PL208319B1 - Gravitational and pumped dischargeable storage reservoir - Google Patents

Description

Description of the invention

The subject of the invention is a gravity-pump retention tank for hydraulic unloading of networks and facilities of various sewage disposal systems, especially those transporting rainwater and combined sewage by gravity.

Control of sewage flows, especially rainwater flows in the sewage system, is an issue that has a decisive impact on the optimal dimensioning and effective use of the network. This issue is particularly important in the case of collectors that are subject to hydraulic overload during periods of sewage runoff in amounts exceeding their hydraulic capacity.

This goal was achieved as a result of the solution of a retention reservoir with an adjustable outflow of liquid, described in the Polish patent application No. P378387. The retention reservoir, which is the subject of the said application, is a network reservoir, which is an object located directly in the network, through which sewage flows both during the process of filling and emptying it. The pumping system in this solution of the tank operates continuously during the inflow of sewage. The necessity to operate the pumping system throughout the entire period of sewage flow through the sewage system is a disadvantage of this solution, expressed in high electricity consumption and the resulting operating costs. In addition, the existing solutions to prevent overloading of the sewage disposal network require large areas for their construction.

Also, a significant improvement in the economic indicators of the operation of retention reservoirs was achieved as a result of the solution that is the subject of Polish patent application No. P386844. The relief storage reservoir, which is the subject of this application, due to its location outside the main run of the canal, on its side branch in the form of a bypass and placing the bottom of the accumulation and pump chamber at or above the bottom of the inflow and outflow canals, is filled by gravity for a significant part of its volume. It is also emptied entirely by gravity. As can be seen from the above, significant savings of electricity were obtained, thus reducing the costs of its operation. The solutions of retention reservoirs known so far require the occupation of large areas for their construction. This problem is partially alleviated by the use of tanks according to the aforesaid application No. P 386 844, in which accumulation chambers with considerable heights can be used. Solving this problem is of particular importance in the case of limited available space for development of municipal infrastructure, especially in urban areas.

Gravity-pump unloading the retention tank, containing an accumulation chamber connected to it, a pump chamber and a collecting chamber, and an adjustable sewage outflow, the accumulation chamber of which can be divided into sections functioning independently of each other, connected with the pump chamber in series or in parallel, located on the side branch of the sewage network, in accordance with according to the invention, characterized in that the bottom of the accumulation chamber is placed at or below the level of the bottom of the inflow and outflow channel, while the pumping system located in the pump chamber is connected to the collecting chamber, the space of which is connected with the space of the accumulation chamber by an inter-chamber overflow and an opening with the regulating device and is also connected to the drainage channel.

The applied hydraulic system of the reservoir according to the invention enables its complete location below the ground surface, without limiting the height of the available sewage retention. Covering even a small layer of soil or other material allows the surface occupied by the reservoir to be used for purposes, for example, for recreational purposes or for greenery and ornamental plants. It is very important when locating these facilities in urban areas. The new solution of the retention reservoir, similarly to the previously described one, in accordance with the Polish patent application No. P 386 844, does not require continuous operation of the pumping system in the process of filling and emptying the accumulation chamber, because part of the accumulation chamber volume is filled and emptied by gravity through the flow holes. The applied configuration of the pumping system with the use of the collecting chamber enables the filling and emptying of a part of the volume of the accumulation chamber with the installation of only one pumping system. The mentioned possibilities of filling and emptying the retention tank according to the invention constitute a significant reduction of its operating costs.

PL 208 319 B1

The subject of the invention in an exemplary embodiment is shown in the drawing, in which Fig. 1 shows, in a schematic view, in a top view, the location of the relief retention reservoir in relation to the sewage network, Fig. 2 - gravity-pump retention reservoir in longitudinal section with a single-section accumulation chamber Fig. 3 , 4, 5, 6, 7, 8, 9 and 10 show the phases of filling and emptying this reservoir, Fig. 11 shows a top view of a gravity-pump retention reservoir with a three-section accumulation chamber in series configuration, and Fig. 12 - a longitudinal section of this reservoir. solutions of the tank, while Figures 13, 14, 15, 16, 17, 18. 19 and 20 show the successive phases of filling and emptying the tank with a three-section accumulation chamber in series. In turn, Fig. 21 shows a top view of the retention reservoir with a three-section accumulation chamber in a parallel configuration, and Fig. 22 - a longitudinal section of this reservoir and Figs. 23, 24, 25, 26, 27, 28, 29 and 30 show the subsequent phases. filling and emptying the tank with a three-section accumulation chamber in a parallel system.

