TH19135B - Membrane cover for waste water reservoir And the drain system for that purpose - Google Patents

Abstract

DC60 (03/09/45) Membrane covers are installed on the surface of the waste water reservoir. Membrane cover will have a membrane. Which water is impermeable and floats and is flexible The articulation is attached to the wall around. Containment And stretched loosely Above the level of internal wastewater The row sets of weights are stretched. Floating against the surrounding walls And will be stretched loosely Above the impermeable membrane, a row of weights is defined as a rectangular herringbone model. This set of outlet rows is also available. Each drain is installed throughout a series of transverse weights. The membrane cover also contains A series of tubular rows in there, underneath the series of buoyancy weights with a continuous herringbone model, is contained within the pipe by means of this buoyancy. Causing the membrane cap to be always taut And stabilized during rainstorms And its surface Which affects the wind which will lift it up It is minimal. A membrane cover is installed on the surface of the reservoir. Membrane cover will have a membrane. Which water is impermeable and floats and is flexible The articulation is attached to the wall around. Containment And stretched loosely Above the level of internal wastewater A row of weights is attached. Floating against the surrounding walls And will be stretched loosely Above the impermeable membrane, a row of weights is defined as a rectangular herringbone model. This set of outlet rows is also available. Each drain is installed throughout a series of transverse weights. The membrane cover also contains A series of tubular rows in there, underneath the series of buoyancy weights with a continuous herringbone model, is contained within the pipe by means of this buoyancy. Causing the membrane cap to be always taut And stabilized during rainstorms And its surface Which affects the wind which will lift it up Will be minimal

Claims (5)

