FI87186C - Screw Grating - Google Patents

Description

87186

The present invention relates to a screw pin according to the preamble of claim 1.

Wastewater treatment plants remove solid constituents from the water to be treated by flickering. In this case, the water containing solids is led to a flap feed trough with a grille through which the liquid to be flushed can flow out of the flap, but the solids remain on the grille and are further lifted off by some sort of conveyor.

There are several known lightning solutions. They can be divided, for example, into the following groups with different operating principles: rake blades, step or chain blades and screw blades. The rakes have parallel slats with rake spikes in between. The flap is cleaned by transporting the rake between the slats. The stair or chain-like strips, which act as slats in the step and chain spacers, rotate around the perimeter and at the same time lift the spacer up from the liquid stream. In a screwdriver, the clearance accumulated on the surface of the slats is lifted from the liquid flow by means of a screw. The slats are usually arranged around the screw in the direction of its axis and form a semicircular cradle below the screw.

These known flicker solutions have several weaknesses. The wedge of solid components between the slats and the rake tines has proved to be a practical drawback of the rakes. Clogging causes the rake to wedge and often twist the slats and break loosely. Keeping the rake clean is very cumbersome and often requires a water jet to clean the spikes. The louver spacing of the rake blade is always large, because the rake tines must be sturdy due to the risk of entrapment and the high transfer resistance that occurs when the blade is partially or completely blocked. The slats of the flap must also be quite massive in order for the flap to withstand the stresses caused by the wedging of the solid as well as possible. Due to the large slots, the solid easily passes through the flap, 2 87186, leaving its resolution and efficiency poor.

The disadvantage of stair and chain flaps is their complex and expensive structure. The parts of the chain or lamellae acting as slats are in a straight line next to each other, and thus various solid particles tend to wedge between them. Trapping of chains easily causes damage and replacement of broken parts is expensive.

In known screw washers, an attempt has been made to prevent clogging by shaping the slats so that solids can easily leave the gaps between the slats. The slats can be, for example, triangular in shape and positioned so that the angle below the slats is large and one straight side of the triangle is towards the screw. The disadvantage of the known screw flaps is that the thin plastic films commonly contained in sewage today form a cover between the screw and the louvre, which quickly clogs the flap. Removal of these membranes requires discontinuation and at least partial disassembly of the flicker.

U.S. Pat. No. 1,698,387 discloses a flow gap with toothing on the flow-side edge of the slats. This flap can be cleaned by pressing the toothed plane against the flap and moving the slats in the direction of their longitudinal axes, whereby debris stuck to the slats moves in the direction of the teeth and is removed from the surface of the flap. The structure is complex and only suitable for planar spaces.

U.S. Pat. No. 1,773,576 describes a solution in which there are toothed rods between the slats of the flow gap, which are moved back and forth, whereby solid debris rises upwards at an oblique surface of the flap. Because the teeth extend as they move above the level of the slats, the structure is not suitable for screwdrivers. A similar solution is also disclosed in US 4,853,116 and GB 2,225,962.

The object of the present invention is to provide a lightning solution which does not clog as easily as known diapers.

The invention is based on the fact that the louvre louvre is formed of two interleaved louvres which are reciprocated relative to each other.

More specifically, the screw blade according to the invention is characterized by what is stated in the characterizing part of claim 1.

The invention provides considerable advantages.

The device according to the invention has several advantages over known flicker solutions. The relative movement of the slats prevents the formation of a thin film cover between the slats and the screw, as the reciprocating movement of the adjacent slats forms wrinkles in the films, allowing the screw thread to grip and grip the film and be able to remove them. The slats can be made from flat profiles on a normal commercial street and do not need to be massive, because no stresses are caused by clogging.

The gaps remain very efficient because the slats are in mutual motion and thus shed any clogging solid between the slats. Since the gaps between the slats are at a slightly downward angle to each other in the radial direction of the screw, no gap-sealing solid can be packed between the slats. Due to the small size of the screw in the direction of the screw axis of the deflection device, the device according to the invention can be installed, for example, in a sewage channel, whereby the installation costs of the flap remain very low.

