FI72955B - ANLAEGGNING FOER AVLOPPSVATTENBEHANDLING. - Google Patents

Description

This invention relates generally to wastewater treatment technology, and more particularly to wastewater treatment devices.

The device according to the invention can be used for the treatment of waste water in ships or buildings and structures which are not connected to the main waste water drainage lines.

Biosphere pollution has now become a problem of global concern. The discharge of waste into rivers, lakes and seas has a special place in the overall pollution of the biosphere. The increase in shipping has significantly increased the amount of ship-generated waste discharged into rivers, lakes and seas, which in turn has led to a number of measures taken by most countries in the world to prevent ships without wastewater treatment and sterilization units from entering their waters. According to the Convention for the Prevention of Marine Pollution by Waste and Other Substances, ships must be equipped with such purification and sterilization units. The modern shipbuilding industry provides ships with automatic wastewater treatment equipment. Much attention is therefore paid to the development of highly reliable and trouble-free on-board wastewater treatment and sterilization units. There are a large number of known wastewater treatment units applicable to ships under construction. However, as the Convention stipulates that both newly built and existing ships must be equipped with such waste water treatment units, this requirement raises the problem of equipping older ships, which normally have only limited capacity waste water tanks, with more modern waste water treatment systems. Such systems take up a lot of floor space and usually need to be installed separately from the ship's waste water tanks.

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A wastewater treatment device is widely used, comprising indicators on the upper and lower surfaces of the water in the on-board wastewater tank for switching the device on and off when corresponding signals are obtained from these indicators. The waste water tank also has a water intake unit, the end of which facing the incoming waste water stream is covered with a net arranged at right angles to the walls of the water intake unit housing and the waste water flow. A water intake pipe and a pipe for recirculating untreated water are arranged in the inner wall of the water intake unit. The water intake pipe is connected to the suction head of the circulation pump. The pressure head of the circulation pump is connected via a pressure line, a pressure tank and a constant flow pressure line to a flotation unit where the wastewater is treated. The pressure vessel is also connected to an untreated wastewater recycling pipe. An ejector is fitted in the pipeline connecting the wastewater recirculation pipe to the pressure tank, the purpose of which is to aerate the water flowing through the water intake pipe. The ejector, in turn, can be connected to the gas gas sections of the sludge collector and the purified water tank. A constant flow pressure line is usually a calibrated pipe of a predetermined length that ensures a predetermined flow rate of wastewater to the flotation unit.

A reagent such as FeCl 2 or Al 2 O 4 (O 2 O 2) is sprayed with special pumps to coagulate the contaminants in the effluent flowing through the pressure line.

The flotation unit comprises a tank in which the water is purified, a scraper for removing the foam formed during the treatment of the effluent and means for removing the purified water.

The flotation unit communicates with a sludge collector and a purified water tank having a sludge drain pump and a purified water drain pump, respectively. The device is further provided with a control block electrically connected to the indicators of the upper and lower surface of the circulating pump tree, the sludge discharge pump and the purified water discharge pump tree and the water tank.

3 72955

During operation of the device, the circulation pump draws wastewater from the housing of the water intake unit through the water intake pipe to transport it under overpressure to the pressure tank. In this case, the network of the water intake unit retains the large pieces of solids carried by the wastewater. An overpressure of approx. 2-3 ata is developed in the pressure vessel. Approximately 60% of the water in the pressure tank is forced back through the untreated water recirculation pipe into the housing of the wastewater intake unit. The ejector connected to the untreated wastewater recycling pipe aerates the water, whereby the water transported to the pressure tank contains a considerable amount of dissolved air. About 40% of the water is fed through a constant flow pressure line to the flotation unit. Because this line is made into a calibrated pipe, the flow rate through it is constant when the water pressure in the pressure vessel is constant. The coagulant is also fed to a water stream which is fed to a flotation unit where flotation takes place under pressure. The sludge formed as foam during the process is removed with a scraper to the sludge collection tank, while the purified water is pumped to the treated water tank. A sterilizing solution is also fed to the water stream.

