KR200208296Y1 - Drainage trench unit - Google Patents

Abstract

The present invention relates to a drain trench unit, which is integrally formed from the waterproofing concrete (3) into which the reinforcing wire (2) is put, and has a predetermined width (W), a height (T), and a length (L) of a drainage passage ( 4) a bottom portion 10 and side portions 20 on both sides thereof are formed so as to form an upper and lower side light of the outer side 21 of each side portion 20 that is widened toward the lower side. The drainage trench unit 1 is disclosed in which the upper surface 22 of 20 is inclined downward toward the outside. A step S may be formed on the inner surface 23 of each of the side parts 20 to cover the drain glazing 30, and a bottom F may be formed on the bottom 11 of the bottom part 10. Concave-convex 11 may be formed to improve the bonding force with the concrete (C) to be poured in.

Description

Drainage Trench Unit

(Technology)

The present invention relates to a drain trench unit, and more particularly, to a drain trench unit made of concrete which is formed in a parking lot floor or the like to form a drain trench.

(Background)

A drain trench for collecting sewage and discharging it into sewage is usually built on the floor where the sewage needs to be treated in use, such as an indoor parking lot floor. In installing such drainage trenches, it was common to build a drainage trench at a site by directly stacking bricks when placing floor concrete.

5 is a schematic longitudinal cross-sectional view of the drainage trench that is built on site when placing floor concrete; The construction of the conventional drainage trench 100 shown in FIG. 1 forms a trench installation groove 110 having a sufficient width at a position where the drainage trench 100 is to be constructed by using a formwork when pouring the first floor concrete BC1. Next, the angle 120 is supported in parallel on both sides of the trench installation groove 110, and then the bricks 130 are stacked and blocked thereon, and then the secondary bottom concrete BC2 is disposed up to the angle 120. Is poured to have a gradient toward the drainage passage 100, and finally, after waterproofing the inner surface of the drainage trench 100, the mortar (M) is given to the bottom of the drainage passage 100 to have a gradient toward the sump. After applying, the glazing 140 is finally raised on the angle 120 to be completed.

The drainage trench 100 of the field construction method is very complicated and difficult to install, such as installing the angle 120, stacking the brick 130, matching the gradient of the entire drainage trench 100. There is a problem that the work productivity is low. In particular, since it is not easy to adjust the thickness of the mortar (M) for the overall drain trench 100 to match the gradient to the sump well, there are many cases where a reverse gradient occurs everywhere and smooth drainage is not achieved. When the glazing 140 hits the angle 120, the noise is also very severe.

In order to solve the problem of the drainage trench 100 of the field construction method, a technique for building a drainage trench has been developed by fabricating the drainage trench unit as a ready-made product in a factory rather than a construction site in advance. .

6 is an exploded perspective view of the 'drainage passage mold' of Utility Model Publication No. 97-5532 showing an example of a conventional drain trench unit. The conventional drainage mold 200 has a plurality of side members 210 having a cover support portion 211 and an insertion groove 212 and a bottom member 220 having an insertion protrusion 221 to assemble a plurality of parts. Using the piece 231 has a structure to be fixed to the floor by the mold support member 230.

However, although the drainage mold 200 has eliminated the inconvenience of having to build the drainage trench directly at the construction site, the number of parts and the assembly work are complicated, and still require a lot of work time, especially with plastic synthetic resin. Due to the difference in thermal expansion coefficient between the drainage mold 200 and the floor concrete, there is a problem that the drainage mold 200 is easily lifted from the floor according to the temperature change. Due to such a problem, the drainage path mold 200 is not actually applied to the site, and the drainage trench 100 of the complex traditional site construction method as shown in FIG. 5 is still used.

The purpose of the present invention is to solve the problems of the on-site drainage trenches and the conventional drainage trench units that are built on the floor of an indoor parking lot, and the construction work in the field is very simple, easy to match the gradient and durability. It is to provide this excellent drain trench unit.

1 is a perspective view of an exemplary drainage trench unit according to the present invention;

2 is a cross-sectional view of the drain trench unit of FIG.

3 is a perspective view of another exemplary drain trench unit according to the present invention;

4 is a cross-sectional view of the drain trench unit of FIG.

5 is a schematic longitudinal cross-sectional view of a conventional drainage trench constructed in the field when placing floor concrete;

Figure 6 is an exploded perspective view showing an example of a conventional drain trench unit.

<Description of the code | symbol about the principal part of drawing>

1: drain trench unit of the present invention 2: reinforcing wire (2)

3: concrete 4: drainage

10: bottom 11: unevenness

20: side portion 21: outer side

22: upper surface 23: inner surface

30: drainage glazing 40: plastic resin film

C: concrete S: step

F: bottom

According to the present invention, there is provided a drain trench unit integrally formed of waterproofing concrete with reinforcing wires. The drainage trench unit of the present invention is composed of a bottom portion and side portions on both sides thereof so as to form a drainage passage having a predetermined width, height, and length therein, and the outer side surface of each side portion has upper and lower light beams widening toward the lower side. Iii) and the upper surface of each side portion is inclined to lower toward the outside.