The invention will now be described in more detail with reference to the accompanying drawings, in which: Figure 1 shows a side flap according to the invention, partly in section.

4 87186 Fig. 2 shows the movement mechanism of the flattened louvre in a partial section. Fig. 3 shows the flap in the direction of its longitudinal axis, Fig. 4 shows a cross section B-B of Fig. 1.

Figures 5 to 8 schematically show details of various embodiments of the invention.

According to the drawings, the flap consists of an axis 2, the center line C of which forms the central axis of the flap. An ascending screw thread 4 is arranged on the shaft 2. The circumference of the screw thread 4 is surrounded by a flap body 18 and a feed trough 6. At the top of the feed trough 6 there is a feed opening 5 below which there are two louvers in the direction of the screw axis. The slats 7 and 8 of the slats are interleaved with respect to each other. At the upper end of the shaft 2 there is a drive motor 1 and at the lower end there are deflection members 11 and 12. The screw thread 4 has a large diameter at the feed trough 6 and decreases conically after the feed trough 6 and continues inside the body 18 as a smaller diameter transfer screw towards the upper end. At the upper end of the screw thread 4 there is a discharge opening 3.

The structure of the slats is shown in Figures 3 and 4. The slats consist of flat-shaped profiles, slats 7 and 8. The slats 7, 8 are arranged on an arc defined by the outer circumference of the screw thread 4 parallel to the axis 2. The slats 7, 8 are of uniform thickness and their axial direction is parallel to the radius of the outer circumference of the screw thread 4, whereby the adjacent slats 7 and 8 form a triangular opening opening outside the flap. Of the slats 7, 8, one is a fixed slat 8 and the other a movable slat 7. The movable slats 7 are slightly longer than the fixed slats 8 and are attached at one end to an end support 9, which in turn is between the deflection plates 11 and 12. The slat is tied with support archs 17 in the circumferential direction of the screw thread.

5 87186

Attached to the end of the jacket on the side of the hopper 6 is a blocking plate 10 which prevents solid components from entering the louvre deflection apparatus (Fig. 2). The deflection device is arranged at the end of the shaft 2 and is powered by the shaft from the drive motor 1. The deflection device consists of two deflection discs 11 and 12 mounted on the shaft. One end of the outermost puzzles 13 and 15 is straight and the other oblique. Both ends of the bushing 14 between the deflection plates 11 and 12 are inclined. The deflection plates are placed between the buffers 13, 14, 15 and fixed in place by a screw 16.

The device described here works as follows. The drive motor 1 rotates the screw 4 rising through the shaft 2. A liquid containing solid constituents, for example sludge, is led to the feed trough 6 through the feed opening 5. In the louvre, which consists of louvers 7 and 8, solid particles and liquid are separated. The solid particles remain on the louvre as liquid flows through it out of the flicker. The drive motor 1 rotates a rising screw 4, the ridges of which are against the inner surface of the louvre 7 and 8. The screw moves the solid particles left on the surface of the louvre towards the discharge opening 3, through which they exit the flicker.

The end support 9 at the end of the slatted cradle consisting of movable slats 7 moves in the direction of the flattened axis C, displaced by the inclined deflection plates 11,12 on the support arches 17. In this case, as the shaft 2 rotates, the slatted cradle formed by the slats 7 moves back and forth with respect to the fixed slatted cradle formed by the slats 8. The gap between the slats 7, 8 remains constantly open due to their mutual movement, and no clogging films or other solid material can spread between the slat cradle and the screw.

In addition to the above, the present invention has other embodiments. The deflection device can also operate in such a way that the shaft 2 has fixedly arranged buffers 13 and 15, between which a freely movable deflection plate 22 with a diameter smaller than in the example shown is placed on the screw shaft 2. The deflection plate 22 β 87186 does not then rotate with the screw shaft 2, but is in the shape of a slot 23 at its lower end, in which the slot 23 has an end support 9 resiliently attached.

