KR101011080B1 - Top-flow for increasing fluid velocity in sewage drina conduit - Google Patents

Abstract

PURPOSE: A top-flow for increasing fluid velocity in a sewage drain conduit is provided to prevent sludge and suspended materials from being piled inside a drain conduit by reduction in the section of a water tank inside the bottom of the drain conduit. CONSTITUTION: A top-flow(100) for increasing fluid velocity in a sewage drain conduit is installed at the inner center of a drain conduit to partition a flow passage into two pieces. The top flow is light and is made of synthetic resin. The side the top flow has the cross section of the triangular shape.

Description

TOP-FLOW FOR INCREASING FLUID VELOCITY IN SEWAGE DRINA CONDUIT}

The present invention relates to a top flow rate increase flow in the conduit to increase the flow rate of sewage flowing inside the conduit so that sludge and suspended solids do not accumulate in the conduit, more specifically, a single flow path in the conduit to the top flow in the center of the conduit By forming the two flow paths, while reducing the cross section of the bottom water passage in the conduit to increase the flow rate according to the rise of the sewage level, and also to guide some of the sewage flowing through each flow path to the vortex passage formed in the top flow vortex Flow rate inside the conduit structure to prevent sediment accumulation in each flow path and to form a flat moving path to mount the imaging equipment on top of the top flow to secure the moving path of the irradiation equipment. It is about increasing topflow.

In general, sewage facilities are planned according to the sewage facility standard according to related laws, and the combined sewage and sewer storms have a minimum flow rate of 0.8 m / sec or more for rainwater sewage planning, and a minimum flow rate of 0.6 m / sec for sewage sewers. It is above.

Although each conduit in Korea differs from region to region, odors are generated due to the accumulation of suspended solids and sludge as they fall below the minimum flow rate. Such sediments are causing problems of deterioration of treated water quality and river pollution.

Due to these problems, there are a number of core maintenance targets that need to be dredged regularly.

Moreover, recently installed conduits are designed to reflect the maximum flow rate, so the sludge and suspended solids are being deposited because a small amount of sewage can not be secured at a minimum flow rate.

In addition, each conduit is to put the survey equipment to dredging the point of excessive accumulation of sediment, this time there was a problem that it is difficult to enter the survey equipment due to the sediment accumulated on the floor.

Therefore, even if the investigation, people have to go in and investigate directly, there was always a risk of safety accidents due to the harmful gas filled in the conduit.

The present invention has been made in view of the above problems, the first object of the present invention is to reduce the cross section of the bottom water passage in the conduit to increase the flow rate of the sewage according to the rise of the water level so that sludge and floats are not deposited inside the conduit It is to provide a top flow increase flow inside the conduit.

The second object of the present invention is to install a single flow path in the conduit to the top flow in the center of the conduit, to form two flow paths while reducing the cross section of the bottom passage in the conduit to increase the flow rate due to the rise of the sewage level, In addition, it is to provide a flow rate increasing top flow inside the conduit of the structure that can prevent the accumulation of sediment in each flow path by generating a vortex by inducing some of the sewage flowing through each flow path to the vortex passage formed in the top flow.

The third object of the present invention is to provide a flow rate increasing top flow inside the conduit of the structure that can secure the movement path of the irradiation equipment by forming a planar movement path that can be mounted on the top of the top flow image photographing irradiation equipment have.

In order to achieve the above object, the flow rate increase topflow inside the conduit according to the first invention of the present invention is installed in the longitudinal direction in the inner center of the conduit having a rectangular cross section so as to increase the flow rate by increasing the sewage water level The top flow divides the flow passage into two conduits; wherein the top flow is triangular in cross section to prevent sludge and sediment accumulation and to minimize the volume occupied by the cross-sectional area inside the conduit, the upper portion of the image acquisition It is characterized in that the planar movement path is formed with a protrusion projecting in the center for mounting and movement of the irradiation equipment.

According to a second invention, in the first invention, the top flow is zigzag at regular intervals with a plurality of vortex passages which are inclined in the discharge direction of the sewage along the width direction to form vortices so that suspended matter and sludge do not accumulate in the conduit. Characterized in that formed.

