KR20090034082A - Rainwater drain apparatus having hydraulic rain leader pipe with built-in screw - Google Patents

Abstract

A rainwater drainage system is provided to rapidly discharge the rainwater because the evacuation rate increases when a precipitation increases. A rainwater drainage system is composed of an eaves gutter(12) whose top is opened to collect the rainwater, and a gutter(20) combined to be connected to the eaves gutter. In the gutter, a screw is built in along the longitudinal direction to discharge the rainwater of the eaves gutter.

Description

Rainwater drain apparatus having hydraulic rain leader pipe with built-in screw}

The present invention relates to a rainwater discharge device provided with a rain gutter, and more particularly, to prevent clogging caused by fallen leaves or dust, and built-in screw can be quickly discharged a large amount of rainwater by a hydraulic pressure It relates to a rainwater discharge device provided.

There are two semi-circular barrels and pipes such as eaves gutters, gutters, funnel gutters, decorative gaskets, seal gutters, gutters, and roof drains. More than two are used in combination.

Such storm drains are needed for flat roofs as well as sloped roofs. Its material is usually used by processing galvanized flat stone, but it is not used for a long time due to rust. In recent years, the gasket made of PVC is widely used because it does not cause rust. If the thickness of the gutter is too thin, the gutter cannot be used for a long time.

1 is a view schematically showing a rainwater discharge device of the roof according to the prior art.

Referring to FIG. 1, the rainwater discharge device includes an eave gutter 2 and a gutter 10.

The eaves gutter 2 is a trough which is horizontally installed in the sandwich panel 3 at the end of the eaves of the roof 1 in a semicircular shape of about 10 cm in diameter. In high-end architecture, they are also made into double rectangles with decorations. Here, the sandwich panel (3) is a building member produced in the form of a panel by inserting a heat insulating material between the iron plate.

The rain leader pipe 10 is a vertical trough connected to the eave trough 2, which varies in size depending on the roof area, but in the case of a house having a circular diameter of about 75 mm in diameter and arranged at intervals of about 7 m. You can see a lot.

In addition, although not shown here, the storm drain device is generally further provided with a funnel gutter, a sump, a sump, a hanger, and a roof drain.

The funnel gutter is a funnel-shaped gutter connected between the cornice 2 and the gutter 10. The decorative barrel is disposed on the top of the trough 10 and has a cuboid shape as a decoration. In the case of the double gutter, the gutter is a U-shaped gutter installed by laying down along the roof of the downstairs to connect the water of the gutter of the second floor to the eaves of the downstairs. The groove hanger is made of a belt (帶 形 鐵) is used to fix the cornice (2) to the rafters and the like or to fix the line gutter (10) to the wall. The roof drain (roof drain) is usually installed in a drip port (落水 口) connected to the gutter 10 in the flat roof, which is to prevent the paper or rubbish flow into the gutter 10 to be blocked. It is covered with a hat-shaped cover with several holes.

As described above, the rainwater discharge device according to the prior art has a simple structure in which water flowing from the eaves gutter 2 having a natural gradient descends down the line gutter 10 connected to the lower portion.

The spacing between the plurality of gutters 10 coupled to the eave gutter 2 and the size of the gutters 10 are appropriately determined by the designer according to the construction equipment standards and the rainfall intensity of the region concerned in the past, but at the moment There are many problems in timely coping with the rainwater discharge device such as the above-mentioned natural drainage for precipitation exceeding existing design standards such as heavy rain.

An object of the present invention is to provide a rainwater discharge device that can discharge rainwater quickly by increasing the discharge rate when the precipitation increases.

Still another object of the present invention is to provide a rainwater discharge device that can prevent clogging due to fallen leaves or dust accumulated on the roof.

The present invention to solve the above problems,

Eave gutter to open the upper part to receive rainwater; And

It is coupled to the eaves can communicate with each other to discharge the rainwater of the eaves to provide a rainwater discharge device having a; a line gutter is built in the screw along the longitudinal direction.

According to one embodiment of the present invention, at least a portion of the gutter is disposed at an angle of 5 to 85 ° from the direction parallel to the depth direction of the cornice.

According to another embodiment of the present invention, the first gutter portion and the second vertical gutter portion and the first vertical gutter portion and the second vertical gutter portion arranged in the direction parallel to the depth direction of the eave gutter An inclined trough portion disposed in the depth direction and the inclined direction of the eave trough therebetween, and the screw is disposed in the inclined trough portion.

According to another embodiment of the present invention, the line trough is formed with an inlet for receiving rainwater contained in the eave trough, the inlet is disposed protruding away from the bottom of the eave trough.

According to a further embodiment of the present invention, the rain discharge device, the rain trough cover covering the inlet of the trough is further disposed, the trough cover is disposed spaced from the inlet of the trough.

According to another embodiment of the present invention, the trough cover is formed in a circular or square cap shape, the inlet of the trough is inserted at least partially into the groove portion of the trough cover.

