KR20040097697A - Inverted syphon pipe system - Google Patents

Abstract

PURPOSE: A reverse siphon sewer system is provided to prevent deposits from being layered without additional drain equipment by simplified structure. CONSTITUTION: A reverse siphon sewer comprises a main pipe(10) having a connection pipe(11) and vertical pipes(12,14). An inlet pipe(20) and an outlet pipe(30) are each connected to the vertical pipes. A bypass-sub pipe(15) having the caliber smaller than the caliber of the main pipe is connected to a lower side of the vertical pipe and to the end of the outlet pipe. The height of the upper end of the bypass-sub pipe is lower than the height of the water level of sewage flowing into the vertical pipe. The connection parts of the vertical pipe of the main pipe and the outlet pipe are interconnected by a slant pipe(18) having a proper rake angle.

Description

Historic Efund Conduit System {INVERTED SYPHON PIPE SYSTEM}

The present invention relates to a history-funded conduit system, and more particularly, to a history-funded conduit system whose structure is improved so that sediment is not laminated without requiring a separate drainage system.

In general, sewage conduits are buried in the history-funded structure to provide sewage facilities in riverbeds, railways, and heavy traffic roads and underground areas where irreplaceable burial is buried.

Existing historical fund conduits are structures that are not recommended in sewage system standards, but are inevitably installed and used to provide sewage facilities in the aforementioned places.

On the other hand, in order to avoid the history-funded conduit in the above place, there is a method of bypassing the obstacles or installing it inclined downward so as not to obstruct the flow of sewage, but both methods increase the construction period or increase the construction cost. There was such a disadvantage.

In particular, the method of constructing the conduit of the sewage facility inclined downwardly has to be dug deeper and deeper so as not to disturb the flow of sewage, and thus there is a problem in that the construction period and overall costs are increased.

As an example of the conventional history fund conduit, as shown in Figure 3, the main pipe 10 having a substantially "U" shape on both sides of the obstacle (river R) that can not be moved in the middle, and both sides of the main pipe 10 It is composed of inlet pipe 20 and outlet pipe 30 which is connected to each of the inflow and outflow path of the sewage.

The main pipe 10 has both vertical pipes 12 and 14 connected to the inlet pipe 20 and the outlet pipe 30, and a connecting pipe 11 connected horizontally to the lower portion of the vertical pipes 12 and 14. It is composed of.

In addition, the vertical pipe (12, 14) has a structure that is coupled to the inlet pipe 20 and the outlet pipe 30 by coupling coupling, respectively.

In the existing conduit-shaped conduit, because of its structural characteristics, sediment can only be accumulated in the lower part of the main pipe 10, so that an underwater pump is separately installed to discharge the sediment outside, or as shown in FIG. In order to diversify the discharge path, the plurality of connecting pipes 11 connected to both vertical pipes 12 and 14 are arranged in parallel so that the fluids can be joined.

In addition, as an example of a conventional historic funnel conduit, Korean Patent Application No. 1999-16139, "Sediment prevention device for sewage facilities," installs a porous pipe with a high-pressure nozzle in a sewer pipe of a sewage facility installed in a historical funnel shape, and downstream. It has a structure in which a submersible pump is installed in the manhole.

As described above, the conventional history-fund conduit has a problem such as waste of manpower and cost increase in order to separately manage the condensation of a submerged pump or a parallel confluence method due to the structural disadvantage of depositing sediment. .

In addition, if more than a certain amount of foreign matter is introduced into the historic Efund conduit, a lot of sediment is deposited on the lower part of the main pipe, which may cause the original function of the conduit to be lost.

The present invention has been proposed to solve the above problems in view of the above, the object of the present invention is to provide a history-funded conduit system improved in its structure so that sediment is not laminated without having a separate drainage system in a simple structure.

1 is a block diagram showing a history fund conduit system according to the present invention.

2 is a use state diagram showing a sewage flow state of the present invention.

Figure 3 is a cross-sectional view showing a general history fund conduit.

