KR200300519Y1 - Vortex Separator for Combined Sewer Overflows - Google Patents

Abstract

The present invention is designed to remove solids such as grit, sand, and silt contained in sewage, such as rainwater runoff, overflowed water, and combined sewer overflows, and suspended solids such as oil and grease from sewage. The separated upper treated effluent is discharged to the stream and the concentrated sewage is discharged to the sewage treatment plant.

In order to achieve the above object, the solids and suspended solids separator of the present invention, a separator vessel, an inlet pipe for introducing the sewage into the separator vessel, a dip plate installed inside the separator vessel, An annular ventry plate for sealing an upper portion by connecting an outer circumferential surface of the dip plate and an inner circumferential surface of the separator container, an outlet pipe connected to one side of the dip plate, and installed below the dip plate and directed toward the center A concave bent skirt formed inclined, a cone-shaped center cone installed above the bent skirt, a base channel formed in a space between the center cone and the bent skirt, and connected to the base channel. Storage outlet pipe;

Description

Vortex Separator for Combined Sewer Overflows}

The present invention relates to a sewage treatment apparatus, and in particular, separates the suspended solids and suspended solids contained in the waste water (waste water) from the sewage, the vortex for the overflow water discharged to the sewage treatment plant without discharging the solids of a predetermined size or more into the stream Relates to a separator.

Conventional sewage treatment apparatus is mainly used to rotate the sewage containing the solid in the cylindrical separator vessel to drop the solids to the bottom of the separator vessel by gravity, which is a complex flow in the apparatus The inwardly induced effect caused by the pattern is used to push the float to the outlet located in the center of the bottom of the container.

Although the conventional sewage treatment apparatus has a simple structure, there is a problem in that the flow is complicated due to the simple structure of the apparatus. That is, the flow pattern according to the sewage treatment apparatus is divided into a downward spiral flow generated near the outer wall of the apparatus and an upward spiral flow generated near the central portion of the apparatus, and these two spiral flow regions are shear zones. zones). Velocity gradients and vortices occur due to fluid viscosity, boundary layer, and momentum transfer effects between interfaces moving at different speeds, and there is a problem in that uneven axial flow occurs due to the interference between the upward spiral flow and the downward spiral flow.

In addition, the conventional sewage treatment apparatus, as described above, focuses on separating only solid matter from sewage, and does not include a process of separating suspended matter contained in sewage, such as oils and greases contained in sewage. The float was discharged into the river without being filtered.

The problem to be solved by the present invention is to provide a sewage treatment apparatus having a structure that improves non-uniform axial flow, which is a problem in a conventional sewage treatment apparatus, and filters not only solid matter contained in sewage but also floating matter. .

1 is a perspective view of the cut-away vortex type separator separated device according to the present invention.

Figure 2 is a plan view of the vortex-type separator separation device according to the present invention.

Figure 3 is a vertical cross-sectional view of the vortex-type separator separated device for receiving water according to the present invention.

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

1 ... inlet, 2 ... dip plate,

3 ... annulus baffle, 4 ... center baffle,

5 ... top shaft, 6 ... ventury plate,

7 ... center cone, 8 ... base channel,

9 ... benching skirt, 10 ... outlet,

11 ... storage conduit, 12 ... separator vessel.

In order to achieve the above object, the vortex separator for receiving water according to the present invention,

A separator vessel;

An inlet pipe for introducing sewage into the separator vessel;

A cylindrical dip palte located inside the separator vessel;

An annular ventry plate connecting the outer circumferential surface of the dip plate and the inner circumferential surface of the separator vessel;

An outlet pipe connected to one side of the dip plate;

A cone-shaped bending skirt positioned below the dip plate and inclined toward the center;

A center cone positioned above the bend skirt and formed in a cone shape;

A base channel formed in a space between the center cone and the benching skirt;

At the same time the one end is connected to the base channel, the other end is characterized in that it comprises a storage outflow pipe to the outside of the separator vessel.

In addition, in the vortex separator for the overflow water of the present invention, it is preferable that an annulus baffle is formed inside the dip plate.

In addition, it is preferable that the swirl water separator for the overflow water of the present invention further includes a center baffle located inside the dip plate and smaller in diameter than the dip plate.

