KR101397628B1 - Flap valve apparatus having double links - Google Patents

Abstract

The present invention relates to a dual rotary link type flap valve. An end of the flap valve is coupled to the front surface of the upper side of a terminal unit by a hinge, and the other end of the flap valve is coupled to the both ends of a flap by a hinge to configure a connection unit which guides the opening and closing of the flap to block the outside water from flowing inside by closing the flap. The flap also easily opens when the water level of the inside and the outside differs by the flexible operation of the connection unit which uses a dual rotary link to configure the upper and lower portion. A support unit is formed on the front surface of the dual rotary link, and an adjustment pole which couples the center portion of the support unit with screws is arranged to move the connection unit to a body in the horizontal direction to rotate the adjustment pole to adjust the water-tightness of the flap by moving the connection unit to the body in the horizontal direction.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a flap valve,

More particularly, the present invention relates to a flap which is turned up and down with a body coupled to a terminal opening of a pump discharge port or a channel to form a flap, and when the external water level rises above the water level, When the water level rises above the water level, the opening moment of the flap is small even if the water level difference between the inside and outside water is small, so that the flap is brought close to the body side by the water pressure generated by the water level difference. Link type flap valve in which a dynamic link is formed and the internal water is easily drained to the external side so as to be opened / closed without power.

As shown in Figs. 1 and 2, the conventional flap valve comprises a connection rod and a hinge in a circular end opening of a discharge port or a channel of a pump, and the upper part of the flap is inclined to the inner water side by about 7 degrees to 10 degrees. The flap valve is configured to be closed with the body by the self weight of the flap, so that all loads acting on the flap act on the upper shaft, and the water pressure generated by the inner and outer water level difference acts on the flap, And when the outer water level is higher than the water level, the flap is closed to block the reverse flow of the water on the inner water side, and if the water level is higher than the outer water level, the flap is opened and is used to naturally dampen the water.

In such a flap valve of the prior art, the flap for opening and closing the body vertically and vertically is usually a one-door type having one flap up to 900 mm in diameter, and since the opening and closing load is more than 1,000 mm, (Gate type). Such a flap valve is arranged such that the body and the flap are inclined at an upper portion of about 7 ° to 10 ° such that the weight of the flap normally comes into close contact with the body, and when the water level rises in the closed flap, So that the flap is more closely contacted to the body side so that the exponent is formed, thereby making it suitable for closing the flap valve by focusing on prevention of reverse flow of the foreign water to the internal water side.

However, such a prior art flap valve has a protruding length (L = D x Cos (?), Where L: flap length) of the flap by arranging the upper part of the flap at about 7 to 10 inclination as shown in Fig. , D: flap diameter, and: inclination angle) is about 336 mm in the case of a one-door type having a diameter of 900 mm, there is a problem that a flap valve can not be installed in a place where the installation space is narrow.

In the prior art flap valve, the flap self weight Gw is concentrated only on the upper hinge so that the distance L between the upper hinge and the load acting point becomes longer and the moment (M = Gw x L, The upper hinge is broken at the time of closure, or the index rubber, which is inserted into the flap, is damaged due to frequent impact with the body, resulting in poor index.

The flap valve of the related art has a problem that the flap is not opened well when the horizontal component force Hix generated due to the water level on the water side is larger than the horizontal component force Gwx of the flap self weight Gw (Hix <Gwx) , There is a problem in that natural drainage is difficult.

Particularly, in the flap valve disposed in the discharge port end portion of the pump, the frictional loss with respect to the fluid flow of the internal water becomes very large, so that the discharge pressure of the pump must be increased by the lost amount. There was a problem.

When the flap material is changed to HDPE instead of steel material in order to reduce the horizontal force Gwx of the flap weight Gw, the tensile strength of the HDPE material is about 1 / 3, the specific gravity is decreased, but the thickness is increased, so that the horizontal component force Gwx can not be significantly reduced. The flap valve, which is composed of HDPE ash and installed on the coast, is not easy to break due to high wave pressure like a typhoon due to insufficient stiffness, causing frequent flooding damage on the domestic side due to backwash of sea water. Life cycle cost is rather increased, resulting in uneconomical problems.

In addition, the conventional flap valve can not control the stop water of the flap valve during use after installation, so that there is a problem that when the index is not reliably maintained, foreign water can not be prevented from flowing backward to the inside water side through the flap valve.

