HU202604B - Establishment for draining water through enbankment - Google Patents

Abstract

The installation has one or more suction nozzles for receiving the pump (s) and a part of the pump (s) for transporting the water raised by the pump (s). The essence of the invention is that the facility for conveying water raised by the pumps (2) consists of one or more, preferably open-surface, gravity resetting channels (9), which are in the area of the inlet end of the water with the suction shaft (1) or and with the water outflow end (11a). (Figure 1).

Description

FIELD OF THE INVENTION The present invention relates to an installation for transferring water through a embankment, a hydro-engineering structure.

In the field of water construction, especially in the water utilization, water management and water supply sectors, an increasing number of new pumping stations are needed, and the need to modernize and reconstruct existing pumping stations is becoming more and more frequent. In the field of agricultural water use, for example in Hungary, the reconstruction of existing water works is particularly urgent; and the inclusion of new areas in irrigation obviously involves the construction of new water abstraction facilities on both natural and artificial streams and reservoirs. In the field of inland drainage, it is necessary to upgrade existing pumping stations and to build new pumping stations to raise the main receiving water of inland sewers, large canals and backwaters, as the volume of inland waterways is increasing due to regional drainage interventions.

It is primarily due to the climatic and topographic features of temperate areas, such as Hungary, that in shallow areas, rainwater is collected by inland sewerage network during rainy periods, and water is pumped into receiving streams through inland pumping stations. In the case of dry climatic conditions, however, the irrigation water is pumped out of the streams via water extraction pumping stations and is also routed through a steel discharge pipe to the irrigation channel.

The inland pumping station is always located at the deepest point of the catchment area, so the receiving water stream is usually filled at this location, as are the reservoirs around the pumping station.

The pumping station includes a suction duct, pump suction manhole, discharge pipe, manhole and service facilities.

Currently, the charges in the area around the pumping station are crossed by pressure lines starting from the pump, which are located on the receiving side in a manhole. they end up in a damping pit. Since the location of the intersection of the filling and discharge pipe can be a source of danger for the protection of large water, it is generally necessary to install a shut-off device in the discharge pipe on both the pump side and the receiving side. The cost of investing in the crossing facilities - that is, the manifold and its fittings, the manhole, and the manhole and damper - can account for a very significant proportion, up to 30-40%, of the total cost of the pumping station. In addition to the very high investment cost, the ongoing maintenance costs of the pipelines also involve significant sums.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a hydraulic engineering structure for the passage of water through the embankment that does not require the use and costly maintenance of steel pressure pipes and fittings (e.g. shutoffs) that can be constructed at a high investment cost and can be operated with simple, low maintenance work. allows quick and cost-effective construction and installation of an artwork.

The invention is based on the discovery that in case of a significant difference in the water level to the suction side of the pumping station and the receiving water, the energy savings achieved by the pump effect are insignificant compared to the flow losses of the pipeline and its fittings, by pumping the water to the appropriate height economically, with less flow loss than the pressure line installation and at a significantly lower construction cost, the charge can be gravitationally transferred to the receiving surface with a free surface. The invention is further based on the discovery that a free-flowing water column raised to an appropriate height, namely above the flood protection or other safety level, is interrupted when pumping is completed, thereby preventing backflow from the reservoir or the swollen space behind the flood protection embankment. it would be necessary to install costly shut-off valves while complying with the relevant safety regulations.

On the basis of the above findings, the object of the present invention has been solved by the use of an installation - a hydroelectric object - which has one or more sumps for receiving their pumps and a part for transferring the water lifted by their pumps). The pumping station for transporting the water raised by one or more of its pumps) is formed by one or more gravity water supply channels, preferably open to the surface, which are connected to the sump or sumps in the region of the inlet end of the water and the outlet end of the water. Preferably, the energizing members are teeth and / or ribs projecting upward from the surface of the carriage. According to another advantageous feature of the invention, their pumps) are submersible propeller pumps (s) mounted in a vertical, top closed manhole,

In a preferred embodiment of the installation, there is a suction port (s) in front of the sump or sumps and an oblique rake (s), preferably movable rake (s), in front of the suction port (s). .

It may also be advantageous if the installation has temporary grooves and / or fittings in front of the sump or shafts and / or in front of the sinker for the flow of water, or / and has, for example, a flat-plate shut-off device.

In a further embodiment, the sump or sumps are connected to the water supply channel or channels by means of a pressure pipe. The manifold valves are provided from ^the water supply channel (s) to the sump (s) with a device to prevent backflow of water, such as a stopcock or / and end valve, or to the water supply channel (s) at the end or at the mouth. at their ends are provided with an upwardly extending pipe-like discharge section, the outlet of which is located above the highest water level in your waterway.