1. In the mixing of the wastewater container And mainframe cover It is installed above the effluent reservoir that holds the said wastewater. There is a level of sewage and a wall around it. And membrane cover Such at least contains Impermeable membrane Which floats in a flexible manner The joints are fixed to the surrounding wall and are loosely stretched. Above the said wastewater level A row of weights Which is suspended against the surrounding wall and loosely stretched over the impermeable membrane. The row of weights is defined as a rectangular herringbone model, where at least consists of A row of weights along the length and a row of weights across a number of distances from each other. Perpendicularly Coming out of a row of weights along that length On both sides of a row of weights along the aforementioned length, the drain row is set. Each body is installed along a row of weights along the way. At least one row And will continue to enter waste water through a membrane that permeates the water No, such a set of pipe rows, located there under the row of such weights, whereby the pipes are connected to each other and the buoyancy is contained in them. In such a way that the membrane cover is always taut And is stable during That caused a rainstorm And its surface The impact of the wind to lift it up is minimal. 2. In a mix with a septic tank, a membrane cover is installed above the waste water reservoir. Said that such wastewater The wastewater level, length, width and surrounding walls are defined as such length and width. And the membrane cover has a long center line. Relative to length And such width Flexible floating shelves The splice is fixed to the surrounding wall and is loosely stretched above the sewage level. Impermeable membrane It is attached to the surrounding wall and loosely stretched over the flexible mezzanine. A set of rows of weights It floats against the surrounding walls and stretches loosely. Above the impermeable membrane The aforementioned weight row consists of a longitudinal weight row. Continued along the center line and a number of rows of weights from each other. Which will come out perpendicular from the weights row Along such a long way On both sides of a row of weights along the length, the row of weights is defined as a rectangular herringbone model. Outlet row Each body is installed along a row of weights along the way. At least one row Close to the surrounding walls and into the sewage Through the aforementioned flexible floating shelves And such impermeable membrane Such membrane cap There is also a series of rows of pipes. In there Under the row series of Such weights The pipes are connected to each other and the buoys are contained in them. In such a way that the membrane cover Will always be tight And it is stable and its surface, which impacts the wind, which lifts it up, is minimal during a rainstorm. 3. Mixes as stated in Clause 2, where the buoyancy. There will be a subject The herringbone is formed as such. 4. Mixing as described in Clause 2, where each such pipe has sloping sides. 5. Mixers as specified in Clause 4. Where the membrane cover will Continue to A series of edges Where there is With each ridge installed Between the two rows of cross weights 6. The combination specified in Clause 2, where each such vent It consists of a straight tube extending over one side of the impermeable membrane. 7. Mixture as described in Clause 2, where such vent will be in A quarter of the width Closest to the surrounding walls One side. 8. Mixing as described in claim 2, where the impermeable membrane is They are made of sheet material which can be stacked. Using nylon as a base 9. The combination specified in claim 2, where the flexible floating floor is It is made of insulating foam impermeable 1 0. The combination specified in Clause 2, where each row of weights consists of a number of pipe sections. Filled with sand And connected to each other by a loop 1 1. The combination as specified in Clause 10, where the lasso in the weights row One row Which will be attached to one such drain. 1 2. Mixture as specified in Clause 2, where each such drain will consist of a straight pipe and a flange attached to it. Throughout the center Of such straight pipes And with the aforementioned impermeable membrane 1 3. Mixture as described in Clause 12, where the discharge outlet also contains a sealing connection between the flanges. And the impermeable membrane 1 4. Mixture as described in Clause 12, where the straight tube consists of the upper part extending over the impermeable membrane. Such And the bottom section extends under the flexible floating shelf 1 5. Mixture as stated in Clause 14, where the above part is of length, consisting of equilibrium dimensions. And the size as protected first And the balance size corresponds to the water level of the said buoyancy. Near one of the said outlet and the size as a precaution It extends above the water level of the said buoyancy. 1 6. Mixture as described in claim 15, where the balance is approximately one inch. And approximately two inches 1 7. Combination as described in Clause 15, where the preceding size It is approximately one and a half inches. 1 8. Mixing as described in Clause 15, where the water level of the said buoyancy is higher than the said wastewater level in the said effluent reservoir 1. 9.Mixtures as described in Clause 18, where such a flexible buoyancy shall have the thickness and water level of such buoyancy. Will be higher than the level of wastewater In such containment By size slightly greater than the aforementioned thickness 2 0. Mixing as stated in Clause 12, where the aforementioned straight pipe has a flange installed therein 1. Mixes as described in Clause 12 where the pipe is straight. Will have a part that is The thread is on the top end of it 2. 2.How to install the drain system in the membrane cover Used to cover the waste water reservoir. Where is the method It consists of steps of Arranging a set of weight rows Installation of such a weight row unit On the said membrane cover Creating a set of pipe rows Under that weights row set Arrangement of a vent with a straight pipe Cutting the drain holes in the membrane cover under the weights in the weights row. Such weight Making water return from that containment Flows through the vent hole and into a series of pipes. Sinking such a row of weights In the reverse flow of water Until the aforementioned flowing water forms a continuous model Throughout the aforementioned series of weights Measuring the depth of the return water Near that row of weights in that weight row unit Adjustment of the said drain And such straight pipes In the drain hole where the pipe is directly connected above the membrane cover Which will cover at least one size Which corresponds to the aforementioned depth and to bring the water back down Out of the aforementioned membrane cover in a way that the tube will work fine. To collect the rainwater in it quickly To stabilize the membrane cover During rain storms and such a vent will work well. In bringing too much rainwater thereof Out of the said pipe 2 3. Procedures set forth in Clause 22 at which the said stage of arrangement The weight row consists of the process of arranging the series of those weights designated as the herringbone model 2. 4. Method as set out in Clause 22 Clause 22 at which the said procedure of adjustment The said outlet And such straight pipes In the said vent contains steps of Adjust the said outlet And such straight pipes By such straight pipe Will extend over the cover Such membrane And will cover any size At least Which corresponds to the aforementioned depth, increased by the size as previously protected by one and a half inches. 5. Methods set out in Clause 22, which follows the procedure for having the said membrane cover. That is between about an inch and a half to about three quarters of an inch thick.