According to another embodiment of the present invention, the gutter cover is partially coupled to the inner wall of the cornice.

According to another embodiment of the present invention, the rainwater discharge device further comprises a net disposed to cover the open portion of the cornice.

According to the present invention, a rainwater discharge device that can discharge rainwater quickly by increasing the discharge rate when the precipitation increases can be provided.

In addition, according to the present invention, rainwater discharge device that can prevent clogging due to fallen leaves and dust accumulated on the roof can be provided.

Next, with reference to the accompanying drawings will be described in detail with respect to the rain discharge apparatus according to a preferred embodiment of the present invention.

FIG. 2 is a view schematically illustrating a rainwater discharge device of a roof according to an embodiment of the present invention, and FIG. 3 is a plan view of FIG.

2 and 3, the rain discharge device according to the present embodiment is provided with a cornice 12 and the trough 20.

The eaves trough 12 is opened to receive the rainwater, the cross section is formed in a semi-circular, U-shaped, or U-shaped. In this embodiment, the cross section of the cornice 12 is formed in a c-shape. The eave trough 12 is disposed to be elongated horizontally or at an angle along the eaves under the eaves of the roof (not shown).

In addition, the mesh 12a may be further disposed to cover the open portion of the cornice 12. Such a net (12a) prevents the falling leaves and dust accumulated on the roof flow into the cornice 12, thereby preventing the eaves 12 to be blocked by them.

 The trough 20 is coupled to the eave trough 12 to discharge the rainwater from the eave trough 12. In this embodiment, the first vertical trough portion 21, the inclined trough portion 22, and the second vertical trough 12 are discharged. It is comprised including the trough part 22. As shown in FIG. However, the present invention is not limited thereto, and the line gutter 20 may have various other configurations.

At one end of the first vertical trough portion 21, that is, at the end of the eave trough 12, an inlet 21 a for receiving rainwater contained in the eave trough 12 is formed. The inlet 21a is disposed in the inner space of the eave trough 12, and specifically, one end thereof is protruded from the bottom so as to be spaced apart from the bottom of the eave trough 12 by a predetermined distance (for example, about 5 cm).

In addition, the trough cover 21b is disposed to cover the inlet 21a. The gutter cover 21b is disposed spaced apart from the inlet port 21a by a predetermined interval (for example, 5 cm). In addition, it is preferable that such a trough cover 21b is formed in a circular or square cap shape, and the inlet 21a is at least partially inserted into the groove portion (concave portion) of the trough cover 21b.

In addition, the trough cover 21b is partially coupled to the inner wall, that is, the inner wall or the bottom of the eave trough 12. In this embodiment, as shown in Fig. 3, the trough cover 21b is coupled to the inner wall of the eave trough 12 by four coupling portions 21b '.

As the rainwater discharge device has the above configuration, the rainwater falling directly on the roof or from the sky flows into the cornice 12 and opens the bottom of the cornice 12 through the gap V of the trough cover 21b. After filling, it is filled up to the vicinity of the inlet 21a and then flows into the first vertical trough 21 through the inlet 21a. On the other hand, the rainwater gradually accumulated without being discharged through the inlet 21a fills up to the upper portion of the trough cover 21b so as to be locked, and the upper portion of the groove of the trough cover 21b is located in the upper portion of the inlet 21a. The air layer A which is not filled with rainwater is formed. This air layer (A) serves to suck the rainwater toward the air layer (A) because its pressure is lower than the water pressure of the rainwater filled in the cornice 12 to lock the gutter cover (21b). Accordingly, in particular, when there is a lot of precipitation so that the sun gutter cover 21b is locked, the rain may be sucked into the inlet 21a by the pressure difference to maximize the rain discharge rate.

On the other hand, the deeper the depth of the cornice 12, the higher the water pressure of rainwater filled in it, the greater the amount of rainwater that the air layer A sucks per hour, so that the design design criteria allow the depth of the cornice 12 to be allowed. It is advantageous to form as deep as possible in.

An inclined trough portion 22 is disposed at one end of the first vertical trough portion 21, that is, at an end opposite to the eave trough 12. This inclined trough portion 22 is 5 to 85 degrees (θ in FIG. 2), preferably 10 to 80 degrees, more preferably 15 to 75 degrees, most preferably from the direction parallel to the longitudinal direction of the eave trough 12. Preferably inclined at 65-75 °. In this way, by arranging the inclined trough 22 inclinedly, the discharge rate of rainwater can be increased. This will be described in more detail later.

The inclined trough 22 has a screw 22a built in its longitudinal direction. The screw 22a is disposed to be fixed to the inner wall of the inclined trough portion 22, and the rainwater flowing into the inclined trough portion 22 through the first vertical trough portion 21 passes through the screw 22a. It plays a role in helping to form the vortex. When the rainwater forms a vortex, because the flow rate is faster, the discharge rate of rainwater can be significantly increased.

A second vertical trough portion 23 is disposed at one end of the inclined trough portion 22, that is, at an end opposite to the first vertical trough portion 21. Rainfall is discharged to the outside through the second vertical trough portion 23.