Further, in order to solve such a problem, the motor is coupled to the flap valve so that the motor can be reliably opened and closed up and down. However, this conventional method is not only expensive, but also can not constitute a power transmission device for a two-door flap valve, and the protrusion length of the flap is extended to 560 mm for a diameter of 1,500 mm, And power generation equipment is required. When such a device fails to operate smoothly due to a failure or a power failure, it can not be driven.

Korea Utility Model Registration No. 20-0243409

SUMMARY OF THE INVENTION It is an object of the present invention to solve such a problem, and it is an object of the present invention, which is devised to solve such a problem, that when the water level rises above the water level, the opening moment of the flap is easily leaked by the organic action of the upper shaft, And to provide a double-link ring type flap valve capable of allowing natural drainage to the outside water side.

Another object of the present invention is to provide a double-link ring type flap valve in which a friction loss with respect to a fluid flow of a domestic water in a flap valve disposed in a pump discharge channel is minimized.

It is still another object of the present invention to provide a double-link link type flap valve that can be easily adjusted in the field so that the flap valve can keep the index of the flap valve securely while the flap valve is in use.

Another object of the present invention is to provide a double-link ring type flap valve which prevents the upper hinge from being broken or the exponential rubber from being broken by the impact of the flap against the body when the flap valve is closed.

It is still another object of the present invention to provide a double-link floating flap valve in which the protruding length of the flap is removed to minimize the installation space.

It is still another object of the present invention to provide a double-link ring type flap valve which is easy to open and close even if the flap is made of a steel material or a stainless steel material having high rigidity.

Still another object of the present invention is to provide a double-link floating flap valve which can be easily opened and closed even at a small water level without a separate power unit.

In order to achieve the above object, the double-link ring type flap valve of the present invention, which is devised to attain the above object, forms a flap so as to be vertically open and closed with the body at a discharge port of a pump or a round terminal opening of a duct, A flap valve for opening and closing an outlet portion of a terminal portion with a water pressure generated according to an outside water level, the flap valve having a first end hinged to an upper shaft on both sides of an upper portion of a body, A connection unit hinged to both sides of the central portion by a lower shaft and guiding the upper and lower shafts to connect with each other by a double link so that the flaps can be opened and closed and a connection unit installed and connected to the connection unit, And a watertightness adjusting unit for moving the unit toward the body so as to adjust the closing of the flap and the body.

In order to achieve the same object, the double-strand dynamic-link type flap valve of the present invention, which is devised in order to achieve the same object, has a flap formed in a discharge port of a pump disposed in a water channel, A two-port type flap valve for opening and closing an outlet portion of a terminal portion with a water pressure generated in accordance with an inner and a outer water level, the flap valve having a first end hinged to a top end of a top portion of a body, An upper connecting unit hinged by a lower shaft supporting a load of the upper flap and guiding the upper flap to be opened and closed by connecting the upper shaft and the lower shaft by an upper link so as to double rotate, And the other end is hinged to a lower shaft supporting the load of the lower flap, and the other end is hinged to the lower shaft supporting the load of the lower flap, A lower connecting unit for connecting the upper and lower shafts to each other so as to open and close the lower flap by connecting the upper and lower shafts to each other by a lower link so as to double rotate the lower shaft and the lower shaft; And an upper watertightness adjusting unit and a lower watertightness adjusting unit for moving the upper connecting unit and the lower connecting unit toward the body to adjust the closing of the upper flap and the lower flap and the body.

Another aspect of the double-link floating flap valve of the present invention is that the connecting unit includes a top shaft coupling for supporting the up-and-down rotation of the flap on a front surface extending to both sides of the top of the body in an open / close relationship with the flap, And a lower shaft connected to the lower end of the double-stranded link and supporting the load of the flap and connected to the lower end of the double-stranded link and supporting the up-down rotation of the double- A double shaft coupling which is rotatably connected to the upper shaft coupling shaft at one end and is connected to the lower shaft coupling shaft and a shaft which is hinged to the upper shaft coupling shaft and the double shaft coupling to support the rotation of the double shaft coupling; And a lower shaft which is hinged to the lower shaft coupling and the double rotor link to support the load of the flap, and a double-link is formed between the upper shaft installed on the body and the lower shaft installed on the flap So as to guide opening and closing of the flap.

