KR102580942B1 - Sewage ejector of underground - Google Patents

Abstract

The pump that pumps the sewage collected in the underground sewage well is placed outside the underground sewage well to facilitate repair and replacement of the pump, and solves the problem of floating solids solidifying on the upper surface of the underground sewage well and sediment accumulating at the bottom of the underground sewage well. An improved underground sewage discharge device is disclosed that prevents foreign substances from sticking to the inside of an underground sewage well and prevents corrosion of the underground sewage tank due to acidification.

Description

Improved underground sewage discharge device {SEWAGE EJECTOR OF UNDERGROUND}

The present invention relates to an improved underground sewage discharge device. More specifically, the pump that pumps the sewage collected in the underground sewage well is placed outside the underground sewage well to facilitate repair and replacement of the pump, and to prevent suspended matter from floating on the upper surface of the underground sewage well. An improved underground sewage discharge device that solves the problem of not only solidification but also sediment accumulation at the bottom of the underground sewage tank, and at the same time prevents foreign substances from sticking to the inside of the underground sewage tank and prevents corrosion of the underground sewage tank due to acidification. will be.

In general, in buildings for residence or business, the underground space is used as a space for residence or work to improve space utilization. Various types of sewage are generated in these underground spaces, and a separate underground sewage discharge device is installed to treat the sewage generated in the underground space.

As an example of such an underground sewage discharge device, the applicant's registered patent No. 10-1638617 is disclosed. The underground sewage discharge device according to the above patent pumps the sewage collected in the underground sewage well and forces it to be discharged to the septic tank on the ground through the discharge pipe. When some of the discharged sewage is circulated back into the underground sewage well and sprayed through the spray nozzle, the suspended matter solidifies. We are trying to prevent this from happening.

However, in the above patent, the pump is placed inside the underground sewage well, making it difficult to repair and replace in case of pump failure. It sprays the circulated sewage through a spray nozzle to prevent floating matter from solidifying on the upper surface of the underground sewage well, but it is not possible to prevent floating matter from solidifying on the upper surface of the underground sewage well. The disadvantage is that it cannot solve the problem of sediment accumulation.

The present invention was devised to solve the above problems, and its purpose is to facilitate repair and replacement of the pump by placing a pump that pumps sewage collected in the underground sewage well outside the underground sewage well, and to prevent suspended matter from solidifying on the upper surface of the underground sewage well. Of course, it also provides an improved underground sewage discharge device that can solve the problem of sediment accumulating at the bottom of the underground sewage well.

Another object of the present invention is to provide an improved underground sewage discharge device that prevents foreign substances from sticking to the inner surface of an underground sewage tank and prevents corrosion of the underground sewage tank due to acidification.

The object of the present invention is to include an underground sewage cistern (10) installed at a position lower than the lowest floor of the underground space to collect sewage generated in the underground space; A sewage inflow pipe (20) that guides rainwater to flow into the underground sewage well; a first discharge pipe (30) installed to connect the underground sewage well and the above-ground septic tank and guide sewage collected from the underground sewage well to the above-ground septic tank; a second discharge pipe (40) installed to connect the underground sewage well and the above-ground septic tank and guide sewage collected from the underground sewage well to the above-ground septic tank; a first pump (50) disposed outside the underground sewage well and discharging the sewage collected in the underground sewage well through a first discharge pipe through a pumping operation; a second pump (60) disposed outside the underground sewage well and discharging the sewage collected in the underground sewage well through a second discharge pipe through a pumping operation; A sensor unit (70) that detects the height of sewage collected in an underground sewage well and transmits a signal; a control unit 80 that receives a signal from the sensor unit and selectively operates the first pump and the second pump; After branching from the first discharge pipe, it extends to the lower part of the underground sewage tank to recover part of the sewage discharged through the first discharge pipe into the underground water tank, and at the end, there is a first injection port 38 for spraying the recovered sewage in the form of bubbles. A first recovery pipe 34 installed; After branching from the second discharge pipe, it extends to the lower part of the underground sewage well to recover part of the sewage discharged through the second discharge pipe into the underground water tank. At the end, there is a second nozzle 48 that sprays the recovered sewage in the form of bubbles. This can be achieved by providing an improved underground sewage discharge device, characterized in that it includes a second recovery pipe 44 mounted thereon.

