that the cleaning process may only be necessary after a relatively long period of time, during which time the sector can fill with waste material. This period depends on the height of the webs 36 and on the still permissible amount of deposited material which increases the flow resistance.

It will be clear that, in particular when there is no excessive contamination or intermittent operation, the sealing lips 48 need only be as long as it corresponds to the gap dimension a, that is to say that they then do not contact the webs 36 invest.

In FIG. 4 and FIG. 5 is preferably formed as a flexible seal, the flexible hollow body as a hose 68 and attached to the walls 40 and 42, wherein another supporting surfaces 69 may be disposed.

In FIG. 6, the flexible seal consists of a sealing profile 70 with a convex limit or with inclined surface is formed to the web 36. An elastic element 71 generates the necessary sealing force.

Fig. 7 shows a chute 63 to screen body 12 and webs 36, with the inlet region 66 and outlet area 67.

Claims (7)

1.Device for the mechanical cleaning of liquids, in particular cooling water to be supplied from a heat exchanger, which flow in a pipeline ( 10 ) with a rotationally symmetrical, conical sieve body ( 12 ) essentially in the size of the tube diameter and a coaxial, on the inflow side of the Screen body ( 12 ) arranged suction device ( 20 ), which is rotatably mounted, with the aid of a drive ( 26 , 28 , 30 ) for the duration of a cleaning interval or can be pivoted intermittently and provided with an inlet nozzle ( 22 ) and gradually during the cleaning interval after the entire surface of the screen body ( 12 ) is suctioned off on the upstream side, the screen body ( 12 ) being divided into areas ( 37 , 38 , 39 ), the inlet nozzle (e.g. 22 ) of the suction device ( 20 ) can cover each area and a cavity in each area of the actual screen surface and the suction device r temporary absorption of impurities ( 52 ) is present, the sieve body ( 12 ) on the upstream side through essentially radial webs forming the cavities (e.g. B. 36 ) is divided into individual sectors forming the areas, the inlet nozzle (z. B. 22 ) of the suction device ( 20 ) has such a shape that it at the time when the inlet nozzle just covers an area (z. B. 38 ), adjacent areas (z. B. 37 , 39 ) leaves essentially free, and the gap (a) between the free web edges ( 50 ) and the edges of the inlet nozzle (z. B. 22 ) of the suction device (z B. 20 ) is bridged by flexible sealing lips (z. B. 44 ) of at least the height of the gap, characterized in that the cone tip ( 61 ) has no webs ( 36 ), so that slides ( 63 ) and the nozzle ( 24 ) has an opening ( 62 ) in the region of the cone tip ( 61 ). 2. Apparatus according to claim 1, characterized in that the flexible sealing lips ( 44 ) extend so far beyond the gap extension (a) that during the movement of the lips with respect to the webs they initially lay against them laterally, increasingly bend and finally glide over the web edge when bent. 3. Apparatus according to claim 1, characterized in that the flexible seal is designed as a flexible hollow body, preferably as a hose ( 68 ). 4. Apparatus according to claim 1 and 2, characterized in that the hose ( 68 ) is supported on other one or more surfaces ( 69 ) in addition to the fastening walls ( 40 and 42 ). 5. The device according to claim 1 to 4, characterized in that the inlet region ( 66 ) and the outlet region ( 67 ) of the slide ( 63 ) are covered by the inlet nozzle ( 22 ). 6. The device according to claim 1 to 5, characterized in that the conical sieve body ( 12 ) in the region of the web-free cone tip ( 61 ) has no sieve openings ( 65 ). 7. The device according to claim 1 to 6, characterized in that the seal which covers the gap (a) consists of a convex-shaped sealing profile ( 70 ) and an elastic element ( 71 ), guided by a holder ( 73 ).