Instead of two louvers, more can be used, and all the louvers can be movable. In this case, a separate movement mechanism is required for each louvre, which may consist, for example, of several successive deflection plates and the ends arranged between them.

The relative movement of the slats can also be realized by fastening the movable slats at one end to the body of the flap and at the other end by means of a non-central pin and slot mechanism or crank mechanism to the shaft of the flap. In this case, the moving slats move in the direction of the screw radius. This solution is more susceptible to damage than the solution implemented with a longitudinal movement, because it is easier to get pieces stuck in the movement between the slats. Correspondingly, it is also possible to realize the transverse movement of the slats with respect to each other, but in this case the distance between the slats must be increased.

The mechanism for moving the slats can be realized, for example, by connecting a crank 25 to the end of the shaft 2 via an eccentric 24 and a slot, which is fixedly articulated from its center. The slot at the other end of the palm 25 is fitted into the groove 27 in the end support. In this case, the rotational movement of the shaft moves the crank laterally, and the crank moves the end support accordingly. If the end coming on the shaft of the palm is fitted in an oblique groove 29 on the shaft, the same mechanism can be used to make a longitudinal movement of the slats.

Various alternative mechanisms are shown in Figures 5-8.

Claims (10)

A screw flap for separating a solid from a liquid, the jacket comprising: - a central shaft (2) around which a screw thread (4) is arranged, - a body (18) partially enclosing the screw thread (4), - a feed tray (6) arranged as an extension of the body (18) ) with a supply opening (5) for supplying liquid, and - a louvre cradle arranged in the supply tray (6) and comprising a plurality of slats (7, 8) at least approximately in the direction of the shaft (2) surrounding the screw thread (4), characterized in that - at least a part of the slats (7) is connected to the shaft (2) of the flap by means of movement means (9, 11, 12) so that these slats (7) can be moved relative to the other slats (8) of the slat by the rotational movement of the shaft (2). Screw flap according to Claim 1, characterized in that the actuating means comprise two parallel deflection discs (11, 12) arranged diagonally at a distance from the shaft (2) and an end support (9) to which at least some of the slats (7) of the louvre are attached and extending between the deflection discs (11, 12). Screw flap according to claim 1, characterized in that the moving members comprise an end support (9) to which at least part of the slats are attached and a palm (18) one end of which is fixed to the end plate by means of a joint (20) and the other end of the other joint ( 19) via the shaft (2). 8 87186 Screw flap according to claim 1, characterized in that the actuating means comprise two pushers (21), each end of which is oblique and which are arranged on the shaft (2) at oblique ends at a distance from each other and between the pulleys (21). a freely rotating deflection plate (22) connected by a slot (23) to the end support (9). A screw flap according to claim 1, characterized in that there are two movement member mechanisms and part of the slats of the slat is connected to the first movement members and part to the second. Screw flap according to claim 1, characterized in that the moving members comprise a palm (25) arranged on the shaft (2) by means of an eccentric (24), fixed at its center to a fixed joint (26) and one end of which is arranged via a slot (27) to the end support (9) so that when the palm rotates due to the rotational movement of the shaft, the end plate (9) moves laterally with respect to the shaft (2). Screw flap according to claim 1, characterized in that the moving members comprise a palm (30) fitted through a slit in the inclined groove (29) on the shaft (2), fixed at its center to a fixed joint (29) and one end of which is fitted in the slit ( 23) to the end support (9) so that when the palm (30) moves in the groove of the shaft due to the rotational movement of the shaft (2), the end plate (9) moves longitudinally with respect to the shaft (2). 7 8 71 8 6 Screw flap according to Claim 2, characterized in that the deflection discs (11, 12) are supported on the shaft (2) by means of three pushers (13, 14, 15), both ends of which (14) between the deflection plates (11, 12) are oblique and of which the outer (13, 15) end against the deflection plate (11, 12) is oblique. 9 87186 Screw flap according to Claim 8, characterized in that the pushers (13, 14, 15) are locked to the shaft (2) by a nut (16). 10,871 86