The underground sewage discharge device according to the present invention facilitates repair and replacement of the pump by placing a pump for pumping sewage collected in the underground sewage well outside the underground sewage well, and not only solidifies suspended matter on the upper surface of the underground sewage well but also causes it to be discharged to the lower part of the underground sewage well. It can solve the problem of sediment accumulation.

In addition, it can prevent foreign substances from sticking to the inside of the underground sewage tank and prevent the underground sewage tank from corroding due to acidification.

Figure 1 is a cross-sectional view showing the configuration of an underground sewage discharge device according to the present invention.

Hereinafter, the underground sewage discharge device according to the present invention will be described in detail with reference to the attached drawings.

The attached Figure 1 is a cross-sectional view showing the configuration of an underground sewage discharge device according to the present invention.

Referring to the drawing, the underground sewage discharge device according to the present invention includes an underground sewage well (10), a sewage inlet pipe (20), a first discharge pipe (30), a second discharge pipe (40), a first pump (50), and a second pump. (60), sensor unit 70, control unit 80, first recovery pipe 34, and second recovery pipe 44.

To describe the basic underground sewage discharge device of the present invention, an underground sewage hydrant 10 is installed at a position lower than the lowest floor surface of the underground space to collect sewage generated in the underground space. Here, the underground sewage cistern 10 is configured to have a lid 12 assembled at the top so that the inside is exposed when the lid 12 is opened.

In addition, a sewage inlet pipe (20) flows into the underground sewage cistern (10), and sewage generated in the underground space flows into the sewage inlet pipe (20). Here, a valve that selectively opens and closes the sewage inlet pipe 20 is installed in a portion of the sewage inlet pipe 20.

In addition, the first discharge pipe 30 and the second discharge pipe 40 are installed to be spaced apart from each other in order to connect the underground sewage cistern 10 and the above-ground septic tank and guide the sewage collected from the underground sewage cistern to the above-ground septic tank. Sewage collected from the underground sewage well (10) through the first discharge pipe (30) or the second discharge pipe (40) joins the main discharge pipe (1) and is guided to the septic tank on the ground.

Here, a first opening/closing valve 32 is installed in a portion of the first discharge pipe 30 to selectively open and close the first discharge pipe 30, and a portion of the second discharge pipe 40 is installed to selectively open and close the second discharge pipe 40. A second opening/closing valve 42 is installed to open and close.

In addition, a first pump 50 that discharges sewage collected in the underground sewage well through a first discharge pipe through a pumping operation and a second pump 60 that discharges the sewage collected in the underground sewage well through a second discharge pipe are disposed outside the underground sewage well.

In addition, a sensor unit 70 is installed in the underground sewage cistern 10 to detect the height of the collected sewage and transmit a signal. This sensor unit 70 sequentially moves from the bottom of the underground sewage cistern 10 to the first A sensor 72, a second sensor 74, and a third sensor 76 are installed.

Here, the first sensor 72 to the third sensor 76 are for detecting the water level of sewage collected in the underground sewage cistern 10, and when sewage is detected only by the first sensor 72, the first pump 50 ) or the second pump (60) operates, and when sewage is detected by the second sensor (74) or the third sensor (76), the first pump (50) and the second pump (60) operate together. do. In other words, the amount of sewage discharged is adjusted according to the water level of the sewage.

The control unit 80 receives a signal from the sensor unit 70 and selectively operates the first pump 50 and the second pump 60, and also operates the first on-off valve 32 and the second on-off valve 42. They are electrically connected to control the operation of the first on-off valve 32 and the second on-off valve 42.

Furthermore, the present invention provides a first recovery pipe (34) that branches off from the first discharge pipe and extends to the lower part of the underground sewage well to recover a part of the sewage discharged into the first discharge pipe into the inside of the underground sewage pipe, and a first recovery pipe (34) branched from the second discharge pipe. It includes a second recovery pipe 44 that extends to the lower part of the underground sewage tank and recovers part of the sewage discharged through the second discharge pipe into the underground water tank.

The first recovery pipe and the second recovery pipe are pipes that recover part of the sewage discharged from the first discharge pipe 30 and the second discharge pipe 40 into the inside of the underground sewage tank, and extend to the lower part of the underground sewage tank, and have a pipe at the end. A first injection port 38 and a second injection port 48 are each formed, and the injection ports 38 and 48 have fine holes to spray the recovered sewage in the form of bubbles.