4 is a view for illustrating the fact that the discharge speed of the rainwater varies according to the arrangement angle of the trough and whether or not the vortex is formed in the rainwater discharge device of FIG.

Referring to FIG. 4, an experiment was performed after filling a half-liter of water in a plastic bottle 30 having a size of 1.5 liters in order to compare the rain discharge rate according to the simple gravity type (a) and the inclined rotary type (b) rain discharge methods. . Initially, in both cases, the inlet of the plastic bottle 30 is upside down, blocked by hand.

First, the water filled in the ordinary plastic bottle 30 of the left (a) took about 20 seconds to drain all the water after removing the lower inlet by hand. Next, when rotating the plastic bottle 30 filled with water in a state inclined at about 70 ° obliquely by the method of the right side (b), it took about 9 seconds to drain all the water. Therefore, it was confirmed that the oblique rotation type (b) was about 2 to 3 times faster than the general gravity type (a).

Hereinafter, a process in which rainwater is discharged through the rainwater discharge device according to the present embodiment will be described in detail with reference to FIG. 2.

First, rainwater falling directly on the roof or in the sky is introduced into the cornice 12 through the net 12a. At this time, fallen leaves and dust are filtered out by the mesh 12a.

Next, the rainwater introduced into the eaves 12 is filled into the bottom of the eaves 12 through the gap V of the trough cover 21b and then flows into the inlet 21a of the trough 22.

If the speed of rainwater flowing into the cornice 12 is greater than the speed of rainwater discharged to the outside through the inlet 21a, that is, if there is a lot of precipitation, the rain gutter cover 21b is locked by the rainwater accumulated. It becomes. In this case, the rainwater flows into the inlet 21a at a higher speed due to the pressure difference between the water pressure of the rainwater and the air layer A.

Rainwater introduced into the inlet 21a flows into the inclined trough 22 through the first vertical trough 21. The rainwater flowing into the inclined trough portion 22 forms a rapid vortex by the appropriately adjusted inclination angle θ and the screw 22a, thereby rapidly increasing the discharge rate of the rainwater.

Rainwater that has passed through the inclined trough portion 22 is discharged to the outside through the second vertical trough portion 23.

 Rainwater discharge device according to the present invention having the configuration as described above, it is possible to discharge the rainwater quickly by increasing the discharge rate of rainwater, especially when there is a lot of precipitation. In addition, the rainwater discharge device according to the present invention is formed with a mesh to cover the open portion of the cornice can prevent the phenomenon such as clogging the cornice by falling leaves or dust.

Although the present invention has been described above with reference to the drawings and embodiments, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. . Therefore, the protection scope of the present invention should be defined by the appended claims.

1 is a view schematically showing a rainwater discharge device of the roof according to the prior art.

2 is a view schematically showing a rainwater discharge device of the roof according to an embodiment of the present invention.

3 is a plan view of the top and bottom of FIG. 2.

4 is a view for illustrating the fact that the discharge speed of the rainwater varies according to the arrangement angle of the trough and whether or not the vortex is formed in the rainwater discharge device of FIG.

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

1: roof 2, 12: cornice

3: sandwich panel 10, 20: gutter

12a: mesh 21, 23: vertical gutter section

21a: inlet 21b: gutter cover

22: inclined trough portion 22a: screw

A: air layer θ: inclination angle

Claims (8)

Eave gutter to open the upper part to receive rainwater; And Rainwater discharge device having a; is coupled to the eaves can communicate with the gutter is a screw along the longitudinal direction to discharge the rainwater of the cornice. The method of claim 1, At least a portion of the gutter is an excellent discharge device, characterized in that arranged inclined 5 to 85 ° from the direction parallel to the depth direction of the cornice. The method of claim 2, A depth direction of the eave trough between the first vertical trough portion and the second vertical trough portion, and the first vertical trough portion and the second vertical trough portion, wherein the line trough is disposed in a direction parallel to the depth direction of the eave trough; An inclined trough portion disposed in an inclined direction, Rainwater discharge device, characterized in that the screw is disposed in the inclined trough portion. The method of claim 1, The rain gutter is formed with an inlet for receiving rainwater contained in the cornice, the rainwater discharge device characterized in that the inlet is projected to be spaced apart from the bottom of the cornice. The method of claim 4, wherein The rain gutter cover is further disposed to cover the inlet of the gutter, the gutter cover is characterized in that the rain discharge device is characterized in that spaced apart from the inlet of the gutter. The method of claim 5, The rain gutter cover is formed in a circular or rectangular cap shape, rainwater discharge device characterized in that the inlet of the sun gutter is inserted at least partly in the groove portion of the sun gutter cover. The method of claim 5, Rainfall discharge device, characterized in that the gutter cover is partially coupled to the inner wall of the cornice. The method of claim 1, Rainwater discharge device further comprises a net disposed to cover the open portion of the cornice.

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