The reliability of the above-mentioned device is rather poor due to the fact that the network traps large contaminants, which are initially flushed by the return water stream entering the water intake unit through the untreated water recirculation pipe. Such solids clog the network as it continues to operate. Clogging reduces the supply of wastewater to the pressure tank, while the discharge of wastewater from the pressure tank via a constant flow pressure line to the flotation unit remains constant. This in turn results in a reduction in the amount of water flowing through the recirculation pipe into the housing of the wastewater intake unit and rinsing or cleaning the network, which increases the clogging of the network.

Thus, the amount of wastewater fed to the pressure tank by the circulation pump continues to decrease, while the discharge rate from the pressure tank through the constant flow pressure line remains unchanged, which in turn reduces the water flow to the wastewater tank returning to the return line, etc. The above order is 4 72955 irreversible.

To prevent this, the operation must be stopped and the network must be washed with an external stream of water.

The object of the invention is to provide a more reliable wastewater treatment device, which can be achieved by better cleaning of the network of the water intake unit, which is achieved by a new arrangement of its parts and the use of new parts.

This is achieved by a wastewater treatment plant comprising a water intake unit with a housing and a network fitted to the waste water tank, arranged in series on the waste water flow path, covering the end part of the housing facing the water inlet flow, pipes for waste water intake and connected by a pipeline to a waste water intake pipe and the outlet of which is connected to a waste water recirculation pipe, a flotation unit connected by a constant flow pressure line to the outlet of the circulating pump, a sludge collector and a treated water tank both connected to the flotation unit , and a control block electrically connected to the circulation pump, the sludge discharge pump and the purified water discharge pump and the indicators of the upper and lower surfaces of the water of the waste water tank, the device according to the invention is further hand-operated a vacuum sensor electrically connected to the control block and arranged in a pipeline connecting the waste water intake pipe to the inlet of the circulating pump, the outlet of said pump being connected directly to the recirculation pipe for untreated water.

Preferably, the wastewater intake unit comprises a jacket attached to the front of the network, the bottom of which has an opening through which the wastewater flows, the network of the water intake unit being inclined at an angle of 30-45 ° to 72955 so that the untreated water stream fed by the circulation pump flows back through the network. from the sheath and acts on the surface of the net to flush contaminants away from it.

The use of the proposed device for wastewater treatment guarantees even more reliable wastewater treatment without operating personnel.

The objects and advantages of the present invention will become more apparent from the more detailed description taken in conjunction with the accompanying drawings, in which Figure 1 is a flow diagram of a wastewater treatment apparatus according to the invention, with longitudinal section, and Figure 2 is an enlarged sectional view of a wastewater treatment plant according to the invention.

The wastewater treatment device according to the invention comprises a water intake unit 1 (Fig. 1), a ship's water tank 4 with an upper water level indicator 2 and a lower water surface indicator 3. The water intake unit 1 has a housing generally indicated at 5 with a jacket part 6 open on its underside. The end of the housing 5 facing the flow of wastewater is closed by a net 7. The water intake unit 1 has a pipe 8 for the intake of incoming wastewater and a pipe 9 for the recirculation of untreated water. The water intake unit 1 is also provided with means 10 for rinsing the net 7. This means 10 is located inside the housing 5 and communicates with an external main water line (not shown) via an automatic inlet valve 11.

The inlet pipe 8 is connected to the inlet of the circulation pump 14 via a pipe 12 and a valve 13. A water vacuum sensor 15 is located in the pipeline 12. The outlet of the circulation pump 14 is connected via a pipeline 16 and a valve 17 to the pipe 9 for the recirculation of untreated wastewater. The pipeline 16 communicates with the flotation unit 21 6 72955 via a constant flow pressure line 18 with an automatic valve 19 and a flow rate diaphragm 20. The flotation unit 21 is connected by a pipeline 22 to a treated water tank 23 and a pipeline 24 to a sump collector 25 23 is in turn connected by a pipeline 27 to a pump 28 for the removal of purified water, while a sludge collector 25 is connected to a pump 30 for the removal of sludge. The sludge can be removed from the sludge collector 25 either to the waste water tank 4 via a pipeline 31 with a valve 32 or to a furnace not shown on the ship via a pipeline 33 with a valve 34.

