NL1010851C2 - Barrier for regulating water flow along e.g. river, drain, ditch or canal, has reduced play between cog wheels and teeth in the mechanism used to move gate when this gate is open - Google Patents

Abstract

When the flow opening is blocked, the play between the cog wheels (8, 9) and teeth (7) is less than the play between these two bodies when the opening is unblocked. A device for regulating water flow, especially in a water course, drain, ditch or canal, comprises a barrier (2) with at least one opening for the water to flow through, and at least one gate (3) joined to the barrier by hinges (4) so that it can be swung between a position where it blocks the flow opening and a position where this opening is unblocked. Teeth on the gate engage with cog wheels secured to the barrier and are used to move the hinges. When the flow opening is blocked, the play between the cog wheels and teeth is less than the play between these two bodies when the opening is unblocked. Independent claims are also included for (a) the gate, (b) barrier, and (c) a water flow control method using this device.

Description

DEVICE AND METHOD FOR CONTROLLING A WATER FLOW

The present invention relates to an apparatus and method for controlling a water flow, in particular in a watercourse, sewer pipe, ditch or channel.

For retaining or allowing a water flow into a watercourse and the like, devices are known which comprise a thrust body arranged in the water flow, which thrust body is provided with at least one through-flow opening. This flow opening can be closed or released with the aid of a valve. It is known to arrange this valve with hinges on the thrust body, so that the valve member is pivotable between a position closing the flow opening and a position releasing the flow opening. Gear racks are arranged on the valve, while pinion means engageable in the rack are provided on the thrust body. By actuating the pinion means, the valve is turned up or down to close or release the flow opening, respectively.

Such known devices have the advantage of easy operability and simplicity of construction. However, the known device has a number of drawbacks.

In the known device the thrust of the water flow is completely absorbed by the teeth of the pinion means and the rack means. In order to absorb the thrust without damaging the (ends of the) teeth, the play between the gear means and the pinion means must be minimal. However, due to temperature changes occurring in the environment, the material of the device expands or shrinks. Therefore, in order to enable operation of the device under all temperatures occurring in the environment, the clearance between the pinion means and the rack means must be quite large, so that variations as a result of expansion or contraction of the device 5 and in particular the valve are taken care of. A drawback of the known device is that different requirements are imposed on the required amount of play between the pinion means and the rack means.

The object of the present invention is to overcome this drawback. An apparatus is therefore provided in which position in the flow opening closing position the clearance between the pinion means and the rack means is kept at substantially the same temperature as in the flow opening releasing position. In the position of the flow opening, the thrust of the water against the valve is greatest, so that the play must be as small as possible in order to avoid damage to the teeth. In the flow-opening opening position, the thrust of the water flow 20 is smaller, so that a larger clearance is sufficient. Moreover, in the closing position, the temperature of the valve due to the greater height of the water flow will generally be lower than in the releasing position, where the water flow has a lower height level. According to the invention, there is therefore provided a device which on the one hand prevents damage due to the high thrust of the water in the closing position, and moreover prevents damage as a result of expansion of the material of the valve, in particular in the position releasing the flow opening.

According to a preferred form of the invention, the valve member is built up from a closing plate and one or more upright side plates arranged on either side thereof, at least one of the side plates having a substantially quarter-circle arc-shaped end to which the rack and pinion means are arranged and wherein the hinge means are outside the circle center are applied. Due to the hinge means outside the circle center 1 Π j Π 'r i • ν ’I ^ V ,. i! When the valve member is pivoted, the play between the pinion means and the rack means will vary. According to a preferred form of the invention, the pinion means are attached to the thrust body at a position substantially above the rack means and the hinge means are attached to the valve member at a position substantially above the center of the circle. This positioning of the pinion means and the hinge means ensures that the clearance between the pinion means and the rack means in the position closing the through-flow opening is smaller than in the position releasing the through-flow opening.