4 is a plan view of main parts of FIG. 3;

Explanation of symbols on the main parts of the drawings

10: host 11: connector

12, 14: vertical

15: bypass tube 18: inclined tube

20: inlet pipe 30: outlet pipe

The present invention for achieving the above object is a main pipe having a connecting pipe and a vertical pipe so as to have a "Y" shaped inverse-shaped shape, and the inlet pipe and the outlet pipe are connected to both vertical pipes, respectively, and the inner diameter is larger than the main pipe. Small by-pass pipe is connected to the lower side of the vertical pipe and the end side of the outlet pipe, respectively, characterized in that the top height of the bypass pipe is installed lower than the water level of the sewage introduced into the vertical pipe.

Another feature of the present invention is that the connecting portion of the vertical pipe and the outlet pipe of the main pipe are interconnected by the inclined pipe having an appropriate inclination angle.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings, the same reference numerals for the same components as the prior art described above, but the fluid flowing through the history-funded conduit of the present invention is a constant flow rate It will be described with an example of the case of sewage without the concern of large deposits.

1 and 2, the constitution system according to the present invention, the configuration is approximately "U-shaped and the main pipe 10 is connected to the inlet pipe 20 and the outlet pipe 30 on both sides. And the bypass sub-pipe 15 connected to the lower part of the main pipe 10 (connecting pipe 11) and the outlet pipe 30 to discharge foreign substances such as sludge.

In more detail, the main pipe 10 is composed of both vertical pipes 12 and 14 and the connecting pipe 11, the vertical pipes 12, 14 are both inlet pipe 20 and the outlet pipe ( 30) to have a structure coupled to the coupling.

In addition, the inclined tube 18 having an appropriate downward inclination angle of about 20 to 40 ° in order to increase the flow rate of the fluid (sewage) at the connection portion between the outlet pipe 30 and the right vertical pipe 14 of the main pipe 10. Are provided and interconnected.

When the inclination angle of the inclined tube 18 is less than 20 °, the fluid flow is not smooth and sufficient potential energy cannot be obtained. On the contrary, when the inclination angle is larger than 40 °, the potential energy is satisfied. However, since the depth of the outflow pipe 30 is required and the outflow pipe 30 is to be buried deeper, it is preferable to have an appropriate downward inclination angle that satisfies potential energy and makes use of construction advantages. .

In addition, the bypass sub-pipe 15 has an inner diameter smaller than that of the main pipe 10 so that the flow rate of the fluid passing therein is faster than that of the main pipe 10. The upper end of the bypass tube 15 is coupled to the inside of the inclined tube 18 through.

The bypass sub-pipe 15 has a height (L₂) from the bottom bottom to the upper end of the connecting pipe 11, the height of the full water level (ℓ₁) of the sewage introduced into the vertical pipe 14, and the head head difference (ℓ₃). It has potential energy.

That is, the bypass sub pipe 15 has an upper end lower than the sewage water level of the vertical pipe 14 so that the potential energy due to water head difference is converted into the velocity energy of the fluid.

In addition, the outlet pipe 30 is buried deeper than the inlet pipe 20 to induce the flow of fluid naturally, the upper surface of the sewage above the vertical pipe 12, 14 of the main pipe 10 Atmospheric pressure P acts.

For reference, the sewage flow rate in the historic fuel conduit is preferably about 0.6 m / sec or more, which is a rate at which the sediment will not be deposited.

Reference numeral "50" indicates an obstacle 50 (river, underground structure, buried material, etc.) located between both vertical pipes 12 and 14, and "60" indicates road pavement.

Referring to the operation of the present invention having such a configuration as follows.

When the sewage funnel conduit system of the present invention is introduced into the main pipe 10 through the inlet pipe 20, it is filled from the bottom of the vertical pipe 12, 14 and the connection pipe 11, and then a constant water level After it becomes the flow to the outflow pipe 30 side.

At this time, the sewage filled above a certain level flows down from the vertical pipe 14 to the inclined pipe 18 and is transferred to another place through the inside of the outflow pipe 30, and a part of the waste water is passed through the bypass sub-pipe 15. It is conveyed to the outflow pipe 30 side.