Another feature of the double-strand dynamic-link type flap valve of the present invention is that the watertightness adjusting section has a support rod formed on the front surface of the double-stranded link, a control rod which is screwed into the center of the support rod is disposed, The connection unit is horizontally moved to the body side so as to adjust the closing of the flap and the body.

Another feature of the double-link floating flap valve of the present invention is that the upper connecting unit is provided on a front surface extending to both sides of an upper portion of a body in an open / closed relationship with the upper flap, A lower link provided at a lower portion of the upper link for supporting a load of the upper flap and supporting the up and down rotation of the upper link, an upper link connected to the upper link, An upper shaft hinged to the upper shaft link and hinged to the upper link to support the rotation of the upper link, a hinge shaft hinge coupled to the lower shaft shaft and the upper link to support the rotation of the upper link, And a lower shaft.

Another feature of the double-strand dynamic-link type flap valve of the present invention is that the upper water tightness adjusting portion is provided with an upper support rod on the upper surface of the upper link and an upper control rod which is screwed into the central portion of the upper support rod, And the upper connecting unit is horizontally moved to the body so as to adjust the closing of the upper flap and the body.

Another feature of the double-link floating flap valve of the present invention is that the lower connecting unit is provided on the front surface extended to both sides of the center of the body in the open / close relationship with the lower flap, A lower link provided at a lower portion of the lower link to support a load of the lower flap and to support the up and down rotation of the lower link, a lower link having one end rotatably coupled to the upper axle coupling and the other end connected to the lower axle coupling, An upper shaft hinged to the upper link and a lower link to be hinged to the lower link and hinged to the lower link and the lower link to support the lower link, And an extended lower shaft.

Another feature of the double-strand dynamic-link type flap valve of the present invention is that the lower watertightness adjusting section is provided with a lower support rod on the front surface of the lower link and a lower adjustment rod which is screwed into the center of the lower support rod, And the lower connecting unit is horizontally moved to the body side by rotating so as to adjust the closing of the lower flap and the body.

Another aspect of the double-link ring type flap valve of the present invention is that the upper link connecting rod is coupled to the upper flap and both ends thereof are hinged to the lower shaft coupling formed on the lower side of the upper link, And the upper flap is closed on the body side by the weight of the connecting rod and the upper flap.

Another aspect of the double-link ring type flap valve of the present invention is that the lower link connecting rod is coupled to the lower flap and both ends thereof are hinged to the lower shaft coupling formed on the lower side of the lower link, And the lower flap is closed on the body side by the weight of the connecting rod and the lower flap.

Another feature of the double-strand dynamic-link type flap valve of the present invention is that the flap is connected to the outer water side of the flap in a lattice form of a transverse steel and a longitudinal stiffener, and the transverse steel and the longitudinal stiffener are configured to form a vacuum with the flap .

Another feature of the double-strand dynamic-link type flap valve of the present invention is that the upper flap and the lower flap are coupled in a lattice form to the outer side of the upper flap and the lower flap in a lattice form, Is configured to provide a vacuum to the upper flap and the lower flap.

In the present invention as described above, the unit load acting on the flap is reduced to about 1/2 by constituting the upper and lower shafts of the connecting unit, and when the outer water level rises above the water level, the water pressure When the water level rises above the external water level, the opening moment of the flap is increased by the lower shaft and the double shaft link by the lower shaft and the lower shaft by the double shaft connection It is an economical flap valve that can be opened / closed without power by organically draining the domestic water to the outside water easily.

Further, in the circular flap valve disposed in the pump discharge channel, the friction loss with respect to the fluid flow of the domestic water is minimized, so that the discharge pressure of the pump can be lowered and the required power of the pump motor can be lowered.

Further, since the flaps are suspended vertically, the protruding length L of the flaps is removed, thereby minimizing the installation space, thereby increasing the applicability.

The present invention has the advantage of easy maintenance since the flap valve can be easily adjusted in the field so that the flap index can be reliably maintained during use after installation.

In addition, since flap material is made of steel or stainless steel material, it has high tensile strength and can withstand high wave pressure like typhoons. It is made of corrosion resistant material so that it does not damage flood damage caused by flap valve damage and has a longer durability than synthetic resin. The cycle cost is economical.

Also, the flap valve can be opened / closed without a separate power unit, and the valve can be easily opened and closed even at a small water level due to the water pressure (non-power) generated by the inside / outside water level of the flap valve.