It is possible to cover the drainage grating by forming a step in the upper side of the inner side of each side portion, and at least the bottom surface of the bottom portion to form an unevenness to improve the bonding strength with the concrete placed on the floor. .

Hereinafter, the drainage trench unit according to the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are merely illustrative of the drainage trench unit according to the present invention, and are not intended to limit the scope of the present invention.

1 is a perspective view of an exemplary drainage trench unit according to the present invention, FIG. 2 is a cross-sectional view of the drainage trench unit of FIG. 1 in a construction state, FIG. 3 is a perspective view of another exemplary drainage trench unit according to the present invention, and FIG. 3 is a cross-sectional view of the drain trench unit constructed in FIG.

As shown, the drain trench unit 1 according to the present invention is composed of a bottom portion 10 and two side portions 20 integrally formed at both sides thereof to form a drainage passage 4 having a predetermined size therein. As a unit, the reinforcing wire 2 is put into the waterproofing concrete 3, and it is produced by integrally hardening.

The waterproofing treatment of the drain trench unit 1 is to prevent leakage through the drainage channel 4, and a waterproof method widely known in the art is applied. The waterproofing method is not particularly limited, but it can be waterproofed, for example, by adding an appropriate waterproofing liquid when making the concrete 3 for manufacturing the trench unit 1. The reinforcing wire (2) is for reinforcing the strength of the concrete (3), for example, when making the drain trench unit (1) of concrete (3), a wire mesh made by weaving a wire mesh (2) of 5MM diameter in a lattice shape It is injected into the bottom part 10 and the two side parts 20. In the concrete 3, it is preferable to mix fine aggregate (for example, a stone of about 10 mm in diameter) for reinforcement.

As described above, since the drain trench unit 1 according to the present invention is made of the same concrete 3 as the concrete (or mortar: C) to be installed on the floor F, the drain trench unit 1 is constructed on the floor F. When the drain trench unit (1) and the bottom concrete (C) is a complete joint, substantially no cracking or warping occurs.

The size of the drainage path 4 formed in the drainage trench unit 1 of the present invention is determined according to the characteristics of the floor F in which the trench unit 1 of the present invention is constructed, for example, the floor F of an underground parking lot. In the drainage trench having a width of approximately 200MM and a height of 50MM can be constructed, the size of the drainage passage 4 formed in the trench unit 1 of the present invention is also 200mm in width (W) and 50MM in height (T The length L may be about 1,000MM (1M) in consideration of the convenience of carrying, handling and construction.

The drainage trench unit 1 has its side portion 20 in the form of upper and lower light, and its upper surface 22 is inclined so as to go outward. That is, the side surface portion 20 that forms the drainage passage 4 has its inner surface 23 vertically formed, but the outer surface 21 gradually widens downward, and the upper surface 22 of the side surface portion 20 The inner side in contact with the drainage path 4 is high and the outer side is formed low.

The side portion 20 of the drainage trench unit 1 is formed to have a lower side light so that the drainage trench unit 1 is firmly held in the concrete C of the floor F. As shown in FIG. In addition, the outer surface of the upper surface 22 of the side surface portion 20 is formed so that the concrete (C) of the floor (F) is covered on the entire upper surface 22 and the concrete (C) of the floor (F) This is to prevent the joint line between the concrete 3 of the drain trench unit 1 from being exposed.

When the upper surface 22 is formed in a horizontal plane, when the concrete (C) of the bottom (F) is finished to the edge where the outer surface 21 and the upper surface 22 of the side portion 20 meets two concrete (bottom concrete and trench The seam of the unit concrete) is exposed. In order to prevent the connection line is exposed, it can be considered to cover the entire surface (22) with the floor concrete (C) to a predetermined thickness, but the construction work is very complex, such as using a separate formwork.

1 and 2, the width W and the height T of the drainage passage 4 are 200 mm and 50 mm, respectively, and the height ST of the side portion 20 is 80 mm and the inner surface 23 of the side portion 20. The example shows that the angle A formed by the upper surface 22 is 70 degrees, and the angle B formed by the outer surface 21 and the upper surface 22 of the side portion 20 is 130 degrees.

Unlike the open drainage trenches of FIGS. 1 and 2, when the drainage trench unit 1 of the present invention is used to construct a covered drainage trench to which a drainage grating 30 is applied, FIGS. As illustrated in FIG. 4, a step S for covering the drainage grating 30 may be formed on the inner surface 23 of the side surface portion 20. 3 and 4 show a step S having a height of 30 mm and a width of 30 mm so as to cover the glazing 30 having a height of 20 mm and a width of 200 mm. It shows an example formed on both sides, whereby the drainage trench unit 1 of the present invention is formed with a drainage passage 4 covered with the grating (30).