As shown in Fig. 1, the gravity-pump unloading retention tank 1 is located outside the main run of the sewer 2, on its side branch in the form of a bypass and connected to it from the sewage inlet side through the inlet conduit 3 and the flow splitting chamber 4, while at the outlet through the drain channel 5 and the connection chamber 6.

This tank has a pump chamber 7 with a pumping system 9, which is connected to the accumulation chamber 8 through a flow opening 10, in which a device 12 controlling the flow of sewage is installed. In the first phase of filling the tank, gravity flow occurs through the device 12, which is a gate valve. In the next step, the accumulation chamber 8 is filled by means of a pumping system 9 located in the pump chamber 7 through the collecting chamber 13, in which the inter-chamber overflow 14 and a flow opening are located. The pump chamber 7 is connected to the sewer 2 by an inflow channel 3 through the flow distribution chamber 4, in which exceeding a certain level of sewage causes the excess of sewage to flow into the retention tank 1. At the outlet, the retention tank has an outflow opening 16 to the sewer 2 through the outflow channel 5 with an installed at the end, an outlet throttling device 17, which is most often a fluid flow regulator. A collection chamber 13 is separated in the space of the accumulation chamber 8, connected to it by an inter-chamber overflow 14 and an opening in which the control device 15 is located. The pumping system 9 located in the pump chamber 7 is connected to the collection chamber 13 by a conduit 18.

The described tank is shown schematically in Fig. 2. The accumulation chamber 8 of this tank is a single-section chamber.

In the tank with a single-section accumulation chamber, the inflow of sewage takes place into the pump chamber 7, which is filled in the first stage of the accumulation process. This step is shown in Fig. 3. When the flow opening 10 is opened, the sewage flows into the accumulation chamber 8 by gravity. A gate valve can be installed in the flow opening 10 as a flow control device 12. This phase of operation of the retention tank is shown in Fig. 4. After filling the pump chamber 7 and the accumulation chamber 8 to the level of the roof of the inflow channel 3, the opening 10 is closed. from the pump chamber 7 to the collecting chamber 13, as shown in Fig. 6. Then the excess sewage from the collecting chamber 13 is poured through the inter-chamber overflow 14 into the accumulation chamber 8. This stage of the tank operation is shown in Fig. 7. The process continues until the sewage supply stops or until full filling is achieved in the collecting chamber 13 and the accumulation chamber 8. This stage of the tank operation is shown in Fig. 8. The process of emptying the tank starts automatically when the flow of sewage in the sewage network drops to a predetermined value or it is started by the operation of the tank. First, the collection chamber 13 is emptied by gravity, then the accumulation chamber 8 is emptied through the open regulating device 15. The flow rate of sewage from the collecting chamber 13 to the sewage network 2 or the receiver is regulated by the regulating device 17. This phase of the tank operation is shown in Fig. 9. After the gravitational emptying of the collecting chamber 13 and a part of the accumulation chamber 8, the regulating device 14 is closed and the device 12 is opened, and the sewage flows into the pump chamber 7 and transports it by pumping to the collecting chamber 13. This stage of operation of the tank, which is shown in Fig. 10 continues until the tank is completely empty. After that, the tank remains empty and waits for more waves of sewage inflow.

Taking into account operational considerations, and in particular the need to limit contamination of the bottom of the entire accumulation chamber at low rainfall, and to facilitate

In order to clean the surface of the tank, it is advantageous to divide the space of the accumulation chamber 8 into sections 19 that function independently of one another. The separated sections 19 of the accumulation chamber 8 can be hydraulically connected to each other in series or in parallel.

In the case of a multi-section storage reservoir with an accumulation chamber 8 divided into sections in series, the sections 19 have flow openings 20 with adjustable flow in the lower parts, and inter-section overflows at the top 21. The collecting chamber 13 is connected to the sections 19 of the accumulation chamber with 8 openings equipped with devices regulation 15, while in the partition between the collecting chamber 13 and one of the sections 19 there is an inter-chamber overflow 14 as shown in Figs. 11 and 12.

In the case of a tank with a multi-section accumulation chamber 8 in which the sections are connected in parallel, it should be considered advantageous to have flow openings 10 in the inter-chamber partition 11 with flow shut-off devices in the form of gate valves installed therein. The openings 10 together with the flow shut-off devices 12 allow the section 19 to be partially filled by gravity. In the partition between the collecting chamber 13 and sections 19 there are openings with adjustable flow 15 and an inter-chamber overflow 14. This solution is shown in Figures 21 and 22.