1 is a side view showing a closed state of a two-door flap valve using a conventional technique.
2 is a front view showing a closed state of a two-door flap valve using a conventional technique.
3 is a perspective view showing a closed state of a single-type double-double-link link type flap valve according to the present invention.
4 is a front view showing a closed state of a single-tooth double-double link link type flap valve according to the present invention.
5 is a side view showing a closed state of a single-type double-double-link link type flap valve according to the present invention.
FIG. 6 is a perspective view showing a closed state of a two-port double-link link type flap valve according to the present invention. FIG.
7 is a front view showing a closed state of a two-port double-link link type flap valve according to the present invention.
8 is a perspective view showing an open state of a double-double-double-link link type flap valve according to the present invention.
9 is a side view showing the closed state of the double-double double-link link type flap valve according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a perspective view showing a closed state of a one-door double-double link link type flap valve according to the present invention, FIG. 4 is a front view showing a closed state of a single- Fig. 6 is a perspective view showing a closed state of a two-port double-link link type flap valve according to the present invention, and Fig. 7 is a cross- FIG. 8 is a perspective view showing an open state of a two-port double-stratified-link type flap valve according to the present invention, and FIG. 9 is a perspective view showing a double- 2 is a side view showing a closed state of a double-gate double-stranded link type flap valve.

As shown in Figs. 3 to 9, the double-strand flap link type flap valve of the present invention first constitutes the body 11 in the discharge port of the pump disposed in the water channel or the round terminal opening of the channel, And a flap 12 which opens and closes vertically.

The flap valve 10 is disposed in a lattice shape so as to be suitable for various loads acting on the flap 12 and the longitudinal stiffener 14 and the transverse stiffener 15 as a reinforcing material forming a vacuum on the outer water side of the circular flap 12, It is preferable to form a reinforcing member so as to form a vacuum with the reinforcing member 12. On the water-repellent side of the flap 12, the flap 12 is joined to the body 11 by means of an exponential rubber 13 so as to be indexed when closed.

As shown in Figs. 3 to 5, the one-port type double-stranded double-link type flap valve is provided with an upper shaft coupling hole 22 on the entire surface extending to both sides of the upper portion of the body 11, A lower shaft coupling member 26 for supporting the load of the flap 12 and supporting the up-and-down rotation of the double-link link 24 is formed. The upper shaft 21 is hinged to the upper shaft coupling 22 and the lower shaft 25 is coupled to the upper shaft 21 and the lower shaft 25 via a double- The link 24 is hinged to form a connection unit 20.

3 to 5, the one-piece connecting unit 20 includes an upper shaft 21, a upper shaft coupling 22, a lower shaft 25, a lower shaft coupling 26 and a double- And a link 24.

The upper shaft coupling member 22 is disposed on both sides of the upper portion of the body 11 and the upper shaft 21 is hinged so that the flap 12 is normally closed by its own weight at normal times.

A double-link 24 is disposed between the upper shaft 21 and the lower shaft 25 to form a link. A lower shaft 25 is coupled to the center of the outer side of the flap 12 and a lower shaft coupling 26 is disposed on the double coupling 24 to hinge the lower shaft 25. Between the upper shaft 21 and the lower shaft 25, both ends of the double-acting link 24 are hinged to each other to constitute a link.

3 to 5, the watertightness adjusting unit 40 includes two side support rods 41 formed on the front surface of the double-stranded link 24, The rod 42 is disposed at a position to horizontally move the connection unit 20 toward the body 11 and is disposed to horizontally move the connection unit 20 toward the body 11 by rotating the adjustment rod 42.

The longitudinal stiffener 14 and the transverse stiffener 15 which are the reinforcing members forming the vacuum on the outer water side of the flap 12 are arranged in a lattice form so as to be suitable for various loads acting on the flap 12, Respectively. The longitudinal stiffener 14 and the transverse stiffener 15 may be arranged in a lattice form using ordinary stiffeners.

