NL1030248C2 - Screw jack for lifting water, has radial dimensions of screw blade at bottom end of screw designed to reduce injury to migrating fish - Google Patents

Abstract

The radial dimensions of the screw blade (8) at the bottom end (14) of the conveyor screw (17) decrease evenly in the opposing direction to the top end (15) of the screw. The conveyor screw comprises a screw beam (7) with at least one screw blade extending around it, as well as a trough (18) in which the screw is rotatably mounted in a tight fit manner. The screw has a slanting central axis and its rotation direction is chosen so that water is transported from its bottom end to its top end. An independent claim is also included for a water lift apparatus, comprising a casing (2) which extends between a lower body of water (3) and a higher body of water (5), containing this screw jack (1).

Description

I ---————

Screw violet. as well as a water-raising device provided with a specific screw-type violet

The invention relates to a screw auger for raising liquids such as water, comprising a conveyor screw consisting of a screw beam and at least one helical blade running around the screw beam, as well as a trough in which the conveyor screw is tightly and rotatably received, wherein in operation the center line of the conveyor screw is inclined and the direction of rotation of the conveyor screw is chosen such that a conveying action is obtained from a lower end to an upper end of the conveyor screw.

Such a screw auger, which is also known under the designation Archi-! fellow screw, is known. The screw blade of the conveyor screw extends at the circumference to close to the inner wall of the trough, which in this connection is usually semi-cylindrical. When the transport screw is rotated, the water is raised from a relatively low water level on the rotating screw blade to a relatively high water level. Because the circumference of the propeller blade is located close to the inner wall of the trough, leakage of the supplied water can be kept as small as possible. If desired, sealing means, such as a flexible sealing lip, can be provided in a known manner at the peripheral edge of the conveyor screw, the purpose of which is to virtually completely exclude the leakage.

The transport screw, i.e. both the screw beam and the screw blades, usually consist of stainless or preserved steel. The propeller blades are plate-shaped, and have a boundary edge or end edge both at their upper end and at their lower end which is directed radially with respect to the axis of the conveyor screw. In view of the relatively small thickness of the plates from which the propeller blades are made, this boundary edge or end edge is relatively sharp. This appears to be a problem for fish stocks. In fact, it has been found in practice that a certain percentage of the fish that tries to migrate via the screw jack from the water body with the relatively low water level to the water body with the relatively high water level, is affected by these boundary edges or end edges of the propeller blades .

The importance of this fish migration must be seen in particular in relation to reproduction and the search for food. The fish usually tries to swim upstream or downstream in order to reach suitable spawning and / or feeding areas. During the migration, therefore, the largest possible percentage of the fish must be able to pass through the various installations in the watercourse without being damaged.

Since the ecological aspects are also becoming increasingly important in waters in which such screw jacks are used, this adverse effect of the transport screws in question is becoming an ever greater disadvantage. Recent estimates show that about 20% of the fish do not survive the migration via the screw auger. This is caused by the fact that the fish sees no chance of avoiding the boundary edges or end edges of the conveyor screw moving relatively fast through the water. The fish is affected by this, and usually collapses as a result of the injuries sustained.

The use of gratings that would prevent the fish from accessing the transport screws is of course not an option, since it makes migration impossible. Attempts to further reduce fish mortality as a result of migrating from a relatively low water level to a relatively high water level via a screw auger have had little effect so far. A proposal is known in which an attempt is made to provide a more or less open passage for the fish via venturi action generated by a screw pump or centrifugal pump. However, a disadvantage of this is that a relatively high motor power is required for generating the venturi effect, which leads to a very high energy consumption.

The object of the invention is therefore to provide a screw jack of the aforementioned type wherein the risk of fish mortality during the migration of the fish can be kept to a minimum. That object is achieved by gradually reducing the radial dimension of the screw blade at the lower end of the conveyor screw in the direction away from the upper end of the conveyor screw.

In the screw jack according to the invention, screw blades are used whose lower boundary edge or end edge now no longer runs in a radial direction, but obliquely with respect to such a radial one. As a result, the screw conveyor of the screw auger is, as it were, slightly pointed, which entails advantages with regard to the passage of fish through the screw auger. The most important advantage is that the boundary edge or end edge is no longer perpendicular to the circumferential movement, so that a fish passing close to the boundary edge or end edge will be pushed away more gradually and will therefore be hit less directly. A further advantage of these circumstances is that the fish has more time to react and the boundary edge or end edge can more easily escape. Another advantage is that the rotating boundary edge or end edge does not move at right angles to the swimming direction of fish, but more in the swimming direction of the fish.