The third invention, in the first invention or the second invention, the top flow is coupled in multiple stages at regular intervals along the longitudinal direction, characterized in that a plurality of insertion projections and insertion grooves are further formed on the mutual coupling surface.

The fourth invention, in the third invention, one end and the other end of the top flow disposed on the inlet side and the outlet side of the conduit is formed with a head portion, wherein each head portion has a triangular pyramid shape divided diagonally, but the vertex is the center Characterized in that arranged to face.

In the fifth invention, in the second invention, the inlet side of the vortex passage through which the sewage flows is further characterized in that the expansion portion is dug inwardly formed.

According to a sixth invention, in the second invention, a wing for guiding the sewage to the vortex passage is further provided on the inlet side of the vortex passage into which the sewage flows.

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The ninth invention, in the first invention, is characterized in that the topflow has a volume in the range of 5% to 15% relative to the cross-sectional area inside the conduit.

According to the flow rate increase top flow in the conduit of the present invention, by installing a top flow in the center of the conduit, a single flow path is formed in the conduit, thereby forming two flow paths and reducing the cross section of the bottom passage in the conduit, Increasing the flow rate and inducing some of the sewage flowing through each flow path into the vortex flow path formed in the top flow to prevent the accumulation of sediment in each flow path, which does not require regular dredging in conduits. have.

In addition, there is an advantage that can secure the movement path of the irradiation equipment by forming a plane movement path that can be mounted on the top of the top flow imaging equipment.

In addition, it can be installed in the existing pipeline through the manhole, there is an advantage that does not need to expand the separate manhole.

Hereinafter will be described in detail with the accompanying drawings with respect to the flow rate increase top flow inside the conduit according to the present invention.

Example 1

1 is a perspective view of a flow rate increasing top flow inside a conduit according to a first embodiment of the present invention, Figure 2 is an exploded perspective view of Figure 1, Figure 3 is a flow rate installed inside the conduit according to a first embodiment of the present invention Fig. 4 is a cross sectional view taken along line AA of Fig. 3.

As shown in Figures 1 to 4, the present invention increases the flow rate of sewage flowing through the conduit 300 to increase the flow rate of the flow inside the conduit 300 to prevent sludge and floats deposited inside the conduit 300 It is about.

Here, the conduit 300 includes a confluence / classification sewage conduit, confluence / classification sewage conduit and confluence / classification storm drain.

The flow rate increase topflow 100 inside the conduit of the present invention is installed in the longitudinal direction in the inner center of the conduit 300 so as to increase the flow rate of the sewage by reducing the cross section of the conduit in the conduit 300, the flow path in the conduit 300 It functions to partition into dogs.

That is, the top flow 100 is provided by dividing and securing two single flow paths in the conduit 300, thereby providing a structure that can increase the water level of the sewage, thereby increasing the flow rate of the sewage.

Here, the top flow 100 is made of a synthetic resin that is light and strong in corrosion resistance, and has a structure in which the cross section has a triangular shape so as to prevent the sludge and the deposits from accumulating on the side. In addition, since the top flow 100 is light, the top flow 100 is fixed to the bottom surface of the conduit through a coupling means such as an anchor bolt.

When the top flow 100 is constructed such that the maximum allowable flow rate in the conduit 300 is exceeded by 120% when the conduit 300 is constructed, the volume within the maximum flow rate 20% exceeded when installed in the conduit 300. It is preferable to make it occupy, and more preferably, the volume of the cross-sectional area inside the conduit 300 is preferably 5% to 15%.

The top flow 100 may be configured by forming a weight loss space therein, and also can be configured to freely adjust the height by combining the height control plate in the middle portion separately.

In addition, the top flow 100 is coupled to the multi-stage at a predetermined interval along the longitudinal direction, a plurality of insertion projections 140 and the insertion groove 140 is formed on the mutual coupling surface.

That is, the top flow 100 can be adjusted in various ways according to the length of the conduit 300, which is possible to be connected integrally extending through the insertion protrusion 140 and the insertion groove 140.

In addition, a manhole (not shown) connected to the conduit 300 is installed on the ground for investigation of the inside of the conduit 300. The diameter of this manhole (not shown) is standardized to 64.8 cm. Because of this, the top flow 100 should be preceded by a multi-stage coupling that is separated by 55 cm to 60 cm intervals in order to pass through the manhole.