In addition, in the vortex-type separator for overflowing water according to the present invention, it is preferable that a hole is formed in the center of the central baffle, and a top sahft of a hollow is formed around the hole. It is preferable that a hole is formed in an upper portion of the center cone.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

Figure 1 is a cut perspective view of the vortex-type separator separation device according to the present invention, Figure 2 is a plan view according to Figure 1, Figure 3 is a vertical cross-sectional view according to FIG.

Vortex flow separation type separation device according to the present invention. As shown in FIG. 1, a separator vessel 12 and an inlet pipe 1 formed on one side of the separator vessel 12 are included, and a lower portion of the separator vessel 12 includes a benching skirt 9. , The center cone 7, the base channel 8, and the storage outlet pipe 11 are each formed or installed. Also, inside the upper part of the separator vessel 12. The dip plate 2, the bantry plate 6, and the outflow pipe 10 are formed or installed.

Here, the inlet pipe 1 is tangential to one side of the separator container 12 so as to generate rotational flow in the sewage introduced into the separator container 12 as shown in FIGS. 1 and 2. Installed and communicating with the inside.

Further, as shown in Fig. 1, the dip plate 2 is open at its upper and lower portions, and the side to which the outlet pipe 10 is connected is extended to protrude radially outward, and other attached cavity ( It has a hollow cylindrical shape, located in the upper center of the separator vessel (12). Meanwhile, an annular baffle 3 of a plate shape is preferably installed near the center of the inner circumferential surface of the dip plate 2, and a center baffle 4 is provided at the center of the dip plate 2. In addition, it is preferable that the central baffle 4 is an annular flat plate, as shown in Fig. 1, whose diameter is smaller than the diameter of the dip plate 2, so that the sewage is in the center of the dip plate 2 and the center. It can flow through the space between the baffles 4. In addition, it is preferable that a hole is formed in the center of the central baffle 3, and a top shaft 5 of the cavity is formed around the hole, and the central baffle 4 is formed of the upper shaft ( It is fixed to the dip plate 2 through means (not shown), such as an angle formed above 5).

In addition, the outflow pipe 10, as shown in Figures 1 to 3, is connected to one side that extends to protrude radially outward of the dip plate 2 to discharge the treated upper outflow water into the river.

The ventri plate 6 is an annular plate, one end of which is fixed to the inner surface of the separator vessel 12, and the other end of which is attached to the outer circumferential surface of the dip plate 2, and the outside of the dip plate 12 and the separator vessel. A space sealed upwardly is formed between the insides of (12).

As shown in Figs. 1 and 3, the center cone 7 is provided at the lower center of the separator container 12, and is an upside down cone-shaped baffle, and it is preferable to form a hole in the upper center thereof.

In addition, one end of the bent skirt 9 is fixed to the lower part of the separator container 12, and the other end is formed to be inclined downward toward the center of the separator container so as to be in contact with the lower part of the center cone 4 in a cone shape. An annular base channel 8 is formed in a baffle and a space where the bottom of the bent skirt 9 and the center cone 4 meet each other.

Meanwhile, the storage channel 11 is connected to the base channel 8, and the other end of the storage channel 11 is connected to a wastewater treatment plant (not shown).

Hereinafter, the operation of the sewage solids and suspended solids separating apparatus according to the present invention will be described with reference to the drawings.

If a small amount of sewage is introduced into the separator through the inlet pipe (1), the inflow of sewage flows out through the reservoir outlet pipe (11), because the level of the influent sewage is not high, where the solids of gravity As a result, the solids are collected together with the concentrated sewage through the reservoir outlet pipe along the inclined surface of the benching skirt 9, and the suspended solids float on the upper surface of the sewage so that they fall out of the separator. Can't get out

When the amount of sewage introduced due to heavy rain or the like increases, the sewage introduced by the influence of the inflow pipe 1 connected tangentially to the separator vessel 12 generates a rotational flow, and a spiral flow pattern is generated in the sewage in the separator vessel. Occurs.