6 to 9, the upper flap 18 and the lower flap 19, which are opened and closed with the body 11, are arranged vertically, and the upper flap 18 and the lower flap 19 are arranged vertically, The upper link 27 is provided at the lower end of the upper link 27 and the upper link 27 is provided at the lower end of the upper link 27. [ Thereby constituting a lower shaft coupling hole 26a for supporting the up-and-down rotation. The upper shaft 21a is hinged to the upper shaft coupling hole 22a and the lower shaft coupling 25a is connected to the lower shaft coupling hole 26a. And an upper link 27 connected to the upper and lower shafts 21a and 25a by a double rotating link is hinge-connected to constitute the upper connecting unit 30. [ An upper shaft coupling hole 22b for supporting the up-and-down rotation of the lower flap 19 is disposed on the front surface extending to both sides of the central portion of the body 11 in the open / closed relationship with the lower flap 19, A lower shaft coupling portion 26b that supports the load of the lower flap 19 and supports the up and down rotation of the lower link 28 is formed. The upper shaft 21b is hinged to the upper shaft coupling hole 22b and the lower shaft coupling 25b and the lower shaft coupling hole 26b are connected to the lower shaft coupling hole 26b. And a lower link 28 connected to the upper shaft 21b and the lower shaft 25b by a link rotating in a double direction is hinged to constitute a lower connecting unit 31. [

As shown in Figs. 6 to 9, the upper connecting unit 30 of the two-port double-stranded link type flap valve includes a top shaft 21a, a top shaft fitting 22a, a bottom shaft 25a, And is composed of a coupling hole 26a and an upper link 27.

The upper shaft coupling hole 22a of the upper connecting unit 30 is disposed on the upper portion of the body 11 and the upper shaft 21a is hinged so that the upper flap 18 is normally closed by its own weight.

The upper shaft 21a and the lower shaft 25a constitute an upper link 27. A lower shaft coupling hole 26a for supporting a load of the upper flap 18 and supporting the up and down rotation of the upper link 27 is coupled to a lower portion of the upper link 27, And a lower shaft 25a which extends axially of the upper link connecting rod 16 coupled with the lower shaft connecting rod 18 is engaged. Both ends of the upper link 27 are hinged to each other to form a link between the upper shaft 21a and the lower shaft 25a and the upper link 27 is hinged to the upper link link bar 16, 10) is closed, the upper flap (18) is closed to the side of the body (11).

6 to 9, the upper watertightness adjusting portion 50 includes upper and lower side upper supports 51 on the front side of the upper link 27, The upper adjustment rod 52 is disposed at a position to horizontally move the upper connection unit 30 toward the body 11 and horizontally moves the upper connection unit 30 toward the body 11 by rotating the upper adjustment rod 52 .

The longitudinal stiffener 14 and the transverse stiffener 15 which are the reinforcing materials forming the vacuum on the outer water side of the upper flap 18 are arranged in a lattice form so as to be suitable for various loads acting on the upper flap 18, Or alternatively, the longitudinal stiffener 14 and the transverse stiffener 15 may be arranged in a lattice form as ordinary stiffeners.

6 to 9, the lower connecting unit 31 of the two-port double-stranded-link type flap valve includes a top shaft 21b, a top shaft fitting 22b, a bottom shaft 25b, And includes a lower shaft coupling hole 26b and a lower link 28.

The upper shaft coupling hole 22b is disposed at a central portion of the body 11 and the upper shaft 21b is hinged to the upper shaft coupling hole 22b such that the lower flap 19 is normally closed by its own weight.

The upper shaft (21b) and the lower shaft (25b) constitute the lower link (28). A lower shaft coupling hole 26b for supporting the load of the lower flap 19 and supporting the up and down rotation of the lower link 28 is coupled to the lower portion of the lower link 28, And a lower shaft 25b which is axially extended with the lower link connecting rod 17 coupled with the lower link connecting rod 19 is engaged. Both ends of the lower link 28 are hingedly coupled to each other between the upper shaft 21b and the lower shaft 25b to form a link and the lower link 28 is hinged to the lower link connecting rod 17, 10) is closed, the lower flap (19) is closed to the side of the body (11).

6 to 9, the lower watertightness adjusting unit 60 includes a lower side support rod 61 formed on the front surface of the lower link 28 and a lower side support rod 61 joined to the center of the lower support rod 61 by screwing The lower control rod 62 is disposed at a position where the lower connection unit 31 is horizontally moved to the body 11 side and the lower control rod 62 is rotated to horizontally move the lower connection unit 31 toward the body 11 .