In particular, the screw jack according to the invention can be designed in such a way that at the lower end of the conveyor screw an acute angle is determined between a tangent on both the surface of the screw beam and on the surface of the conveying screw, and an outer intersection of this tangent edge of the screw blade. Furthermore, in the usual manner, at least two screw blades can be provided, which screw blades have a decreasing radial dimension in the same way at the lower end of the conveyor screw. The trough may have a semi-cylindrical portion as well as upright walls that protrude from the semi-cylindrical portion. The upper part of the trough can be covered in a conventional manner, for example by means of a flat plate which rests on the upright walls.

In order to prevent the conveyor screw from getting blocked by any hard objects, such as pieces of wood and the like, which could get stuck between the circumference of the propeller blades on the one hand and the inside of the trough on the other hand at the meeting point of the circumference of a screw blade and the inside of the trough at or just below the water surface, near the lowest part of the trough a cover is provided in the form of a half cylinder. This half cylinder is then located from the lowest edge of the trough to beyond the height of the water line of the water body with the relatively low water level, such that such hard objects cannot reach the circumference of the blades of the conveyor screw there.

The invention also relates to a water lifting device, which comprises a housing which extends between a water body with a relatively low water level and a water body with a relatively high water level, as well as a screw auger as described above which is incorporated in the housing, which screw auger comprises a transport screw consisting of a screw beam and at least one screw blade running helically around the screw beam, as well as a trough in which the transport screw is arranged close and rotatably, the axis of the transport screw being inclined and the direction of rotation of the transport screw it is chosen that a conveying action is obtained from a lower end to an upper end of the transport screw.

Such a water lifting device is also known. According to the invention, it is provided that the radial dimension of the screw blade at the lower end of the conveyor screw decreases gradually in the direction away from the upper end of the conveyor screw. The lower end of the screw jack is then immersed in the body of water with the relatively low water level. In that connection, in order to avoid blockage by any hard objects, a cover is provided near the lowest part of the trough in the form of an approximately half-cylinder and cuts through the mirror of the body of water with the relatively low water level.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the figures.

Figure 1 shows a side view, partly in section, of a water lifting device according to the invention.

Figure 2 shows the section according to II-II of Figure 1.

Figure 3 shows the section according to III-III of Figure 1.

Figure 4 shows the section according to IV-IV of Figure 1.

Figure 5 shows a detail.

The water lifting device shown in Figure 1 comprises a screw jack designated in its entirety by 1, which is located in a housing 2. The housing 2 is only schematically represented, and also forms the separation between a water body 3 with the relatively low water level 4, and a water body 5 with the relatively high water level 6. By means of the screw jack 1, water can be transported from the water body 3 with the lower level to the water body 4 with the higher level.

The screw auger 1 consists of a conveyor screw 17 and a trough 18. This conveyor screw 17 in turn consists of the so-called screw beam 7, as well as the three screw blades 8 welded thereto. Although in the example shown three of such screw blades are shown, other numbers possible such as a single or more than two. As shown in Figs. 2-4, the trough 18 encloses the outer edges of the screw blades 8 so tightly that the desired conveying effect is obtained without significant leakage. The trough 18 consists of a semi-cylindrical shell 21, on the free edges of which the projecting walls 20 are provided.

The screw beam 7 is supported on a foundation 11 by means of a lower support bearing 10, and on a foundation 13 by means of an upper support bearing 12. A further electric motor (not shown) is connected to the screw beam 7. By means of this electric motor, the transport screw 17 can be set in rotation such that the screw blades 8 provide the desired transport action from the lower end 14 to the upper end 15.

With the known screw jacks 1, both at the upper end 15 and at the lower end 14, the boundary edge or end edge 16 of the screw blades 8, 9 is directed in a radial direction with respect to the axis of the conveyor screw 17. At the lower end, there arises the problem that such a radially directed boundary edge or end edge can damage damage to migrating fish via the screw auger 1 from the water body 3 with the low water level to the water body 5 with the high water level. . This is because in practice it appears that about 20% of the migrating fish do not survive this passage via the screw Auger 1 or are seriously damaged.