On the other hand, the head portion 130 is formed on one end and the other end of the top flow 100 is disposed on the inlet side and the outlet side of the conduit 300.

This head portion 130 takes the shape of a triangular pyramid half divided diagonally, it is configured so that the vertex points toward the center.

Therefore, by dividing the water stream of the sewage flowing through the head portion in half to guide the two flow paths smoothly, and the two sewage discharged to prevent the vortices generated when combined, the conduit 300 according to the bottleneck phenomenon Provide a structure to prevent the flow rate from slowing down.

Meanwhile, as shown in FIG. 4, the top of the top flow 100 has a structure in which a planar movement path 120 is formed to mount and move the image acquisition research equipment 200.

In addition, the planar movement path 120 further includes a protrusion 121 protruding from the center to prevent deviation of the trajectory of the image acquisition irradiation apparatus 200.

This structure is to photograph the foreign matter or sediment or cracks of the conduit 300 in the conduit 300, to secure a moving path to obtain an image through the irradiation equipment (200).

5 is an operation diagram of the flow rate increasing top flow inside the conduit according to the first embodiment of the present invention.

As shown in FIG. 5, when the sewage flows into the conduit 300, the sewage is divided into half by dividing the sewage into two halves without reducing the flow rate through the head 130 of the top flow 100. Guide to the flow path.

Thus, the sewage flowing into each flow path is increased in flow rate as the water supply section of the conduit 300 is reduced, so that the flow rate is faster.

Then, as the flow velocity increases, the sediment accumulated on each flow path is swept together, and the suspended matter is not deposited.

On the other hand, the sewage discharged to the outside of the conduit 300 may also prevent vortices generated when combined by the head unit 130 to prevent the flow rate in the conduit 300 is slowed due to the bottleneck phenomenon.

Second Embodiment

6 is a perspective view of a flow rate increasing top flow inside the conduit according to a second embodiment of the present invention, Figure 7 is an exploded perspective view of Figure 6, Figure 8 is a flow rate installed inside the conduit according to a second embodiment of the present invention Is an installation diagram of incremental topflow.

As shown in Figs. 6 to 8, the second embodiment includes the first embodiment.

Here, the top flow 100 has a plurality of vortex passages 110 which are inclined in the discharge direction of the sewage along the width direction so as to form a vortex so that the floats and sludges in the conduit 300 are not deposited. It is a structure formed by.

At this time, the vortex passage 110 of the inlet side in which the sewage flows into each of the vortex passages 110 is further formed with an expansion portion 111 which is dug inward to guide the sewage into the vortex passage 110. .

That is, the expansion part 111 increases the inflow width of the vortex passage 110 to guide the sewage flowing along each passage to the vortex passage 110, and the sewage discharged to the vortex passage 110 is a sewage flowing in a straight line. When combined with the vortex to generate a sediment in the conduit 300 will be able to prevent the accumulation.

9 is an operation diagram of the flow rate increasing top flow inside the conduit according to the second embodiment of the present invention.

As shown in FIG. 9, when the sewage flows into the conduit 300, the sewage is divided into two sections by dividing the sewage water in half without reducing the flow velocity through the head 130 of the top flow 100. Guide to the flow path.

Thus, the sewage flowing into each flow path is increased in flow rate as the water supply section of the conduit 300 is reduced, so that the flow rate is faster.

And some of the sewage entered into each flow path is led to the vortex passage 110 through the expansion 111 formed on the inlet side of the vortex passage 110, the sewage discharged along the vortex passage 110 is a straight sewage Vortex occurs when

When the vortex is generated on the discharge side of the vortex passage 110 in this way, the sediment accumulated on each flow path is swept together, and the suspended matter is not deposited.

In addition, since this phenomenon is formed over the entire section of the conduit 300, sediments do not accumulate inside the conduit 300 without dredging the inside of the conduit 300 separately.

On the other hand, the sewage discharged to the outside of the conduit 300 is also to prevent the vortex generated when combined by the head portion 130 to prevent the flow rate in the conduit 300 is slowed due to the bottleneck phenomenon.

Third Embodiment

10 is an installation diagram of a flow rate increasing topflow installed in the conduit according to the third embodiment of the present invention, and FIG. 11 is an operation view of the flow rate increasing topflow inside the conduit according to the third embodiment of the present invention.