In the drain trench unit 1 according to the present invention, the bottom surface of the bottom portion 10 that is in contact with the concrete (C) placed on the floor (F) to form the concave-convex (11) to improve the bonding force with the bottom concrete (C), respectively It is desirable to. The drainage trench unit 1 is more firmly fixed to the bottom F by the action of the unevennesses 11. Such unevenness may also be formed on the outer side surface 21 of the side portion 20.

In addition, the drain trench unit 1 according to the present invention is a plastic resin film 40 to prevent the floor concrete (C) from falling into the drainage channel 4 in the finishing construction process of the floor (F) to be hardened. It is desirable to be able to ship by taping (see Figure 1) and to remove it after construction is completed.

The drainage trench unit 1 according to the present invention described above is manufactured in large quantities according to specifications using a mold in an automated factory such as a brick factory and supplied to a construction site.

Hereinafter, a method of constructing the drain trench unit 1 according to the present invention on the floor F will be described. First, the concrete (C) is laid on the bottom (F) of the position where the drain trench unit 1 is to be installed, and the drain trench unit 1 is placed thereon. At this time, when the bottom concrete (C) is poured, the bottom concrete (C) is poured to have a gradient toward the sump well, and the drain trench unit (1) is placed on the bottom concrete (C) to length of each drain trench unit (1). Adjust the slope of the entire drain trench by slightly adjusting the direction slope.

Next, a well-known silicone sealant is coated on the connection portions of the two drain trench units 1 to waterproof the connection portions.

Subsequently, the floor F is finished by filling the bottom concrete C up to the finishing height of the floor F on both sides of the drain trench unit 1. At this time, the finish line FF of the bottom (F) to cover all of the upper surface 22 of the side portion 20 to meet the upper end of the inner surface 23 of the side portion 20. In addition, the bottom F, which is finished on both sides of the upper surface 22 of the side portion 20 of the drain trench unit 1, flows toward the drainage path 4 so that sewage from the bottom F flows smoothly into the drainage path 4. It is desirable to have a slight gradient.

Finally, after the construction of the entire drainage trench by the drainage trench unit 1 and the finishing of the bottom F are completed, the plastic resin film 40 taped to the surface of the drainage passage 4 is peeled off. Remove lumps of concrete for floor pouring off the surface.

In addition, in the part where the drain trench unit 1 of unit length (1M) cannot be used as it is, such as a corner part, the drain trench unit 1 is appropriately cut and used for the size of the corresponding part. Accessories such as L-shaped attachments for corners, T-shaped attachments for branch points, and cross-shaped attachments for intersections may be appropriately manufactured and used in accordance with the characteristics of the present invention.

According to the drainage trench unit 1 according to the present invention, since the drainage trench units 1 are continuously connected to the construction position of the drainage trench and connected, the entire drainage trench can be constructed simply by constructing the finishing floor. This is very simple and consequently the construction cost can be reduced.

In addition, the drain trench unit 1 according to the present invention adjusts the slope of the entire drain trench simply by raising the drain trench units 1 on the floor concrete F cast to have a gradient and adjusting a slight slope. It is very easy to fit the gradient.

In addition, the drain trench unit 1 according to the present invention is made of the same concrete (3) as the concrete (C) to be installed on the floor (F), so that the complete junction between the drain trench unit (1) and the bottom concrete (C) In addition, both side portions 20 of the drain trench unit 1 are in the shape of upper and lower light, and the drain trench unit 1 is formed by the unevenness 11 formed on the bottom 11 of the bottom 10. It is firmly fixed to the floor F, and therefore does not easily lift or crack even under the load of the vehicle.

In addition, the drain trench unit 1 according to the present invention is inclined such that the upper surface 22 of each side portion 20 is lowered toward the outside, and the finishing line FF of the bottom F is the upper surface 22 of the side portion 20. ) So as to meet the upper end of the inner side surface 23 of the side portion 20, the connection line between the concrete (C) constituting the floor (F) and the concrete (3) constituting the drainage trench unit 1 is not exposed at all. Do not.

In addition, when the drainage trench unit 1 according to the present invention is applied to the covered drainage trench to which the glazing 30 is applied, even when the glazing 30 and the concrete 3 collide when the vehicle passes, the existing angle Noise also has advantages over bumps.

Claims (3)

The bottom portion 10 is formed integrally with the waterproofing concrete 3 into which the reinforcing wire 2 is inserted, and forms a drainage passage 4 having a predetermined width W, a height T, and a length L therein. And side surfaces 20 on both sides thereof, the outer surface 21 of each side portion 20 being in the form of upper and lower beams widening toward the lower side, and the upper surface 22 of each side portion 20 toward the outside. Drainage trench unit characterized in that the slope is gradually lowered. The drain trench unit according to claim 1, wherein a step (S) is formed above the inner surface (23) of each side portion (20) to cover the drain glazing (30). According to claim 1 or claim 2, The bottom surface 11 of the bottom portion 10 is characterized in that the concave-convex (11) is formed so as to improve the bonding force with the concrete (C) poured on the floor (F). Drainage trench unit.