KR200490922Y1 - Flow control equipment - Google Patents

Abstract

This document discloses a flow control device that can intuitively grasp the operating state and is easy to manage.
The apparatus according to the embodiment comprises: a first body in the form of a cylinder; A second body provided inside the first body to form an independent compartment-The second body is located in the first plate of the semi-circular shape, the upper side of the first plate, the first metering hole A semi-circular second plate formed and a third plate connecting said first plate and said second plate; A third body having a second metering hole and a conveying hole formed therein and rotatably provided in the first body, the third body having a circular plate shape located above the second body; An inlet hole formed in the first body and positioned at a higher point than the third body; And a discharge hole formed in the first body and communicating with the compartment.

Description

Flow control device {FLOW CONTROL EQUIPMENT}

The present disclosure relates to a device capable of adjusting the flow rate (eg, a flow control valve).

This section describes prior art that helps to understand the technical significance of the present disclosure. However, unless clearly stated to the public, it does not mean that the disclosed prior art is known before application.

Wastewater treatment facilities include reactors for treating wastewater by physical, chemical and biological reactions. On the other hand, industrial wastewater and domestic sewage have a large difference in generation amount according to time zones, and when a large amount of wastewater is introduced into the reactor at once, wastewater treatment efficiency may be significantly reduced.

Accordingly, a flow rate control device is provided between the raw water tank in which the raw waste water is stored and the above-described reaction tank so that a predetermined amount of waste water flows into the reaction tank.

The flow control device may be configured in various forms, an example of which can be confirmed through Korea Patent Publication No. 10-1023019.

KR 10-1023019 B1 (2011.03.24. Announcement)

It is to provide a flow control device that can intuitively grasp the operating state, and easy to manage.

The apparatus according to the embodiment comprises: a first body in the form of a cylinder; A second body provided inside the first body to form an independent compartment-The second body, the first plate of the semi-circular shape, located above the first plate, the first metering hole is located inside A semi-circular second plate formed and a third plate connecting said first plate and said second plate; A third body having a second metering hole and a conveying hole formed therein and rotatably provided in the first body, the third body having a circular plate shape located above the second body; An inlet hole formed in the first body and positioned at a higher point than the third body; And a discharge hole formed in the first body and communicating with the compartment, wherein the flow rate entering the compartment is changed according to the overlapping form of the first and second metering holes. .

In addition, the jaw provided on the upper surface of the third body, surrounding the discharge hole may further include a.

In addition, a handle may be further provided on an upper surface of the third body.

The device according to the embodiment is inexpensive in manufacturing cost and can intuitively grasp the operating state (fluid flow) through the open upper part of the first body.

In addition, the apparatus according to the embodiment is easy to maintain due to its structure. For example, even if the first metering hole, the second metering hole, the conveying hole, etc. are blocked by foreign matter, if there is only a long rod, it can be easily repaired and it is also possible to separate and clean each component.

In addition, the apparatus according to the embodiment can simply adjust the flow rate by simply rotating the third body.

1 is a perspective view of an apparatus 100 according to an embodiment.
2 is an exploded perspective view of an apparatus 100 according to an embodiment.
3 is a plan view of the third body 150, the second body 130, and the first body 110.
4 is a diagram schematically illustrating the operation of the third body 150 of the apparatus 100 according to the embodiment.
5 is a state diagram of use of the apparatus 100 according to the embodiment.
6 is a modification of the device 100 according to the embodiment.

Hereinafter, an apparatus 100 according to an embodiment will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an apparatus 100 according to an embodiment, and FIG. 2 is an exploded perspective view of an apparatus 100 according to an embodiment.

1 to 2, the apparatus 100 according to the embodiment includes a first body 110 and a first body 110 formed with an inlet hole 112 and an outlet hole 114. And a second body 130 and a third body 150 provided inside the first body 110 and positioned above the second body 130.

The first body 110, the second body 130, and the third body 150 may be made of a metal material, a synthetic resin material, a cement material, or the like, and in some cases, each of them may be made of a different material. It's okay.

A hollow is formed inside the first body 110 and has a predetermined height in a cylindrical shape in which the upper and lower portions are open.

The second body 130 is fixedly installed inside the first body 110 and forms an independent compartment A. As one example, the second body 130 may be composed of the first plate 132, the second plate 134, and the third plate 136.

The first plate 132 may have a semicircle or an arch shape, and the first plate 132 may cover a portion of an open lower portion of the first body 110.

The second plate 134 may have the same shape as the first plate 132, and is located directly above the first plate 132. In addition, a first metering hole 134a is formed inside the second plate 134.

The third plate 134 is vertically positioned inside the first body 110, and interconnects the first plate 132 and the second plate 134 to each other.

The upper surface of the first plate 132, the lower surface of the second plate 134, the front surface of the third plate 136, and some inner wall surfaces of the first body 110 form the aforementioned compartment A. On the other hand, the conveyance space B is formed in the place which faces the compartment A with the 3rd plate 136 interposed between them.

On the other hand, for ease of maintenance and management, the second plate 134 may be configured to be detachable from the third plate 136, so that the entire second body 130 is detachable from the first body 110. It may be configured.

The third body 150 is in the form of a circular plate, and the second metering hole 152 and the conveying hole 154 are formed inside, and are rotatably provided in the first body 130.

The third body 150 provided in the first body 130 is located above the second body 130. That is, when the second body 130 is composed of the first plate 132, the second plate 134, and the third plate 136, the third body 150 is disposed on the upper surface of the second plate 134. It may be to be seated. Meanwhile, when the rim 134b is further formed on the second plate 134, the third body 150 may be more stably seated on the second plate 134.

