NO177276B - Device for removing particles from the bottom of the water reservoir and other waterways - Google Patents

Description

The present invention relates to a device for removing particles from the bottom

of water reservoirs and other waterways, as stated in the introduction to patent claim 1.

The invention can be used when removing sediments from sediment-carrying rivers,

e.g. to influence bottom processes in the river, or to utilize these sediments for various purposes, in connection with agriculture, sand and gravel production, filling materials for land improvement, mineral exploration, measurement of sediment transport in rivers, etc.

The invention is particularly intended for use with reservoirs in connected waterways

for constructions such as power plants, irrigation systems and ordinary water supply systems.

The function of the reservoir is to regulate the natural inflow into the river so that one has

water available when users need it. In rivers with a large sediment flow, it is difficult to maintain a limited regulation volume for use in periods of low water flow. The invention can be used to regenerate this regulation volume after it has been completely or partially filled with river-transported sediments.

Existing systems for the removal of sedimented masses in reservoirs are based

either by draining so as to generate a "river" with sufficient transport capacity to erode the sedimented masses, or by sucking, scraping or digging up the bottom masses using different dredging techniques.

The largest and heaviest particles will first settle near the river's inlet to the reservoir.

The largest particles must therefore be transported through the entire reservoir by

draining and flushing. Draining and flushing must be carried out when there is plenty of water, but not too much water as you will then not be able to lower the water level behind the dam and thus generate sufficient speed to erode the bottom masses.

The problem of removing sedimented masses is largely solved with a device as stated in Norwegian patent document no. 165 851, from the same applicant. In NO 165 851, a device is described in which a flushing channel is placed under a precipitation basin which is connected to the precipitation basin along its entire length by a longitudinal slit. The slot can be successively opened and closed along the entire length of the precipitation basin so that the entire flushing capacity of the flushing channel is moved along the bottom of the precipitation basin, and it will be concentrated on the open part of the flushing channel just upstream of the closed part of the slit. A flexible floating body, e.g. a flexible pipe, can be used to open and close the gap between the precipitation basin and the flush channel. The floating body can be loaded and unloaded by filling and draining gas and/or liquid from and to it. It will thus be possible to move the extraction point along the bottom of the precipitation basin.

The device shown in NO 165 851 must be built into the bottom of the precipitation basin either in new construction or in case of dry laying and conversion. It is a stationary device, which cannot be removed after use or before periods of flooding, and which requires draining and drying for maintenance.

It is therefore a main purpose of the present invention to provide a device which can be used in old as well as new installations, and which effectively removes particles which have been deposited or which are otherwise present at the bottom of the pool.

The object of the invention is solved with a device with features as stated in the characterizing part of patent claim 1. Further features will appear from the associated independent claims.

In what follows, the invention will be described in more detail using examples of execution, and with reference to the attached drawings, there

fig. 1 shows a dam in a sediment-carrying river where a precipitation basin has been drawn in accordance with known technology, and a device in accordance with the present invention,

fig. 2 shows a longitudinal section through the pool in fig. 1, where a first, principle embodiment of the present invention is seen in longitudinal section,

fig. 3 shows one of the elements in figure 2 in cross-section with fiyte elements drawn in,

fig. 4 shows a longitudinal section of a second, preferred embodiment of the present invention,

fig. 5 shows one of the elements in figure 4 in side view, and

fig. 6 shows one of the elements in figure 4 in cross-section, with fiyte elements drawn in.

Referring first to FIG. 1 shows a water reservoir 1 in connection with a dam 2. In the water reservoir sediments 3 which are transported into the reservoir by the river are deposited and they are stored at the bottom of the river. After a while, the sediments 3 will cause a problem as they reduce the volume of water needed from the regulation standard. With reference number 4, a precipitation basin of known technique is named, e.g. as shown in NO 165 851. From this, sand and flushing water go back to the river downstream of the dam, while purified water goes to a power station, an irrigation system, or another purpose.

In fig. 1 also shows an example of a device in accordance with the present invention, generally named 7. This is connected just upstream of the passage in the dam 2 and is therefore rotatable in the horizontal plane and can thereby cover large parts of the reservoir. This is shown with reference number 7'. The device will be able to be easily moved and connected to several places along the pond so that it can cover the entire reservoir if desired.