According to the invention, therefore, the portion 20 of the screw blades 8 facing the lower end 14 is chamfered, in the sense that the radial dimension of each screw blade 8 outside the trough 18 gradually becomes smaller. These beveled boundary edges or end edges are indicated by the reference marks 19. Such a beveled boundary edge or end edge 19 has the advantage that fish are thereby considerably less at risk. As a result, virtually all fish can migrate undamaged via the screw jack 1 according to the invention.

Conventionally, the trough 18 is covered at the top by a plate 9 which rests on the walls 20 of the trough 18. At the level of the mirror 4 of the water body 3 with the relatively low water level, a cover plate 22 is provided. The purpose of this cover plate is to prevent relatively hard objects, such as pieces of wood, which are located in the body of water 3 from becoming stuck, as a result of which the rotation of the jack can be blocked.

_1 030 7 48_

Claims (12)

A screw auger (1) for raising liquids such as water, comprising a conveyor screw (17) consisting of a screw beam (7) and at least one screw blade (8) running around the screw beam (7), as well as a trough ( 18) wherein the conveyor screw (17) is tightly and rotatably received, with the axis of the conveyor screw (17) tilted in operation and the direction of rotation of the conveyor screw (17) is selected such that a conveying action is obtained from a lower end ( 14) to an upper end (15) of the conveyor screw (17), characterized in that the radial dimension of the screw blade (8) at the lower end (14) of the conveyor screw (17) gradually decreases in the direction which is remote from the upper end (15) of the conveyor screw (17). 2. Screw jack (1) according to claim 1, wherein at the lower end (14) of the transport screw (17) an acute angle is defined between an tangent on both the surface of the screw beam (7) and on the surface of the transport screw (17), and an outer edge of the screw blade (8) intersecting this tangent line. ; 3. Screw jack (1) according to claim 1 or 2, wherein the radial dimension of the screw blade (8) in the direction remote from the upper end (15) of the conveyor screw (17) decreases to zero or substantially zero. Screw auger (1) according to one of the preceding claims, wherein at least two screw blades (8) are provided, which screw blades (8) have a radially dimensioned radial dimension at the lower end (14) of the conveyor screw (17) . Screw auger (1) according to any one of the preceding claims, wherein the trough (18) comprises a semi-cylindrical portion (21) as well as upright walls (20) protruding upwardly from the semi-cylindrical portion (21). The screw jack (1) according to claim 5, wherein the upper part of the trough (18) is covered. 1030 7 4 8_ Screw auger (1) according to claim 6, wherein the trough (18) is covered by means of a flat plate (9) that rests on the upright walls (20). A screw jack (1) according to any one of claims 4-7, wherein a cylindrically curved cover (22) is provided near the lowest part of the trough (18). The screw jack of claim 8, wherein the curved cover (22) extends from the lowest edge of the trough (18). 10 A water lifting device, comprising a housing (2) that extends between a water body (3) with a relatively low water level (4) and a water body (5) with a relatively high water level (6), as well as a screw jack (1) according to a according to the foregoing claims which is included in the housing (2), which screw jack (1) comprises a conveyor screw (17) consisting of a screw bar (7) and at least one screw blade (8) running linearly around the screw bar (7), and a trough (18) in which the transport screw (17) is tightly and rotatably received, the center line of the transport screw (17) being inclined and the direction of rotation of the transport screw (17) is chosen such that a transport effect is obtained from a lower end (14) to an upper end (15) of the conveyor screw (17), with | characterized in that the radial dimension of the screw blade (8) at the lower end (14) of the conveyor screw (17) gradually decreases in the direction away from the upper end (15) of the conveyor screw (17). The water lifting device according to claim 10, wherein the lower support bearing (10) of the screw jack (1) is completely submerged in the water body (3) with the relatively low water level (4). 12. Water-raising device according to claim 11 and provided with a screw mounting (1) according to claim 8, wherein near the lowest part of the trough (18) a cylindrically curved cover (22) is provided, which cover (22) abuts against the raised sides (20) of the trough (18). 1030248_