The vertical stiffener 14 and the transverse stiffener 15 which are vacuum stiffeners are arranged on the outer water side of the lower flap 19 in a lattice shape so as to be suitable for various loads acting on the lower flap 19, And a vacuum. The longitudinal stiffener 14 and the transverse stiffener 15 may be arranged in a grid shape.

The driving method of the double-link floating flap valve thus constructed will be described below.

3 to 5, when the flap 12 and the connecting unit 20 including the stiffener are connected to the upper shaft 21 and the lower shaft 25 at the time of closure of the single- The exponent rubber 13 and the body 11 installed in the flap 12 are kept closed with each other while balancing with the action point. In this state, when the water level on the outside water rises, the water pressure acting on the water level pushes the flap 12 toward the body 11 to prevent the reverse water flow of the water on the water side due to the closing of the waterproof rubber 13 and the body 11 . At this time, the point of action of the load acting on the flap 12 is divided into the upper shaft 21 and the lower shaft 25 so that the flap 12 is smoothly closed.

3 to 5, the flap 12 including the stiffener is connected to the upper shaft 21 and the lower shaft 21, as shown in Figs. 3 to 5, when the water level rises above the water level due to the discharge of the pump, All the load acting on the flap 12 is dispersed to half by the upper shaft 21 and the lower shaft 25 with the subsidiary shaft 25 acting as a point of action and is easily opened by the action of the double-

The flap 12 and the body 11 can be easily closed on the spot by rotating the control rod 42 formed on both sides of the flap 12 and horizontally moving the connection unit 20 toward the body 11 have.

6 to 9, the upper flap 18 including the stiffener and the upper connecting unit 30 are connected to the upper and lower shafts 21a and 25a, respectively, The lower flap 19 and the lower connecting unit 31 balance the upper shaft 21b and the lower shaft 25b by the point of action and an index The rubber 13 and the body 11 are kept closed with each other. The water pressure acting on the water level pushes the upper flap 18 and the lower flap 19 toward the body 11 so that the water flows from the lower end to the upper end Thereby preventing backward flow of the water of the outside water.

Even when the flap valve 10 is vertically suspended when the flap valve 10 is closed, the upper flap 18 is supported by the weight of the upper link connecting rod 16 and the lower flap 19 is naturally lifted by the weight of the lower link connecting rod 17 (11).

6 to 9, the upper flap 18 and the lower flap 19, which include the stiffener (not shown), are closed when the water level rises above the level of the water due to the discharge of the pump or the like and the flap valve 10 is opened All the loads acting on the upper flap 18 and the lower flap 19 are divided by the upper shafts 21a and 21b and the lower shafts 25a and 25b into 1/2 And is easily opened by the double linking action of the upper link 27 and the lower link 28 after dispersing.

The upper and lower connecting rods 52 and 62 formed on the front surface of the upper link 27 and the lower link 28 are rotated to connect the upper connecting unit 30 and the lower connecting unit 31 to the body 11 so that the closing of the upper flap 18, the lower flap 19 and the body 11 can be easily adjusted in the field.

The present invention has the following advantages.

First, according to the present invention, when the outside water level rises above the domestic water level, the flaps 12, 18, 19 are brought into close contact with the body 11 side by the water pressure generated due to the inside / outside water level difference, And when the water level rises above the external water level, the opening moment of the flaps 12, 18, and 19 is dispersed to 1/2 by the upper and lower shafts 21 and 25, The flap valve 10 is an economical flap valve 10 that is actuated by the upper link 27 and the lower link 28 to easily drain and discharge natural water to the outside.

Second, the friction loss of the flap valve 10 disposed in the pump discharge channel is minimized, so that the discharge pressure of the pump can be lowered and the required power of the pump motor can be lowered.

Third, since the flap 12, 18, and 19 are constructed so as not to increase the number of the flap valves 10 due to the horizontal component of their own weight, they are very economical.

Fourth, since the flap valve 10 can be easily adjusted in the field so that the index of the flap valve 10 can be reliably maintained during use after installation, it has an advantage of easy maintenance.

Fifthly, since the flaps 12, 18, and 19 are vertically suspended, the projecting length of the flaps 12, 18, and 19 is removed to minimize installation space to increase applicability .

Sixth, the flaps 12, 18 and 19 are made of steel or stainless steel so that they have high tensile strength and are resistant to high wave pressure like typhoons and are made of a material resistant to corrosion, It eliminates side flood damage and is more durable than synthetic resin, so life cycle cost is economical.