In addition, the first solenoid valve 36 is installed in the first recovery pipe 34 to selectively open and close the first recovery pipe under the control of the control unit, and the second recovery pipe 44 is installed with the second solenoid valve 36 under the control of the control unit. A second solenoid valve 36 is installed to selectively open and close the return pipe. The first solenoid valve 36 and the second solenoid valve 46 are intermittently operated by the control unit for approximately 10 seconds.

The operation and effects of the underground sewage discharge device according to the present invention configured as described above will be described.

First, when sewage flows into the sewage inlet pipe 20 and reaches a certain level in the underground sewage cistern 10, the sensor unit 70 operates to operate the first pump 50 and the second pump 60 alternately. That is, when the first pump 50 operates, the first opening and closing valve 32 of the first discharge pipe 30 is opened, and when the second pump 60 operates, the first opening and closing valve 32 of the second discharge pipe 40 is opened. Valve 42 is opened. At this time, the present invention has the advantage that the first pump 50 and the second pump 60 are placed outside the underground sewage well, so even if they break down, they can be easily repaired and replaced compared to existing submersible pumps.

In addition, suspended matter solidifies on the upper surface of the sewage inside the underground sewage well and sediment accumulates on the lower part of the sewage. Under the control of the control unit, the first solenoid valve 36 and the second solenoid valve 46 are selectively operated to collect the first recovery. Sewage is discharged to the bottom of the underground sewage tank through pipes and return pipes.

At this time, in the present invention, since the ends of the first and second recovery pipes are equipped with injection ports 38 and 48 for spraying the recovered sewage in the form of bubbles, the sewage sprayed in the form of bubbles causes damage to the lower part of the underground sewage cistern. Sediment does not accumulate in the sewage tank, and by moving the sewage in the underground sewage tank, suspended solids are prevented from solidifying on the upper surface of the underground sewage tank.

Meanwhile, the underground sewage cistern 10 is made of 40 parts by weight of bisphenol A-epichlorohydrin-methacrylic acid polymer for 100 parts by weight of FRP (Fiber Reinforced Plastics) to ensure durability, erosion resistance, corrosion resistance, heat resistance, and waterproofing. It is manufactured by molding a composition of 5 parts by weight of vinylbenzene, 5 parts by weight of alkylresorcinol, and 15 parts by weight of alkylresorcinol.

At this time, FRP (Fiber Reinforced Plastics) refers to resin reinforced with fiber, that is, “fiber-reinforced resin (fiber-reinforced plastic)” refers to composite materials of fiber and resin.

In this case, the reinforcing fiber is glass fiber, the base resin mixed with glass fiber is polyester resin, and the weight ratio of glass fiber to polyester resin is 2:8.

In addition, the bisphenol A-epichlorohydrin-methacrylic acid polymer is a material corresponding to CAS number 36425-15-7, and has corrosion resistance and corrosion resistance of the underground sewage cistern (10). It is added to strengthen the anti-pollution properties.

In addition, vinyl benzene is a material corresponding to CAS number 100-42-5, and is added to adjust viscosity, strengthen insulation, and increase acid resistance, water resistance, and heat resistance.

In addition, alkylresorcinol is added to enhance adhesion and increase binding force between components to increase durability and heat resistance.

In addition, in the present invention, 10 parts by weight of cristobalite, 5 parts by weight of polyoxyethylene alkyl ether, 5 parts by weight of disodium EDTA, and 5 parts by weight of diaryl phthalate may be further added to 100 parts by weight of the FRP.

At this time, the cristobalite is added in powder form and contains quartz, which increases the durability of the underground sewage cistern. The base resin penetrates into the pores of the cristobalite powder and binds them, thereby increasing heat resistance and maintaining elasticity at the same time. It will satisfy you.

In addition, the polyoxyethylene alkyl ether is a type of nonionic surfactant and is added to increase emulsibility and dispersibility, thereby increasing agitation and miscibility.

In addition, Disodium EDTA is added to the surface of the underground sewage tank to prevent rancidity due to oxidation.

In addition, diarylphthalates are added to improve adhesion and toughness between components and increase heat resistance, dimensional stability, and chemical resistance, including crack generation inhibition.