The sewage pumped through the bypass sub-pipe 15 is operated by the atmospheric pressure acting on the upper side of the vertical pipe 12 and 14, and also by the fast flow rate of the sewage flowing down the inclined pipe 18 side. Negative pressure acts and is pumped from the bottom to the top, so that the flow rate when flowing from the connecting pipe 11 having a large inner diameter to the narrow bypass side pipe 15 is faster than the flow rate in the other main pipe 10. Bernoulli's theorem quote)

The theory of applying Bernoulli's theorem to the historic fund constitution is as follows.

H: Loss head in historic funds conduits

i: Received slope for flow rate in historic Efunds

L: Street of Historic Efunds

V: Flow rate in historic funds

g: acceleration of gravity (9.8 m / sec)

α: The marginal value (3 ~ 5cm) according to the inverse gradient in the historic Efund conduit

β: When the margin is 1.5

Since H = i * L + β * V² / 2g + α,

Accordingly, the velocity (V) of the fluid due to the potential energy generated in the bypass subpipe is

V = √2 * g * α / β-loss head in the adjuvants,

The head loss in the auxiliaries is inflow loss + curve loss * 2 + outflow loss + pipe friction loss, and this is a value that varies depending on the design, so that the head of the loss in the bypass affiliation 15 is constant, and the bypass affiliation 15 is By standardizing the diameter of and the diameter of the main pipe 10, it is possible to calculate the required flow rate for the discharge of the sludge.

The flow rate of the bypass pipe 15 is preferably maintained at a minimum flow rate of 1.0 m / sec or more so that foreign matter such as sludge is discharged together by the flow of the fluid.

As a result, foreign matter such as sludge, which may be deposited on the lower portion of the connecting pipe 11, is sucked together by the flow rate flow on the bypass side pipe 15 side and pumped to the outflow pipe 30 side. As a result, foreign matter is naturally discharged so that the lower portion of the connection pipe 11 does not settle.

For reference, the flow rate of the sewage flowing through the bypass sub pipe 15 has a close relationship with the inner diameter of the conduit and the flow rate.

That is, in the present invention, the position head according to the pipe height difference between the outlet pipe 30 and the vertical pipe 14 is converted into a velocity head so that a negative pressure acts on the outlet pipe 30 side, and the negative pressure is applied to the bypass subpipe ( 15) has a process in which foreign matter such as sludge or small-sized gravel is discharged to the outlet pipe 30 side.

The present invention as described above is not limited to the above-described embodiments, but may be modified as many as possible without departing from the spirit and concept of the present invention.

The present invention as described above is a simple structure, the structure is improved so that the sediment is not laminated in the history fund conduit without requiring a separate drainage, according to the present invention is the bypass side pipe to the outlet pipe side in the lower part of the main pipe The sediment is not deposited by the flow of fluid (sewage) by connecting the.

Accordingly, the present invention can efficiently discharge foreign substances such as sludge even if the historic fund conduit is adopted in the construction section where there is an obstacle, and also does not require separate maintenance in the historic fund conduit, It has a very useful effect to reduce the cost and the consumption of manpower.

Claims (2)

The main pipe 10 having the connecting pipe 11 and the vertical pipes 12 and 14 so as to have an inversely shaped shape, and the inflow pipe 20 and the outflow pipe 30 are formed at both vertical pipes 12 and 14 thereof. In each historical fund consolidation, The bypass sub-pipe 15 having a smaller inner diameter than the main pipe 10 is connected to the lower one side of the vertical pipe 14 and the end side of the outlet pipe 30, respectively. The upper-height of the bypass sub-pipe 15 is installed in the history fund conduit system, characterized in that lower than the height of the surface of the sewage introduced into the vertical pipe (14). 10. The historic fuel conduit system according to claim 1, wherein the vertical pipe (14) of the main pipe (10) and the connection portion of the outlet pipe (30) are interconnected by an inclined pipe (18) having an appropriate inclination angle.