Seventhly, the flap valve 10 can be opened and closed without a separate power unit, and the flap valve 10 can be easily opened and closed even at a small water level difference by the water pressure (non-dynamic force) generated by the inside / outside water level of the flap valve 10 Thereby simplifying the installation and facilitating maintenance.

10: flap valve 11: body
12: flap 13: index rubber
14: longitudinal stiffener 15: transverse steel
16: upper link connecting rod 17: lower link connecting rod
18: upper flap 19: lower flap
20: connecting unit 21: upper shaft
21a: Upper shaft 21b: Upper shaft
22: upper shaft coupling hole 22a: upper shaft coupling hole
22b: Upper shaft coupling hole 24:
25: Lower shaft 25a: Lower shaft
25b: lower shaft 26: lower shaft coupling hole
26a: Lower shaft coupling hole 26b: Lower shaft coupling hole
27: upper link 28: lower link
30: upper connection unit 31: lower connection unit
40: watertight adjuster 41: support
42: adjusting rod 50: upper water tightness adjusting part
51: upper support 52: upper adjustment rod
60: Lower watertight adjuster 61: Lower support
62: Lower adjustment rod
Gx: Flap self weight Gwx: Horizontal part force of flap self weight
Hix: Horizontal component of water pressure L: Extrusion length of flap

Claims (12)