At this time, the cone-shaped central cone 7 reduces the distance between the free surface of the sewage and the bottom surface of the sewage, thereby inducing an upward flow to occur in the center portion of the separator container 12. Accordingly, in the flow pattern, the descending spiral flow on the outside of the dip plate 2 and the rising spiral flow on the inside thereof are generated, and the velocity of the sewage is zero in the shear zone where the two flows meet. This causes the flow to come to a standstill, where the dip plate 2 is located in the shear zone to separate the external downward spiral flow and the internal upward spiral flow. Thus, interference between the rising spiral flow and the falling spiral flow is prevented so that the flow of sewage is stabilized, and the occurrence of turbulent flow is minimized, which improves undesirable nonuniform axial flow.

However, as shown in FIG. 1, a hole is preferably formed in the upper portion of the center cone 7, through which the sewage flows into the space between the separator container 12 and the benching skirt 9. As such, the storage capacity of the separation device can be increased.

The sewage introduced through the outlet pipe 1 undergoes a descending spiral movement outside the dip plate 2, and then undergoes a rising spiral movement inside the dip plate 2, followed by work of the dip plate 2. It is discharged to the river through the outlet pipe 10 connected to the side.

At this time, the solid contained in the sewage flows along the inclined surface while falling on the inclined surfaces of the benching skirt 9 and the central cone 7 installed in the lower portion of the separator container under the action of gravity while undergoing the flow in the branch container. It is lowered, collected in the base channel 8, and discharged to the sewage treatment plant together with some sewage through the storage outlet pipe 11.

In addition, suspended matter such as oil contained in the sewage floats on the surface of the sewage, and the inner circumferential surface of the separator vessel 12 and the outer circumferential surface of the dip plate 2 and the ventri plate 6 are caused by the action of centrifugal force due to the rotational flow generated in the sewage. Trapped in the space formed by).

Therefore, the sewage discharged through the outflow pipe 10 is discharged to the river because it is relatively clean water from which solids and suspended solids have been removed, and the sewage discharged through the storage outflow pipe 11 includes a lot of solids, and thus, the sewage treatment plant. Induced and purified.

An annular baffle 3 and a central baffle 4 are preferably formed at the inner circumferential surface and the central portion of the dip plate 2, and the annular baffle 3 and the central baffle 4 are formed on the dip plate 2. In the inner part, the sewage rises and increases the flow path of the sewage until it is discharged through the outlet pipe 10, and serves to assist the separation of the solids by blocking the relatively light solids rising with the sewage.

In addition, as shown in Fig. 3, it is preferable to provide an upper shaft 5 of the cavity around a hole formed in the center of the central baffle 4, wherein the upper shaft 5 is a separator container 12. By supplying air into the inside of the separator, the pressure inside the separator vessel 12 is kept the same as the outer area, and the spiral flow is formed around the upper shaft 5 to assist the smooth flow of sewage. .

As described above, the vortex separator for water overflow according to the present invention separates the solids and suspended solids contained in the sewage from the sewage, and the sewage introduced into the sewage flows smoothly, so the separation efficiency is excellent. In addition, since there is no movement part, there is no fear of breakdown and the like, and the maintenance cost is also low.

Claims (5)

In the vortex separator for overflow water for separating solids and suspended solids in sewage, the vortex separator, A separator vessel 12; An inlet pipe (1) for introducing sewage into the separator vessel (12); A cylindrical dip plate (2) located inside the separator vessel (12); An annular ventry plate 6 connecting the outer circumferential surface of the dip plate 2 and the inner circumferential surface of the separator container 12; An outlet pipe 10 connected to one side of the dip plate 2; A conical bent skirt 9 positioned below the dip plate 2 and inclined toward the center; A center cone 7 positioned above the bend skirt 9 and formed in a cone shape; A base channel (8) formed in a space between the center cone (7) and the benching skirt (9); One end is connected to the base channel (8), and the other end is a storage outlet pipe (11) facing out of the separator vessel (12); Overflow vortex separator characterized in that it comprises a. The method of claim 1, Said dip plate (2) is a swirl type separator for overflowing water, characterized in that an annular baffle (3) is formed on the inner circumferential surface thereof. The method according to claim 1 or 2, The inside of the dip plate (2), characterized in that the central baffle (4) is smaller than the diameter of the dip plate (2) is located, vortex type separator for overflow water. The method of claim 3, A hole is formed in the center of the center baffle (4), the vortex separator for the overflow water, characterized in that the upper shaft (5) of the cavity is formed around the hole. The method of claim 1. The central cone (7), vortex-type separator for overflow water, characterized in that the hole is formed in the upper portion.