When the second body 130 is seated on the third plate 134, the second metering hole 152 is located in the upper region of the compartment A, and the conveying hole 154 is the upper portion of the conveying space B. Is located in the area.

The inflow hole 112 is formed in the first body 112 and is positioned at a higher point than the third body 150.

The discharge hole 114 is formed in the first body 112 and communicates with the compartment A.

The fluid flow in the device 100 according to the embodiment is briefly described.

When the fluid flows into the first body 112 through the inflow hole 112, the introduced fluid drops to the upper surface of the third body 150, and a portion accumulated on the upper surface of the third body 150. The fluid is conveyed through the conveying hole 154 and the conveying space (B), and another part of the fluid is transferred to the second metering hole (152), the first metering hole (134a), the compartment (A), and the discharge hole (114). It is discharged to the outside (the next fixation).

3 is a plan view of the third body 150, the second body 130, and the first body 110, and FIG. 4 schematically illustrates the operation of the third body 150 of the apparatus 100 according to the embodiment. It is a figure which shows.

The apparatus 100 according to the embodiment is configured such that the flow rate entering the compartment A is changed according to the overlapping form of the first metering hole 134a and the second metering hole 152. 3 to 4 show exemplary forms of the first metering hole 134a and the second metering hole 152. The shape of the first metering hole 134a and the second metering hole 152 shown in the drawings is only one example, and a person of ordinary skill in the art may determine the first metering hole 134a without departing from the technical spirit of the present disclosure. ) And the second metering hole 152 may be configured in various forms.

On the other hand, the upper surface of the third body 150 may be further provided with a jaw 156. The jaw 156 surrounds the discharge hole 114. When the jaw 156 is provided in the third body 150, the fluid introduced into the first body 110 may exit the second metering hole 152 a little earlier than the conveying hole 154. do. That is, the water accumulates at a predetermined level in the upper portion of the third body 150, and the flow rate into the compartment A is kept constant, and the risk of foreign matter hardening on the upper surface of the third body 150 is reduced.

In addition, a handle 158 may be further provided on an upper surface of the third body 150. The handle 158 increases the operability of the third body 150. In addition, when the handle 158 is provided on the third body 150, the third body 150 may be easily separated from the first body 110.

In addition, a cover (not shown) may be further provided on the upper portion of the first body 110.

5 is a state diagram of use of the apparatus 100 according to the embodiment.

Referring to FIG. 5, the apparatus 100 according to the embodiment may be installed between the raw water tank TN1 and the reaction tank TN2 of the sewage treatment facility.

Considering that the sewage treatment facility is buried underground, as shown in FIG. 5, when the apparatus 100 according to the embodiment is installed, the user removes a cover (not shown) from the first body 110. Through the open upper portion of the first body 110, the operating state (fluid flow) may be intuitively grasped.

In addition, the user can simply adjust the flow rate discharged to the reaction tank (TN2) by simply rotating the third body (150).

In addition, even if the first metering hole 134a, the second metering hole 152, the conveying hole 154, etc. are blocked by foreign matter, the user pushes a rod or the like into the aforementioned holes 134a, 152, 154. In addition, it is possible to simply remove the foreign matter, it is possible to wash each component separately.

That is, the device 100 according to the embodiment can intuitively grasp the operating state and is easy to manage.

In addition, FIG. 6 is a modification of the apparatus 100 according to the embodiment.

Referring to FIG. 6, the second body 130 may further include one or more blocking plates 138 that partition the compartment A, and the first body 110 may include a plurality of discharge holes 114 and 114 ′. ), A plurality of first metering holes 134a and 134a 'may be provided in the second plate 134, and a plurality of second metering holes 152 and 152' may be provided in the third body 150. In this case, there is an effect that the fluid supplied from the raw water tank or the like can be constantly supplied to the plurality of reaction tanks.

At this time, if the stopper 160, 160 'to block the second metering holes (152, 152') is further provided, it may be able to block the fluid flowing into the specific reaction tank.

Apparatus 100 according to the embodiment described above, may be variously modified (applied) by those skilled in the art without departing from the spirit of the present disclosure.

Therefore, the scope of the present disclosure should be broadly interpreted based on the technical spirit contained in the description of the invention and the drawings.

100: device
110: first body
112: inflow hole
114, 114 ': discharge hole
130: second body
132: first plate
134: second plate
134a, 134a ': first metering hole
134b: Rim
136: third plate
138: blind plate
150: third body
152, 152 ': second weighing hole
154: return hole
156: jaw
158: handle
160, 160 ': stopper
A: Compartment / B: Return Space
-
TN1: Raw water tank / TN2: Reactor / PU: Pump

Claims (3)

A cylindrical first body;
A second body provided inside the first body to form an independent compartment-The second body is located in the first plate of the semi-circular shape, the upper side of the first plate, the first metering hole A semi-circular second plate formed and a third plate connecting said first plate and said second plate;
A third metering hole and a conveying hole formed inside, rotatably provided in the first body, and having a circular plate shape located on an upper portion of the second body;
An inlet hole formed in the first body and positioned at a higher point than the third body; And,
A discharge hole formed in the first body and communicating with the compartment;
According to the overlapping form of the first metering hole and the second metering hole, the flow rate entering the compartment is changed.
The method of claim 1,
The jaw provided on the upper surface of the third body, surrounding the discharge hole; apparatus further comprising.
The method of claim 1,
The upper surface of the third body, characterized in that the handle is further provided.

Images