The device further comprises a control block 35 electrically connected to an upper water level indicator 2, a lower water level indicator 3, a circulation pump 14, a purified water removal pump 28, a sludge removal pump 30, automatic valves 13, 17 and 19, a fan 26 and a vacuum sensor 15.

In order to more effectively affect the blocking contaminants of the network 7 of the water intake unit 1 as well as to improve the cleaning efficiency of the incoming water stream, the network 7 (Fig. 2) is arranged at an angle of 30-45 ° to the wastewater flow so that the untreated water streams 36 entering the water intake unit 1 after being recycled so that they pass through the net 7, return from the jacket 6 placed in front of the net 7 and therefore act on the inner and outer surfaces of the net 7, flushing contaminants from the net to the bottom of the waste water tank 4.

Preferably, the angle of inclination of the net 7 is 30-45 °, because only such an angle ensures that the total force of the untreated water flow from the pipe 9 as well as the force and gravity of the water flow returned from the jacket 6 of the water intake unit 1 are as effective as possible.

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When the angle of inclination of the net 7 exceeds 45 °, the power of the scraping force generated by the water stream returned from the jacket 6 decreases greatly, while when the angle of inclination less than 30 ° the gravity decreases rapidly, so that the water stream returned from the jacket 6 cannot scrape contaminants from the surface 7.

The wastewater treatment device according to the invention operates as follows.

The circulation pump 14 (Fig. 1) draws water from the housing 5 of the water intake unit 1 through the net 7 and conveys water from the pipe 8 to the pipe 16. The large contaminants or solids carried by the current do not pass through the net 7, while the jacket 6 prevents large solids suspended in wastewater. from the network 7. When the water flow rate to the housing 5 of the water intake unit 1 is normal and the water vacuum at the inlet of the circulation pump 14 in the pipeline 12 is below a predetermined value, the vacuum sensor 15 does not generate a signal to be sent to the control block 35. The water stream transported along the pipeline 16 is divided into two streams. A smaller portion of the stream (ca. 30%) enters the constant flow pressure line 18, while a larger portion of the water stream (ca. 70%) is made to flow back into the untreated water recirculation pipe 9. This separation is ensured by a membrane 20 fitted to the pressure line 18. The treated water passes through this line 18 to the flotation unit 21, where it is finally cleaned and sterilized. The formed sludge is removed from the flotation unit 21 via a pipeline 22 to a treated water tank 23. From the pipeline 16, a water stream enters the housing 5 of the water intake unit 1 to flush large solids from the net 7.

When contaminants begin to clog the network 7, the vacuum in the water line 12 before the circulation pump 14 causes the vacuum sensor 15 to generate a signal to be sent to the control block 35, which generates a signal to close the valve 19 at constant flow pressure 72955 in the line 18. to the recirculation pipe 9 of the untreated water, so that the water is returned to the housing 5 of the water intake unit 1. In this case, the flow rate of water supplied through the pipe 9 and directed to the network 7 of the waste water intake unit 1 increases sharply, facilitating efficient flushing of the network. Cleaning of the net 7 is further facilitated by the jacket 6 and the inclination of the net 7 in the direction of recirculated water flow. After passing through the non-clogged cells of the net 7, the recycled water streams 36 (Fig. 2) return from the wall of the jacket 6, flowing against the outer surface of the net 7 at an acute angle. Thus, the blocking contaminants of the net 7 are affected on two sides: the return water streams 36 act on the blockages inside the housing 5, separating them from the net, while the streams 36 returning from the jacket 6 tend to scrape the contaminants off the outer surface of the net 7. Such dual operation of the wastewater return stream greatly improves the cleaning efficiency of the network 7. The thus cleaned network 7 increases the inflow rate of wastewater from the effluent tank 4 to the water intake unit 1, whereby the vacuum at the inlet of the circulation pump 14 decreases (Fig. 1). .

During the water purification process, the sludge formed in the flotation unit 21 is conveyed along the pipeline 24 to the sludge collector 25, from where it is pumped by the pump 30 along the pipeline 29 for further use.

The sludge collector 25 is ventilated by a fan 26.