A flap is formed so as to be vertically pivotally opened and closed with respect to the body at a discharge port of a pump disposed in a water channel or a circular terminal opening of a pipeline to open and close the discharge port or the opening portion with a water pressure generated by the inner and outer water level of the flap In the door flap valve,
And a lower end hinged to a lower shaft 25 provided on both sides of the flap 12 so that the upper end of the flap 12 is hinged to the upper side of the upper portion of the body 11, (20) which is rotated about the upper shaft (21) and the lower shaft (25) to guide the shaft (21) and the lower shaft (25)
And a watertightness adjusting unit (40) installed in the connecting unit (20) and pushing the flap (12) toward the body (11) to adjust the closing of the flap (12) and the body (11) Dynamic link flap valve.
A flap is formed so as to be vertically pivotally opened and closed with respect to the body in a discharge port of a pump disposed in a water channel or a round terminal opening of a pipeline to open and close the discharge port or opening portion with a water pressure generated in accordance with the inner and outer water level of the flap In the door flap valve,
One end is hinged to both sides of the upper portion of the body 11 in an open and closed relationship with the upper flap 18 and the other end is hingedly connected to the upper link connecting rod 16 coupled to the upper flap 18, 18 are pivoted about the two hinges to guide the opening and closing operations of the upper connecting unit 30,
One end of which is hinged to both sides of a central portion of the body 11 in an open and closed relation with the lower flap 19 and the other end is hinged to a lower link connecting rod 17 coupled to the lower flap 19, 19) are pivoted about the two hinges so as to open and close the lower connecting unit 31,
The upper flap 18 and the lower flap 19 are pushed to the side of the body 11 so that the upper flap 18 and the lower flap 19 and the body 11 And an upper watertightness adjusting unit (50) and a lower watertightness adjusting unit (60) for adjusting the closing of the upper and lower watertightness adjusting units (50, 50).
The connector according to claim 1, wherein the connection unit (20)
An upper shaft coupling 22 for supporting the up-and-down rotation of the flaps 12 on the front surface extending to both sides of the upper portion of the body 11 in an open / closed relationship with the flaps 12,
A double-stranded link 24 which is rotatably coupled to the upper shaft coupling 22 at one end and connected to the flap 12 at the other end,
A lower shaft coupling 26 coupled to the lower end of the double-stranded dynamic link 24 and connected to the flap 12 to support the load of the flap 12 and to support the up-down rotation of the double-
A double-stranded link 24 which is rotatably coupled to the upper shaft coupling 22 at one end and connected to the lower shaft coupling 26 at the other end,
An upper shaft 21 hingedly coupled to the upper shaft coupling hole 22 and the double shaft coupling 24 to support the rotation of the double shaft coupling 24,
And a lower shaft (25) which is hinged to the lower shaft coupling (26) and the double-phase link (24) and supports the load of the flap (12)
Wherein a double-acting link (24) is formed between the upper shaft (21) and the lower shaft (25) to guide the opening and closing of the flap (12).
The water-tightness adjustment unit (40) according to claim 1,
A control rod 42 is disposed on the front surface of the double-core dynamic link 24 and coupled to the center of the support rod 41 by screwing. The control rod 42 is rotated to rotate the connection unit 41 20) to the side of the body (11) so as to adjust the closing of the flap (12) and the body (11).
The connector according to claim 2, wherein the upper connecting unit (30)
An upper shaft coupling hole 22a provided on a front surface extending to both sides of the upper portion of the body 11 in an opening and closing relation with the upper flap 18 to support a vertical rotation of the upper flap 18,
A lower shaft coupling hole 26a provided under the upper link 27 to support the load of the upper flap 18 and to support the up and down rotation of the upper link 27,
An upper link 27 rotatably coupled to the upper shaft coupling hole 22a at one end and connected to the lower shaft coupling hole 26a at the other end,
An upper shaft 21a hinged to the upper shaft coupling hole 22a and the upper link 27 to support the rotation of the upper link 27,
A lower shaft 25a hinged to the lower shaft coupling hole 26a and the upper link 27 to support the rotation of the upper link 27 and to extend the upper link connecting rod 16 coupled to the upper flap 18, Wherein the flap valve is configured so that the flap valve is closed.
3. The watertight container according to claim 2,
An upper control rod 51 is formed on the front surface of the upper link 27 and an upper control rod 52 coupled to the central portion of the upper support rod 51 by screwing is disposed, (30) is horizontally moved toward the body (11) so as to adjust the closing of the upper flap (18) and the body.
The connector according to claim 2, wherein the lower connecting unit (31)
An upper shaft coupling hole 22b provided on a front surface extending to both sides of a central portion of the body 11 in an open / closed relationship with the lower flap 19, for supporting a vertical rotation of the lower flap 19,
A lower shaft coupling hole 26b provided under the lower link 28 to support the load of the lower flap 19 and to support the up and down rotation of the lower link 28,
A lower link 28 rotatably coupled to the upper shaft coupling hole 22b at one end and connected to the lower shaft coupling hole 26b at the other end,
An upper shaft 21b hinged to the upper shaft coupling hole 22b and the lower link 28 to support the rotation of the lower link 28,
The lower link 28 is hinged to the lower shaft coupling member 26b and the lower link 28 to support the rotation of the lower link 28 and the lower link connecting rod 17 coupled to the lower flap 19, The flap valve being configured to include a plurality of flap valves.
[3] The apparatus according to claim 2,
A lower support rod 61 is formed on the front surface of the lower link 28 and a lower control rod 62 is coupled to the center of the lower support rod 61 by screwing, and the lower control rod 62 is rotated, (31) is horizontally moved toward the body (11) so as to adjust the closing of the lower flap (19) and the body (11).
The method of claim 5,
The upper link connecting rod 16 is coupled to the upper flap 18 and both ends thereof are hinged to a lower shaft coupling hole 26a formed on the lower side of the upper link 27, And the upper flap (18) is closed on the side of the body (11) by the weight of the connecting rod (16) and the upper flap (18).
The method of claim 7,
The lower link connecting rod 17 is coupled to the lower flap 19 and both ends thereof are hinged to a lower shaft coupling hole 26b formed on the lower side of the lower link 28, And the lower flap (19) is closed on the side of the body (11) by the weight of the connecting rod (17) and the lower flap (19).
The flap according to any one of claims 1, 3 and 4,
A transverse steel member 15 and a longitudinal stiffener member 14 are joined in a lattice shape on the outer water side of the flap 12 and the transverse steel member 15 and the longitudinal stiffener member 14, And is configured to be sealed to form a vacuum between the transverse steel (15), the longitudinal stiffener (14) and the flap (12).
The top flap (18) and the bottom flap (19) according to any one of claims 2 to 5,
A transverse steel member 15 and a longitudinal stiffener member 14 are joined in a lattice shape on the outer water side of the upper flap 18 and the lower flap 19 and a transverse steel member 15 and a longitudinal stiffener member 14 Is joined to one face of the upper flap 18 and the lower flap 19 to form a closed vacuum between the transverse steel 15, the longitudinal stiffener 14 and the upper flap 18 and the lower flap 19. [ Wherein the flap valve is a double flap link type flap valve.

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