On the other hand, the inner surface of the underground sewage cistern 10 is coated with a coating solution prepared by mixing 3.5 parts by weight of styrene monomer, 7.5 parts by weight of titanium oxide, and 6.5 parts by weight of sodium benzoate with respect to 100 parts by weight of unsaturated polyester resin to prevent acidification. It is coated.

At this time, the styrene monomer is a material corresponding to CAS number 100-42-5, and is added to adjust viscosity, strengthen insulation, and increase acid resistance, water resistance, and heat resistance.

In addition, the titanium oxide (Titanium Dioxide) is a material corresponding to CAS number 13463-67-7, and is added to block ultraviolet rays and prevent surface acidification of underground sewage cisterns to suppress durability deterioration and lifespan deterioration.

Additionally, sodium benzoate is added to increase adhesion.

In addition, 3.5 parts by weight of acrylonitrile may be added to 100 parts by weight of the unsaturated polyester resin to promote curing; Additionally, 5.5 parts by weight of benzoyl peroxide (BPO) can be added to form a coating solution and improve the rigidity of the coating layer.

1: Main discharge pipe 10: Underground sewage well
12: Lid 20 Sewage inlet pipe
30: First discharge pipe 32: First opening/closing valve:
34: first recovery pipe 36: first solenoid valve
38: first outlet 40: second discharge pipe
42: 2nd opening/closing valve 44: 2nd recovery pipe
46: second solenoid valve 48: second outlet
50: first pump 60: second pump
70: sensor 80: control unit

Claims (4)

An underground sewage cistern (10) installed at a position lower than the lowest floor of the underground space to collect sewage generated in the underground space;
A sewage inflow pipe (20) that guides rainwater to flow into the underground sewage well;
a first discharge pipe (30) installed to connect the underground sewage well and the above-ground septic tank and guide sewage collected from the underground sewage well to the above-ground septic tank;
a second discharge pipe (40) installed to connect the underground sewage well and the above-ground septic tank and guide sewage collected from the underground sewage well to the above-ground septic tank;
a first pump (50) disposed outside the underground sewage well and discharging the sewage collected in the underground sewage well through a first discharge pipe through a pumping operation;
a second pump (60) disposed outside the underground sewage well and discharging the sewage collected in the underground sewage well through a second discharge pipe through a pumping operation;
A sensor unit (70) that detects the height of sewage collected in an underground sewage well and transmits a signal;
a control unit 80 that receives a signal from the sensor unit and selectively operates the first pump and the second pump;
After branching from the first discharge pipe, it extends to the lower part of the underground sewage tank to recover part of the sewage discharged through the first discharge pipe into the underground water tank, and at the end, there is a first injection port 38 for spraying the recovered sewage in the form of bubbles. A first recovery pipe (34) mounted;
After branching from the second discharge pipe, it extends to the lower part of the underground sewage well to recover part of the sewage discharged through the second discharge pipe into the underground water tank. At the end, there is a second nozzle 48 that sprays the recovered sewage in the form of bubbles. It is composed of a second recovery pipe (44) mounted,
The underground sewage cistern is molded with a composition of 100 parts by weight of FRP (Fiber Reinforced Plastics), 40 parts by weight of bisphenol A-epichlorohydrin-methacrylic acid polymer, 5 parts by weight of vinylbenzene, and 15 parts by weight of alkyl resorcinol. An improved underground sewage discharge device characterized by being
According to paragraph 1,
A first on-off valve 32 is installed in the first discharge pipe to selectively open and close the first discharge pipe, and a second on-off valve 42 is installed in the second discharge pipe to selectively open and close the second discharge pipe,
A first solenoid valve 36 is installed in the first recovery pipe to selectively open and close the first recovery pipe under the control of the control unit, and a first solenoid valve 36 is installed in the second recovery pipe to selectively open and close the second recovery pipe under the control of the control unit. An improved underground sewage discharge device, characterized in that 2 electromagnetic valves (46) are installed.
delete According to claim 1 or 2,
An improvement characterized in that the inner surface of the underground sewage well is coated with a coating solution prepared by mixing 3.5 parts by weight of styrene monomer, 7.5 parts by weight of titanium oxide, and 6.5 parts by weight of sodium benzoate with respect to 100 parts by weight of unsaturated polyester resin to prevent acidification. An underground sewage discharge device.