The water purified from the flotation unit 21 is conveyed via a pipeline 22 to a treated water tank 23, from where it is removed overboard by a pump 28 through a pipe 27.

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In view of the above, the use of the proposed device allows for the automatic rinsing and cleaning of the net 7 when it is blocked by contaminants without interfering with the continuous operation of the systems belonging to the device and without interference from the ship's crew.

The net 7 can also be cleaned automatically by opening the valve 11 to supply the flushing liquid to the net flushing means 10, which switches on automatically if no pressure rise occurs at the inlet of the circulation pump 14 three minutes after starting the automatic valve.

The proposed device can also complement on-board sewage treatment plants at the lowest possible cost, as such a device can be installed quite easily in engine rooms and requires relatively little space; e.g.

In 3 ships with a crew of 50, it fills a volume 3a of 1.7 m with an area of only 0.7 m. In addition, the use of the device requires the use of an existing wastewater tank without cleaning the ship's wastewater treatment equipment.

Claims (4)

10 72955 A wastewater treatment device comprising a water intake unit (1) with a housing (5) arranged in a wastewater tank (4) and a network (7) covering the end part of the housing (5) facing the wastewater inlet flow, arranged in series on the wastewater flow path. 8, 9) for the collection of wastewater and the return of untreated wastewater to the water intake unit (1), a circulation pump (14), the inlet of which is connected by a pipeline (12) to the wastewater intake pipe (8) and the outlet of which is connected to the untreated wastewater recycling pipe (9) , a flotation unit (21) connected by a constant flow pressure line (18) to the outlet of the circulation pump (14), a sludge collector (25) and a treated water tank (23) both connected to the flotation unit (21) and having a sludge pump ( 30) and a purified water removal pump (28), respectively, a control block (35) electrically connected to the circulating pump (14), pumps (28, 30) for removing sludge and purified water, and for indicators (2, 3) of the upper and lower surfaces of the waste water tank, characterized in that the device further comprises a water vacuum sensor (15) electrically connected to the control block (35) and connected to a pipeline (12) connecting the circulating pump (8) 14) an inlet, the outlet of said pump being connected directly to the untreated water recirculation pipe (9), the automatic shut-off valve (19) electrically connected to the control block (35) being arranged between the circulation pump (14) and the flotation unit (21) in a constant flow line (18). Device according to claim 1, characterized in that the wastewater intake unit (1) comprises a jacket (6) arranged in front of the network (7) and open at its lower part so that the wastewater can flow through it, whereby the water intake unit (1) ) is inclined at an angle of 30-45 ° to the wastewater flow path so that the untreated water stream supplied by the circulation pump (14) to flow through the net (7) flows back from the jacket (6) and acts on the surface of the net (7) to flush contaminants out. 1χ 72955 1. The calculation of the amount of aid to be paid in accordance with this Regulation, in which case the amount of aid is to be paid in accordance with the rules (1), in which the amount of aid (5) is (7) and (5) and the circulation of the cranks (8, 9) for the operation of the operation and the operation of the operation of the water supply system (1), the circulation pump (14), the inlet end of the genome and the circulation (8) of the circulation (12) in the case of openings and stumps in the case of circulating pumps (9) for the production of pure water and in the flotation system (21), in the case of genomic and triticales (18) in the case of constant volume volumes in the form of circulating pumps (14), and in the case of water (23) for the use of water, in the case of water in the flotation anchorage (21) and in the case of the pump (30) for the suction pump and the respect of the pump (28) for the pumping of Renat watts, which are styrene (35), with an electric boiler for circulating pumps (14), for pumping (28, 30) for pumping of Renat watts with respect to the slam and for the faecal water tank (2, 3) for in the case of a waterproofing system, the power supply of the power supply and the power supply (35) of the electric power supply (15) for the power supply and the power supply (8), in particular (12), with the aid of the inlet and outlet circuits (14), the end of which is directly supplied by the circulating pump (9) for the operation of the water supply, the colors are automatic, the styrene (35) of the electric control valve (19) and the anchorage ) with a constant flow rate with circulating pumps (14) and flotation anordningen (21).