First, as shown in FIGS. 10 and 11, the third embodiment includes the first embodiment.

Wherein the top flow 100 is a plurality of vortex passages 110 inclined in the discharge direction of the sewage along the width direction in order to form a vortex so that suspended matter and sludge in the conduit 300 is zigzag at regular intervals It is a structure to be formed.

At this time, the vortex passage 110 in which sewage flows in each vortex passage 110 is configured to further include a wing 112 for guiding the sewage to the vortex passage 110.

That is, the wing 112 is to actively guide the sewage flowing along each flow path to the vortex passage (110).

And, as shown in Figure 11, the wing 112 of the third embodiment is characterized by being able to form a vortex at the inlet side of the vortex passage 110 hit the wing.

As described above, the flow velocity increasing topflow in the conduit of the present invention can be implemented by forming the wings of the expansion part and the third embodiment of the second embodiment together.

In addition, the flow rate increase topflow inside the conduit of the present invention, when installing a separate opening in the conduit, it can be separated into multiple stages at intervals of 1 to 9m or several tens of meters, it can also be installed at a constant interval long as a single piece Of course.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, the scope of the invention should be construed by the claims described to include many such variations.

1 is a perspective view of a flow rate increasing top flow inside a conduit according to a first embodiment of the present invention;

2 is an exploded perspective view of FIG. 1;

3 is an installation diagram of a flow rate increasing top flow installed inside the conduit according to the first embodiment of the present invention;

4 is a cross-sectional view taken along the line A-A of FIG.

5 is an operation of the flow rate increase top flow inside the conduit according to the first embodiment of the present invention,

6 is a perspective view of a flow rate increasing top flow inside a conduit according to a second embodiment of the present invention;

7 is an exploded perspective view of FIG. 6, FIG.

8 is an installation diagram of a flow rate increasing top flow installed in a conduit according to a second embodiment of the present invention;

9 is an operation of the flow rate increase top flow inside the conduit according to the second embodiment of the present invention,

10 is an installation diagram of a flow rate increasing top flow installed inside the conduit according to the third embodiment of the present invention;

11 is an operation diagram of the flow rate increasing top flow inside the conduit according to the third embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: top flow 110: vortex passage 111: extension portion

112: wings

120: plane moving path 121: protrusion 130: head

140: insertion protrusion, insertion groove

200: image acquisition research equipment 210: camera

300: conduit

Claims (9)

Consists of a top flow that is installed in the longitudinal direction in the inner center of the conduit with a rectangular cross section so as to increase the flow rate of sewage to divide the flow path in the conduit into two; The top flow has a triangular cross section to prevent sludge and sediment accumulation and to minimize the volume occupied by the cross section inside the conduit, and the top of which is a flat surface with a protrusion projecting at the center for mounting and moving the image acquisition research equipment. Top flow rate increase flow in the conduit, characterized in that the movement path is formed. The method of claim 1, The top flow is inside the conduit characterized in that a plurality of vortex passages inclined in the discharge direction of the sewage along the width direction is formed in a zigzag at regular intervals to form a vortex so that suspended matter and sludge is not deposited in the conduit Flow rate increase top flow. The method according to claim 1 or 2, The top flow is coupled to the multi-stage at a predetermined interval along the longitudinal direction, the flow rate increase top flow inside the conduit, characterized in that the plurality of insertion projections and the insertion groove is further formed on the mutual coupling surface. The method of claim 3, wherein One end and the other end of the top flow disposed on the inlet side and the outlet side of the conduit is formed with a head portion, wherein each head portion has a triangular pyramid shape divided into half diagonally, the vertex is configured to face toward the center Top flow increase in flow rate inside the conduit. 3. The method of claim 2, The inflow side of the vortex passage into which the sewage flows in is the flow rate increasing top flow inside the conduit, characterized in that the expansion portion is further dug inwardly formed. 3. The method of claim 2, Top flow rate increase flow inside the conduit, characterized in that the wing is further installed on the inlet side of the vortex passage into which the sewage flows. delete delete The method of claim 1, The top flow is a flow rate increasing top flow, characterized in that the volume of the cross-sectional area within the conduit in the range of 5% to 15%.

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