SU765471A1 - Apparatus for pulsed flushing of debris-trapping grates of submerged water intakes - Google Patents

Description

(54) DEVICE OF PULSE WASHING OF SHORT-CONTAINING LATTICES OF FLOODED WATER CLEARANCE The invention relates to hydrophilic construction and water supply, namely to flooded water receivers. A device for pulsed washing of trash grids in flooded receivers, containing a column at the end of a gravity pipe before the valve, a vacuum pump and a mechanical valve for resetting the vacuum, is known. A disadvantage of the known device is the need to stop water from the gravity pipe when the valve is closed on it before a program. , which leads to a decrease in the reliability of the water intake. It is also difficult to automate the process of applying a pressure wave pulse to the lattice by releasing the vacuum in the column with a mechanical shutter. The purpose of the invention is to increase the reliability of the operation of the device by automating the supply of a flushing pulse and ensuring uninterrupted water intake. This goal is achieved by the fact that the column is made in the form of a siphon equipped with jumpers with valves and a hydraulic valve for vacuum relief, made in the form of an i-shaped pipe equipped in the lower part with a nozzle with an opening for water entry from the shore well, and connected at one end to the upper part of the siphon. The drawing schematically shows a device for pulse-washing of trash grids of a flooded water receiver, general view. The impulse washing device of the trash grids 1 of the receiving chamber 2 of the flooded water intake 3 is a siphon made in the form of two pipes — ascending 4 and descending 5, installed vertically at the end of the gravity flow line 6 on opposite sides of the valve 7. Ascending 4 and descending 5 the pipes are interconnected by bridges with a gate valve:; and 8 and 9, located at different levels. A vacuum pump 11, a mechanical shutter 12 and a hydraulic valve 13 for vacuum relief are connected to the top of the siphon through the valve 10. The hydraulic valve 13 is made as installed

vertically with an i-shaped pipe connected at one end to the upper part of the siphon, and the other end has an outlet to the atmosphere through the valve 14. At the lower part of this pipe there is an eyelid 15 with a hole for free entry of water from the coastal well 16. And a hydraulic pipe The valve has a jumper with a valve 17. The installation works as follows.

We take water when the valve is open 7 through the openings of the trash grids 1 is fed to the receiving chamber 2 of the flooded water intake 3 and diverted to the coastal well 16 along the gravity flow line b

Water intake via the gravity flow line is realized through the siphon of the pulse Device. To do this, open 8 siphons, valves 14 and 7 of hydraulic valve 13, turn on the VACUUM pump 11, open its valve 10 and charge the siphon, by raising the water level to the top of the siphon by forming a vacuum in it to close the valve 7 b, and because of the existing difference in water levels in the river (calculated level) and onshore well (Vcj), water flows to the shore well through a siphon. At the same time, the water level in the onshore well somewhat decreases by the value of head loss E siphon (doUb). After charging the siphon, the valve K) is closed, Turning off, the vacuum pump from the system.

When the grids are clogged, forty one or one depth (the next water level difference in the river and the onshore well will increase. When the water level in the bank of the coastal well drops below the level, the jumper with valve 17 will be connected to the atmosphere and the vacuum will drop. By the ascending branch 4 of the siphon and the self-flowing line b under the pressure of the liquid column in the siphon, a pressure wave (impulse) washes through the grids. At a backward wave, the pressure rises when the water level in the ascending branch 4 of the siphon rises, opening the valve 10, connects The acum pump 11 simultaneously closes the valve of the hydraulic valve 14. Since the water level in the onshore well has not yet reached the orifice 15 of the hydraulic valve, the siphon is recharged due to the vacuum formed in it. After the water level in the river and onshore well is restored its siphon of the device is opened by the valve of the hydraulic clathine, and the valve of the vacuum pump 10 is closed. When the grids 1 are clogged again with debris or sludge, the process of automatic vacuum relief is hydraulic Skim gate and subjecting the trash screen wave is repeated pressures.

At low levels of water in the river, the siphon of the device works through the lower jumper with valve 9 with valve 17 closed,

After stopping shugohode. the vacuum pump is turned off, the valve 7 is opened and the siphon of the impulse device is turned off, and water flows directly through the gravity pipe directly to the shore well.

The proposed device allows automating the process of supplying a pulse of pressure waves to the vacuum retention grids in the column by a hydraulic valve without interrupting water intake, increases the efficiency of washing and thus ensures more reliable operation of the water intake as a whole.

Claims (1)

Invention Formula 1, apparatus I1-4pulsnoy washing trash reyetok flooded water intakes, comprising a water inlet sorouderzhivakvdey grating downpipe and column mounted at its end, vacuum pump, a mechanical shutter for discharge of the vacuum and the shore well, about tlichayuschees in that, in order to increase reliability of devices to automate the supply of flushing impulse and provide-; An uninterrupted water intake column is made in the form of a siphon equipped with jumpers with valves and a hydraulic vacuum relief valve. 2, the apparatus according to claim 1, characterized in that the hydraulic valve is made in the form of a U-shaped pipe provided with. bottom of its part with a hole to enter the water from the shore well, and is connected at one end to the top of the siphon. Sources of information taken into account in the examination 1 Water intake facilities for water supply from surface sources. Under the editorship, Mikhailov K.A. and Obrazovskogo A.S., M., Stroyizdat, 1976, p. 18, fig. 13, with 34-37. . Rksch H. . i. . -y - f / f I Y