According to another embodiment of the invention, the valve member is built up from a closing plate and one or more upright side plates arranged on either side thereof, at least one of the side plates having an arcuate end to which the rack means are arranged and in which the arcuate shape The end is bent such that in the through-flow opening-releasing position the distance between the rack and pinion means is greater than in the position closing off the through-opening.

In a further preferred form of the invention, from the distance between on the one hand the arcuate end or the gear rack means and on the other hand the hinge means, ie the radius of curvature of the arcuate end, decreases from the side of the closing plate to the opposite side.

According to a further preferred form of the invention, the difference in clearance is substantially equal to the expansion distance over which the valve member expands with increasing temperature. According to a further preferred form, the difference in clearance is about 1% of the height of the valve member. With temperature differences of approximately 50 ° C occurring in practice, the expansion coefficient for commonly used materials is approximately 1%.

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According to a further preferred form of the invention, drive means are arranged on the pinion means for driving the pinion means, which drive means preferably comprise an electric motor. Here, the water flow can be controlled in a simple manner and possibly remotely.

According to a preferred form, the side plates, the cover plate, the rack ends and / or the pinion means are made of plastic, preferably high-density polyethylene. These materials are very durable and lightweight.

Further advantages, features and details of the invention will be elucidated with reference to the figures, in which: figure 1 shows a perspective view of a preferred form of a valve weir according to the invention; figure 2 shows a cross section A-A of a valve weir in open position; and figure 3 shows a cross section A-A of a valve weir in closed position.

Figure 1 shows a channel which is filled with water W. A valve weir 1 is arranged transverse to the longitudinal direction of the channel. The valve weir 1 has the function of controlling the flow of the water W through the channel 25. By controlling the flow of the water W through the valve weir 1, the water level on both sides of the valve weir can be influenced.

The valve weir 1 comprises a concrete weir 2 in which a rectangular flow opening is arranged. In order to control the water flow through this through-flow opening, a valve is provided which is pivotable between a first position closing the through-flow opening and a second position releasing the through-flow opening. The valve comprises a closing plate 3 which is provided on both sides with side plates or sectors 5 and 6. The sectors 5 and 6 and / or the cover plate 3 are provided with hinges 4, which hinges 4 are attached to the thrust body 2. As a result it is possible to hinge the two sectors 5, 6 and 1010851-5 the closing plate 3 between the two aforementioned positions.

Both sectors 5 and 6 are approximately 3 cm thick plates, which are essentially in the shape of a quarter circle 5. The closing plate 3 is arranged along one of the straight ends of a sector 5, 6 and has an arbitrary width. In this exemplary embodiment, the width is 50-200 cm. The radius of the circle is chosen to be smaller than the height of the through-flow opening in the thrust body 2. By moving the cover plate 3 up or down, the sectors sliding along the walls of the through-flow opening, the through-flow opening in the thrust body 2 is respectively to close and release.

The valve is operated as follows. About 3 cm high teeth 7 are formed at the ends of the sectors 5 and 6, for example by milling the base material of the sectors 5, 6 in a simple manner.

These teeth 7 can be integrally formed with the sectors 5 and 20. A rack can also be arranged against the arcuate end of a sector, the material of the rack being identical to or different from the material of the sector. A fastening part 11 is further attached to the weir 2 by means of screws. In the fastening part 11, a shaft 10 is rotatably mounted, on which shaft 10 two pinions 8 and 9 are arranged. The teeth 12 of the pinions 8 and 9 engage with the teeth 7 of the right sector 5 and the left sector 6, respectively. Rotation 30 of the shaft 10 causes a rotational movement of the pinions 8 and 9, which rotational movement via the teeth 7 to the sectors 5 and 6 is converted into a hinge movement of the valve. Rotation of the shaft 9 can be effected by means of an electric motor 13 which engages on the shaft 9. As an alternative to this, the shaft 9 can also be driven manually, for instance by means of a crank mechanism (not shown).