The invention will now be described in more detail with reference to the accompanying drawings, in which preferred embodiments of the hydroelectric object are provided. 1 is a vertical sectional view taken along line A-A in FIG. 2;

Figure 2 is a top plan view of the waterworks structure of Figure 1;

Fig. 3 shows another embodiment of the art object, a4. Figure 6 is a vertical sectional view taken along line?

Figure 4 is a top plan view of the waterworks structure of Figure 3.

1 and 2 have a sump 1 based on slit walls 17 and enclosed on the opposite side of the filler 30, i.e. the side where the inland water is collected. In front of the inlet 20 (Fig. 1) of the manhole 1 bounded by reinforced concrete sidewalls, cover and bottom plate, which is sized to the overall width and height of the manhole 1, an inclined rake 16 is provided which is divided. In the direction indicated by the arrows, the water flow has a suction port 15 (open port) which is open in front of the sump 1 and extends into the inlet 20 of the sump 1 and is of the same width. The guardrails extending transverse to the suction channel 15 and to the upper end of the rake 16 are designated by reference numeral 29.

Underneath the upper end of the inclined rake 16 is also a transverse - self-known -18 debris ejector. In the vertical ascending walls of the suction channel 15, grooves or fittings 8 are provided which provide temporary, preferably lining-beam closing. The operating water level in the suction channel 15 is _{denoted by the} reference letter ν _γ in Figure 1. Vertical partitions 21, 21a extend along the suction channel 15 and the sump 1 parallel to the direction of flow of the water indicated by the arrows a; the partition wall 21a extends over most of the entire hydro-engineering structure, as shown in FIG. The passage 23 is connected to the sump 1 as shown in FIG.

Pumps 2 submerged in the sump 1 and into its compartments 24 delimited by the dividing walls 21, 21a are located above, which are located in closed vertical shaft suspension manholes 3. At the upper end of the manholes 3 are arcuate pipe sections 3a, at the outer end of which are steel pressure pipes 5 (short pipe pieces) and to the latter there are fittings 4 which are located in the fitting shaft 25. The assembly blocks 4 comprise an assembly insert, a stopcock and a stopcock from the sump 1 to the receiver 19, otherwise known per se. The assembly blocks 4 have extensions 5b extending through openings 6 in the front wall of the assembly shaft 25 to the water supply channels 9 (the entire coupling assembly is divided into two parts by the aforementioned partition wall 21a). At the beginning of the water transport channels 9, in the reinforced concrete wall of the lateral boundary of the channel, there are grooves 8 and / or fittings suitable for creating temporary obstructions. Above the initial section of the water supply channels 9, a channel cover 10 is formed after the fitting shaft 25. The groove surface water transport channels 9, which are on both sides with vertical reinforced concrete walls and bounded by flat reinforced concrete bottoms below, are recessed into the embankment 18. A channel cover 10a covering the water passage 9 is connected to the enveloped crown 26 of the filling 18. The longitudinal vertical geometric median plane of the hydroelectric structure of the present invention is designated by the reference letter X and by the reference letter Y, respectively. In the continuation of the water transport channels 9, a sloping kinker 11 is formed which is energy-breaking

11a provided with elements such as ribs and / or teeth; they are transverse to the direction of flow indicated by the arrow.

A flat-plate shut-off device 7 is provided at the cantilever end 11 of the water supply channel 9, before the cantilever 11.

At the receiving end 19 of the carriage 11 there is formed a bottom bottom cover 12 to which a supporting stone spray 13 is connected. A watertight joint 14 is formed between the upper end 11 of the reinforced concrete slant and the side walls defining these structures.

Figures 3 and 4 have the same basic structure as those of Figures 1 and 2, therefore, the already described structural parts are designated by the reference numerals already used. The difference is that a steel discharge pipe branch is perpendicular to the manhole pipes 3, to which a steel discharge pipe 5 is connected by inserting a mounting piece 4a, the end of which is bent 90 * upwards through the opening 6 in the reinforced concrete bottom plate of the water channels. that is, the pipe-like spout 5a has a vertical upper end portion, the upper edge of which is above the operating water level. Each pressure pipe 5 comprises a water flow meter 31 in the section between the outlet and the mounting insert 4a. A load distribution plate 28 extends above the pressure pipes 5. The channel cover 10 extending beyond the enveloped crown 26 of the embankment is made up of prefabricated reinforced concrete elements in this embodiment.