Due to the different course of the liquid accumulation process in the tank with a multi-section serial and parallel accumulation chamber, a separate description of their operation has been made.

Fig. 13 shows that the inflow of sewage to the pump chamber 7 causes it to fill up. Subsequently, sewage flows through the flow opening 10, in which the device 12 is located, regulating the direction of sewage flow and gravitational filling of the accumulation space of the first section 19. After reaching a certain level of sewage in the first section 19, subsequent sections 19 of the accumulation chamber 8 are filled through the flow openings. with devices 20 for regulating the direction of the flow of wastewater. This stage of operation of the tank is shown in Fig. 14. After the gravity filling of the accumulation chamber 8 to the level of the roof of the inlet channel 3, the regulation device 12 is closed, as shown in Fig. 15. Then the pumping system 9 is activated and the sewage is transported from the pumping chamber 7 to the collecting chamber. 13 via line 18, which is refilled. This stage in the operation of the tank is shown in Fig. 16. Subsequently, the sewage supplied to the collecting chamber overflows through the inter-chamber overflow 14 and first one and then other sections 19 of the tank are filled. This stage is shown in Fig. 17. The complete accumulation of sewage or the disappearance of its inflow to the pump chamber 7 causes the pump system 9 to be switched off, as shown in Fig. 18. In the process of emptying the tank, the collecting chamber 13 is first emptied by gravity, from which the sewage flows through the channel outflow 5 to chamber 6 and sewerage system 2 or a sewage receiver. The outflow of sewage to the sewage system 2 is regulated by a flow regulator 17 located at the outflow of sewage. This process is shown in Fig. 19. Next, after the gravitational emptying of a part of the accumulation chamber 8, the regulation device 12 is opened and sewage flows from the accumulation chamber 8 to the pump chamber 7 from where the sewage is collected by the pumping system 9 and transported to the collecting chamber 13, and then they flow to sewage network 2. This phase of the tank operation is shown in Fig. 20. After it is completely empty, the tank waits for the next wave of sewage flow.

In the retention tank with the parallel arrangement of the sections 19 in the accumulation chamber 8 as shown in Fig. 21, in the first operating stage, the inflow of sewage into the pump chamber 7 causes it to be filled as shown in Fig. 23. Next, the regulation device 12 is opened as a function of from the adopted filling schedule or in one or more sections 19. The flow of sewage causes its gravity filling, as shown in Fig. 24, up to the level of the roof of the inlet channel 3. After gravitational filling of section 19 of the accumulation chamber 8, the regulating devices 12 are closed, which is 25 is shown. In a further step, the pumping system 9 is activated and sewage is transported from the pumping chamber 7 to the collecting chamber 13 via the line 18. This stage is shown in Fig. 26. Then, the sewage pumped into the collecting chamber 13 flows into the section 19 through weirs. ventricular 14 as shown in Fig. 27. The filling phases of the reservoir are completed at the moment of filling the space of the accumulation chamber 8. This situation is shown in Fig. 28. Depending on the hydraulic conditions in the sewage network to which the sewage from the tank is discharged or the conditions in the receiver, the sewage outflow takes place. First, the sewage accumulated in the collecting chamber 13 of the tank is discharged by gravity, which flows in a controlled amount through the drainage channel 5 to the chamber.

The opening of the regulating device 15 then causes the gravitational flow of waste water from the accumulation chamber 8 section 19 into the collecting chamber 13 and the sewage network 2. This step is shown in Fig. 29. In the final emptying step, the regulating device 12 is opened and the waste water drains out. from the accumulation chamber 8 to the pump chamber 7, from where the sewage is pumped into the collecting chamber 13 through the conduit 18, and then flows out in an adjustable amount to the sewage network 2 or to the receiver. This situation is shown in Fig. 30. After emptying the accumulation chamber, the tank waits for further inflow.

Claims (1)

Gravity-pump unloading the storage reservoir containing an accumulation chamber, connected to it a pump chamber and a collection chamber, and an adjustable sewage outflow, the accumulation chamber of which can be divided into sections functioning independently, connected with the pump chamber in series or in parallel, located on the side branch of the sewage network, characterized in that the bottom of the accumulation chamber (8) is placed at or below the level of the bottom of the inlet (3) and outflow (5) channel, while the pumping system (9) located in the pump chamber (7) is connected to the collection chamber (13) the space of which is connected to the space of the accumulation chamber (8) by an inter-chamber overflow (14) and an opening with the adjustment device (15), and is also connected to the drainage channel (5).