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In known valve weirs, the hinge means 4 are provided in the circular center of the sectors 5 and 6. As a result, the play between (the teeth 12 of) the pinions 8 and 9 and (the teeth 7 of) the sectors 5 and 6 is reduced during hinges of the valve are substantially constant.

However, with temperature differences of the environment, sectors 5 and 6 will expand, causing the valve to jam in pinions 8 and 9 at high temperatures.

In other known valve weirs, therefore, the play between the pinions 8 and 9 and the sectors 5 and 6 is increased, so that even when the sectors 5 and 6 are expanded, the valve does not jam when actuated. In this case, however, when the valve is closed, the entire thrust of the water W will be transferred via the sealing plate 3 to the ends of the teeth 7 of the sectors 5 and 6 and the ends of the teeth 12 of the pinions 8 and 9. With increasing play between the pinions 8 and 9 and the sectors 5 and 6, the force on teeth 12 and 7 thereof will be distributed over an increasingly smaller tooth surface and the point of application of this force will continue to move towards the ends of the teeth 12 and 7. In many cases damage to one or more teeth occurs, as a result of which the functioning of the valve weir is adversely affected. It is even possible for teeth to break off, as a result of which the valve undesirably ends up in a position releasing the flow opening, with all the ensuing consequences.

As can be seen from the figures, according to a preferred form of the invention, the hinges 4 are not placed in the circle center of the sectors 5 or 6, but in the releasing position above them. By moving the hinge point of sectors 5 and 6, the problem is largely solved.

In the open position 35 of the valve shown in figure 2, wherein the closing plate 3 is in a horizontal position, the situation is then as follows.

The height H of the water W on the upstream side of the valve weir 1 is small. In the drawn situation, it is 1010851.

7 f, for example, the water height only slightly higher than the bottom of the through-flow opening. The force on the teeth 7 of the sectors and the teeth 12 of the pinions 8 and 9 is correspondingly small. Since sectors 5 and 6 are to a large extent above the downstream water W, sectors 5 and 6 are exposed to maximum solar radiation, with a maximum expansion of sectors 5 and 6 being expected.

The distance between the hinges 4 and the ends of the sectors 5 and 6 directly above them is equal to the radius of the circle of the sectors 5 and 6 minus the eccentricity of the hinges 4, i.e. minus the distance over which the hinge is moved out of the circle center. In the exemplary embodiment shown in Figure 2, the said distance is 0.99 R, where R is the radius of the circle. The spacing or clearance between the pinions 8 and 9 on the other hand, the sectors 5 and 6 on the other hand, is chosen such that an expansion of approximately 1%, i.e. from 0.99 R to approximately 1.0 R, as a result of an increase in temperature possible without damaging the teeth 12 and 7 of the pinions 8, 9 and the sectors 5, 6, respectively. If there is no temperature increase, no expansion of sectors 5, 25 and 6 takes place and the clearance is thus approximately 0.01 R. Although in this case the clearance is quite large, this does not present any problems since the forces on the teeth 12 and 7 of the pinions 8, 9 and sectors 5, 6, respectively, are small due to the small water height.

In figure 3 the valve is shown in closed position, in this situation, where the closing plate 3 is in a substantially vertical position, the height H of the water W on the upstream side of the valve weir 1 is large, ie that the retaining height of the damper is maximum. As a result, the force on the teeth 12 and 7 is maximum. In this situation, however, the sectors 5, 6 are almost entirely located in the upstream water W, so that the expansion of the 1010351.t 8 · sectors 5, 6 is minimal. In this case, therefore, less expansion of sectors 5 and 6 has to be taken into account. Due to the eccentric arrangement of the hinges 4, in the closed position of the valve, the distance between the hinges 4 and the end directly above it is of the sectors 5 and 6 equal to the radius of the circle R. As a result, there is an optimal fit between the teeth 7 of the sectors 5 and 6 and the teeth 12 of the pinions 8 and 9 on the one hand. maximum thrust of the water can be absorbed, while damage to teeth 12 and 7 is avoided.