Referring further to fig. 2 and 3, a principle embodiment of a flushing tube 7 in accordance with the present invention is seen. The flush pipe 7 is designed as a pipe comprising several elements 10. In principle, the flush pipe 7 can be made up of a pipe that is cut open at regular intervals, but not cut off, and thus the elements 10 are obtained as a piece of pipe with open ends and the joint to the neighboring elements at the part of the pipe cross-section that has not been cut. The joint mechanism can be obtained in several ways. At the downstream end, the flushing pipe 7 is connected to an outlet pipe 14. At the upstream end, the flushing pipe is closed, however, a small opening has been placed to be able to release gases that develop in the sediment and are released during the flushing. The elements 10 are connected to two or more floating/sinking bodies 17 which are designed as flexible hoses or tubes that can be filled with and emptied of water and/or air through an operating tube 26. The floating bodies 17 run through a guide 27 on each side of the flush pipe element 10. The floating bodies 17 are attached only to the end elements 28 and 29. The floating bodies 17 are to a certain extent elastic in the longitudinal direction and are stretched somewhat so that the elements close against each other when they are not subjected to a bending moment in the vertical plane. The elements 10 are thus articulated so that the joint point lies at the upper edge when the flush pipe 7 is bent in the suction area 13 near the sediments and at the lower edge when the flush pipe 7 is bent in the surface position.

The elements can also be equipped with sleeves 30 made of e.g. rubber which seal and ensure that water and sediments are only sucked in from below as illustrated by arrows and reference number 13 in figure 2.

The floating elements 17 are attached at the upstream end to a raft 18, or similar, so that air can flow in and out of them as the floating elements 17 are respectively drained and filled with water through the operating tube 26.

When the floats have been drained of water, the flush pipe 7 will bend due to the buoyant forces. This will result in openings between two neighboring elements 10 as shown with reference number 13. As the outlet 14 of the flush pipe 7 is lower than the water surface 5 upstream of the dam 2, or has a lower potential pressure provided by e.g. pumping, this will create a negative pressure which ensures that water and sediments 3 are sucked in through the openings 13 and flushed out through the outlet 14 of the flush pipe.

By operating the floating bodies by slowly filling them with water, the openings 13 can be moved into the reservoir as the sediments 3 are flushed out. This extraction area can thus be moved along the entire length of the flush pipe 7.

The elements 10 are attached to a float 6 using rope 31 or similar which locks the elements at a desired depth during the lowering of the flush pipe 7.

By turning the flush pipe 7 in the horizontal plane about the connection point in the pond 2, it will be possible to cover the desired area in the reservoir as indicated in figure 1 with 7\

In fig. 4, 5 and 6 show a preferred embodiment of the present invention. The device 7 works in principle in the same way as the one shown in fig. 2 and 3. An element 10 comprises a tubular body 11 which is open at both ends. A joint 12 connects an element with the neighboring elements and seals for tightening between the elements. A downwardly directed pipe connection 18 communicates with the pipe connection 11 and has a smaller cross-sectional area than this. The pipe spigot 18 has a kink and forms an end part 19 which is substantially perpendicular to the longitudinal direction of the pipe spigot 11, and which has an opening 20. In the opening 20, the cross-section is preferably somewhat narrowed in.

At the downstream end, the element 10 has a plate or similar 21 on each side of the pipe connection 11, which is equipped in its lower area with a sealing member 22. This can e.g. be a plate of rubber. The sealing member 22 seals the opening 20 on the downstream neighboring element's pipe connection 18 when the flushing pipe 7 and the subsequent one lie in line or they are bent in the surface position, but opens when it is bent outwards. In connection with the link 12, a flexible rubber sleeve 23 is arranged. Two neighboring elements can swing an angle between them which corresponds to the sum of two angles 24 and 25 at one, respectively. the other end of the element 10. These angles 24 and 25 are preferably equal, and are preferably in the range 5 to 10°.

In fig. 5, the floating/sinking bodies are not drawn in. In fig. 6, an element 10 is seen in cross-

section, and with floating/sinking bodies 17 in one possible embodiment. The floating/sinking bodies 17 are designed as two flexible hoses 17 which extend the entire length of the flush pipe 7.

Means for supply and drainage for air and water are not shown in the figure, but this can be arranged similarly to what is shown in fig. 2.

The present invention shall be described below by its functional principle and properties. With the aid of the flushing pipe 7, a suction area can be moved in a pool so that sedimented particles can be sucked into a flushing pipe through a small number of openings. Buoyancy is used to move the extraction area. The device is not stationary,

and it does not require extensive engineering constructions inside the reservoir. This means that it can also be used in previously built reservoirs.

Flushing out sediments is carried out without draining the reservoir with the resulting

loss of water and production. The flushing process will be able to be carried out at times of the year when there is no shortage of water, so that the water loss is small and the reservoir is used when the water flow is small (dry season), and the value of the reservoir is high. It will be possible to achieve a high concentration of sediments in the flush water. The invention is driven only by gravitational forces and a small amount of energy is required to drive the flushing process. The plant is easy to operate and easy to monitor. The flushing process can be reversed and repeated at any point in the process.