With the help of the waterworks structure of Figures 1 and 2, water is led through the embankment as follows:

the waters coming from the catchment area are discharged into the sump 15 and from there into the reinforced concrete sump 1, from which the steel shaft 3 is propelled with a perforated suction pipe 2 lifting the connecting reinforced concrete into water transport channels 9 in which the inflated water flows under gravity to the recipient 19. In the event of a power failure or a pump shutdown, the valve block 4a or end valve of the valve block 4a, which is connected to the pressure pipe 5, prevents the return of already raised water to the sump 1. The flow of water flowing down the All-Killer is slowed down by the energy-breaking elements 11a, such as energy-breaking ribs or teeth, absorbing the energy of the flow, but also, of course, the support 13 is protected against leaching. All-in, by the way, as shown in FIG.

Since the dam 30 has a flood protection function, i.e. the water supply channels 9 of the construction of the invention intersect the flood protection barrier, the suction duct 15 has a shut-off barrier or electrically operated industrial sluice and a flood-relief damper 7 safety.

The channel cover 10 is formed with adequate bearing capacity, preferably of reinforced concrete, for transporting on the embankment 30 and for pumping and periodically repairing the pumps 2 and, of course, also the channel cover 10a for vehicle transport, which is also preferably reinforced concrete structure (see Figure 3). As can be seen in Figures 1 and 2, Fig

EN 202 604 Β flat-plate shut-off device - that is, one of the shut-off devices required for flood protection is installed on the receiving side 19 of the channel structure of the channel cover.

3 and 4 differs essentially from that described above in that the water pumped from the sump 1 flows through the pipe-like drainage pipe sections 5a into the open-sited water supply channels 9. Since the upper end of the extension pipe section 5a is in a horizontal plane above the established maximum receiving water level, no shut-off fitting between the suspension manifold 3 and the water supply channels 9 is required, since the water from the receiving The outlet openings of the outgoing pipe sections 5, which are located in a horizontal plane, participate in the water supply with their entire surface during operation of the respective pumps 2. After the pumps 2 have been stopped, the water flow in both the suspension manholes 3, the discharge pipes 5 and the water supply channels 9 is stopped.

The advantage of the invention is that it requires only a minimal amount of the most costly means of water transfer on the embankment, the steel discharge pipe, and also saves costly barrier structures. As the operation of the facility also leads to cost savings, the whole solution is highly economical. At the same time, breaking the energy of flowing water, dampening the flow without closing valves, but with the same security as the closing valves. The invention provides the possibility of transferring water from various channels to the recipient via filling, but is also particularly advantageous for streams where the play of the receiving streams is minimal, since the difference in level is comparable to the hydraulic loss of the runner to be used.

Claims (8)

PATENT CLAIMS 1. An installation for passing water through a barrage having one or more sumps for receiving their pumps) and a part for transferring the water raised by their pumps), characterized in that one or more parts of the equipment for transferring the water raised by their pumps) (2) - preferably an open surface - gravity water supply channel (9) connected to the sump (1) or sumps in the region of the inlet end of the water and the outlet end (11) of the water outlet end having energy-breaking elements (11a). Device according to Claim 1, characterized in that the energy-breaking elements (11a) extend to the teeth and / or ribs (1 and Installation according to claim 1 or 2, characterized in that their pumps) (2) are submersible propeller pumps located in a vertical, top closed manhole (3). Figure 3). 4. An installation according to any one of claims 1 to 3, characterized in that the water flow direction (a) has a suction channel (15) in front of the sump (1) or sumps and an inclined rake (s) in front of the suction opening (1) or sumps. 16) - preferably have movable rake (s). 5. Installation according to any one of claims 1 to 3, characterized in that the grooves (8) and / or the grooves (8) and / or, in respect of the flow direction (a) of the water - in front of the sump (1) or sumps and / or there are fittings or / and, for example, the installation has a flat-plate shut-off device (7). 6. Installation according to any one of claims 1 to 3, characterized in that the sump (1) or sumps are connected by means of a pressure pipe (5) to the water supply channel (9) or channels. Installation according to claim 6, characterized in that the discharge pipe (s) (5) from the water supply channel (s) (9) to the sump (s) (1) are provided with an anti-return valve, such as a stopcock or / and is provided with an end flap (Fig. 1). Installation according to Claim 6, characterized in that the pressure pipes (5) at the end of the mouth of the water supply channel (s) are (9). at their ends they are provided with an upwardly extending pipe-like discharge section (5a), the outlet of which is located above the highest water level in the water supply channel (s) (9).