In another embodiment of the invention, not shown, the sectors 5 and 6 do not form a quarter sector of a circle, but a quarter sector of a flattened circle, while the hinges are provided essentially in the center of the circle. In other words, the ends of the sectors are curved such that the radius of curvature thereof is not constant, but decreases from the side of the cover plate to the opposite side. By this special shape of the ends of the sectors, it is ensured, in a manner similar to that stated above, that at the same temperature, the play in the closed position is minimal and maximum in the open position. In the open position of the valve, this creates space for the sectors to expand without the sectors being able to get stuck.

In the exemplary embodiments shown, the closing plate 3, the sectors 5 and 6 (including the teeth 7 thereof) and the pinions 8 (including the teeth 12 thereof) are made of plastic, for example high-density polyethylene. For this material, the expansion coefficient at a temperature difference of 50 °, which is a value occurring in practice, is about 1%. In this case, the eccentricity of the hinges 4 should be about 1% of the radius of the circle to ensure proper operation of the valve weir.

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In general, at an expansion of x%, the eccentricity of the hinges should be x / 100 times the radius of the circle, in order to obtain optimal operation of the valve weir.

The present invention is not limited to the above-described preferred embodiments thereof; the requested rights are defined by the following claims, within the scope of which many modifications are conceivable.

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Claims (14)

Device for controlling a water flow, in particular in a watercourse, sewer pipe, ditch or channel, comprising: - a propellant to be arranged in the water flow, which is provided with at least one through-flow opening; - at least one valve member arranged with hinging means on the thrust body, wherein the valve member is pivotable between a position closing the through-flow opening 10 and a position releasing the through-flow opening and wherein rack elements are arranged on the valve member; pinion means attached to the thrust body which engage the rack means of the valve member and drive the hinge movement of the valve member; wherein in the position closing the flow-through opening the clearance between the pinion means and rack-and-pinion means at substantially the same temperature is smaller than in the position releasing the flow-through opening. 2. Device as claimed in claim 1, wherein the valve member is built up from a closing plate and one or more upright side plates arranged on either side thereof, at least one of the side plates having a quarter-circle arc-shaped end to which the rack and pinion means are arranged, and wherein the hinge means are outside the circle center. 3. Device according to claim 2, wherein the pinion means are attached to the thrust body at a position substantially above the rack means and the hinge means are attached to the valve member at a position above the center of the circle. ; 1 0 1 08 5 1,. 11; 4. Device as claimed in claim 1, wherein the valve member is built up from a plate part and one or more upright cheeks arranged on either side thereof, at least one of the cheeks having an arcuate end to which the rack means are arranged, and wherein the arcuate shape the end is bent such that in the position releasing the flow-through opening the distance between the rack and pinion means is greater than in the position closing the flow-through opening 10. The device of claim 4, wherein the radius of curvature of the arcuate end decreases from the side of the sheet member to the opposite side. Device according to any one of the preceding claims, wherein the difference in clearance is substantially equal to the expansion distance over which the valve member expands with increasing temperature. 7. Device according to claim 6, wherein the difference in clearance is about 1% of the height of the valve member. 8. Device according to at least one of the preceding claims, wherein drive means are arranged on the pinion means for driving the pinion means. Device as claimed in claim 8, wherein the drive means comprise an electric motor. 10. Device according to at least one of the preceding claims, wherein the cheeks, the rack and pinion means and / or the pinion means are made of plastic. 10: The device of claim 10, wherein the plastic is high density polyethylene. 12. Valve member for controlling a water flow, in particular in a watercourse, sewer pipe, ditch or channel, evidently intended for a device according to any one of the preceding claims. 1010351, 12 ' Thrust body which is provided with a through-flow opening and is evidently intended for a device according to any one of claims 1-11. 14. Method for controlling a water flow, in particular in a watercourse, sewer pipe, ditch or channel, wherein the device according to any one of claims 1-11 is used. 1 0 1 08 5 1.,