The concept represents a system for removing sedimented particles in reservoirs

in rivers with large sediment flow. The large sediment transport has long ensured that there are no natural regulating reservoirs such as lakes in the waterways and artificial reservoirs will have a short lifespan as they will also be filled up eventually. On

because of this, large facilities are now preferred, as these do not fill up as quickly as smaller and more gentle reservoirs. With the present invention, it is possible to maintain the regulation capacity in small and medium-sized reservoirs and prevent them from filling up with sediments. River power plants are traditionally not built with any significant reservoir in heavily sediment-carrying rivers, as it becomes impossible to

maintain the regulation volume over a certain period of time. On the other hand, the value of a small 24-hour reservoir becomes greater the greater the general sediment transport within a supply network, as it is impossible to store water. One is therefore at the mercy of the flow of water in the river at all times. The consequence is that a

dimension the power plant for a minimum water flow and that it must coordinate with other energy sources. This means that only a fraction of the energy potential in the river is utilized, while at the same time one must invest in supplementary energy supply systems if one is to maintain a high level of regularity in the energy supply. The alternative to this is very large reservoirs that are not filled up with sediments during the project's economic lifetime, but with associated costs and consequences for the local population and the environment.

There is a great need for rehabilitation of existing reservoirs by both hydropower and irrigation systems, but as far as is known there is no major

activity in this area and there are no good solutions. Today there are many so-called cascade power plants (several river power plants in series along a river). Today, it is tried as best as possible to flush down the reservoirs by draining the reservoir, but with the result that the sand that can be flushed out ends up in the next intake reservoir. With the help of the present invention, it will be possible to take care of the sediments in the upper reservoir, while at the same time the masses will be able to be used as a resource. One has also protected the other magazines downstream.

The invention will also be able to be used in connection with irrigation projects and water supply systems. The potential for agricultural purposes seems to be particularly large in connection with the lower regime in heavily sediment-carrying rivers, where it can contribute to stabilizing rivers, reducing the risk of flooding and securing old and extracting new agricultural land. This will open the way for multiple uses of irrigation facilities, where water for irrigation is purified sufficiently and the washed-out masses are used to raise downstream areas along the river sufficiently above the groundwater level, so that agriculture can be practised.

Claims (11)

1. Device for removing particles from the bottom of a water reservoir (1) or other waterways, comprising an elongated body (7) which at one end is connected to an outlet (14) for water and bottom particles, which outlet (14) has a lower hydrostatic pressure than the water reservoir, the elongate body (7) being connected for most of its length to at least one floating/sinking body (17) in the form of a flexible tube arranged to be filled with water and/or air to bring the elongated body (7) in a meandering movement, characterized in that the elongated body (7) is tubular and comprises a plurality of interconnected elements (10) which form an inlet opening (13) between the body (7) and the surroundings when the body (7) is bent in the vertical plane. 2. Device in accordance with claim 1, characterized in that the elements (10) are interconnected for bending in the vertical plane. 3. Device in accordance with claim 1, characterized in that the body (7) consists of a tube which is radially cut at regular intervals, the cut forming the inlet opening (13) and the remainder of the pipe circumference forming the joint (12). 4. Device in accordance with requirements 1-3, characterized in that the inlet opening (13) of the elements (10) opens when the body (7) bends so that it forms an arc in the vertical plane with the outside towards the bottom of the reservoir. 5. Device in accordance with requirements 1-4, characterized in that the body (7) is connected to at least one floating/sinking body (17) which at the upstream end is kept afloat in or above the surface of the water (5) by a raft (16), a vessel or the like. 6. Device in accordance with claims 1-5, characterized in that each element (10)*comprises a tubular body (11) which is open at both ends and is equipped with a pipe socket (18), which preferably forms an angle of approximately 45° to the longitudinal direction of the element (10), and which has a cross-sectional area that is smaller than the cross-sectional area of the element (10) itself. 7. Device in accordance with claim 6, lizrckterized in that the pipe end (18) has a kink, so that the lower part (19) of the pipe end (18) is substantially perpendicular to the longitudinal direction of the element (10). 8. Device in accordance with claims 6-7, characterized in that an opening (20) on the pipe end (18) has a narrowing in relation to the cross-sectional area of the pipe end (18). 9. Device in accordance with claims 1-8, characterized in that a rubber sleeve (23) is arranged between the elements (10). 10. Device in accordance with claims 1-9, characterized in that each element (10) is equipped with a sealing member (22) which seals the inlet opening (20) of a neighboring element (10). 11. Device in accordance with claim 10, characterized in that the sealing member (22) consists of a tongue (22) made of rubber, which is attached to an arm (21) which projects from the element (10) on the same side as the pipe spigot (18).