KR100815578B1 - Draining trench unit - Google Patents

Abstract

A drain trench unit is provided to be manufactured not to have a gradient and a counter gradient in the longitudinal direction and to be constructed continuously with optimum or minimum number, and to minimize the formation of dead water and wastewater by increasing the velocity of flowing wastewater such as leachate, dew, etc. in a drainageway of a drain trench unit. A drain trench unit(101) is manufactured to have a ÝÀ-shaped body opened upward having many hollows(103) by inputting inorganic powder materials such as cement and silica powder, asbestos, plasticizer and other compounds, pulping fiber thread such as asbestos and pulp, etc., and dry-mixing the cement, silica powder, asbestos, plasticizer and other compounds in a dry mixing machine, inputting water to the mixture, mixing evenly using a kneader and inputting into an extruding machine and passing through a pug screw, a vacuum chamber, an auger screw, a gate and final dice, wherein a drain groove(102) is formed on the body to form a flow passage for draining off waste water and an incline is formed on the bottom(104) of the drain groove to be inclined downward toward the center to accelerate the velocity of wastewater and to drain off the wastewater rapidly.

Description

Draining trench unit

The present invention relates to a drain trench unit for draining sewage such as leachate, condensate, rainwater, etc., such as an indoor parking lot floor.

In general, drainage trenches for collecting sewage and discharging them into sewage are usually built on the floor where the sewage needs to be treated in use, such as an indoor parking lot floor. It was common to build bricks and build them on site.

The conventional drainage trench 1, which is constructed on-site when the bottom concrete is poured, is the position where the drain trench 1 is to be built using formwork when pouring the first floor concrete BC1 as shown in FIG. Trench trenches 2 of sufficient width are formed in the trenches, and then angles 3 are supported in parallel on the upper sides of the trench mount grooves 2, and then bricks 4 are stacked thereon to block the angles. (3) pour secondary bottom concrete (BC2) to the drainage channel (5) to the position, and finally, waterproof the inner surface of the drain trench (1), and then drain the drainage 5) Apply mortar (M) while giving a gradient to the bottom, and finally finish glazing (6) on the angle (3).

The drainage trench 1 of the field construction method is very complicated and difficult to install, such as installing the angle 3, stacking the bricks 4, and matching the gradient of the entire drainage trench 1. 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) with respect to the overall drainage trench 1 to match the gradient to the sump well, there are many cases where a reverse gradient occurs everywhere and smooth drainage is not achieved.

In order to solve the problem of the drainage trench 1 of the field construction method, a factory for the drainage trench 10 is manufactured as a ready-made product, as shown in FIG. Techniques for constructing drainage trenches have been developed, and in order to mold the drainage trench unit 10 into concrete as described above, the factory casts concrete into the mold and cures the product to finally complete the product.

However, the conventional drainage trench unit 10 is to cast the concrete in the mold, and then install a vibration compaction plate at the bottom of the mold to apply a vibration, so that the structure of the poured concrete is uniform and at the same time the surface is uniform It was possible to prevent the inverse gradient phenomenon.

That is, since the drain trench unit 10 is formed by a vibration, the bottom surface of the drain trench unit 10 is formed into a flat and uniform surface on which no gradient or reverse gradient is formed, and the drain trench unit 10 drains the trench. After construction, when leachate, condensate, etc. are drained in the drainage trench unit, not only was not smoothly drained by the uniform bottom 11, but the flow rate was not smooth, It developed into a problem such as causing a bad odor.

In addition, since the size of the mold for forming the drainage trench unit 10 is limited, the size of the drainage trench unit 10 can only be molded in a limited manner, so that a plurality of such drainage trench units 10 are arranged in the factory. When the construction or the length of the construction drainage path and the length of the drainage trench unit 10 does not match, there was an inconvenience to be constructed after cutting the drainage trench unit 10 to a desired length.

Further, as described above, since a plurality of drainage trench units 10 are connected as shown in FIG. 10) also increased labor costs.

The present invention devised to solve the above problems allows the drainage trench unit to be molded so that the gradient and the inverse gradient are not formed along the longitudinal direction, and at the same time, the body is not limited to the length of one body or in some cases. Drainage trench unit to make the drainage trench unit to be connected by water, and to form a structure that can increase the flow rate of leachate, condensate, etc. in the drainage trench of the drainage trench unit, drainage trench unit to minimize the occurrence of shooter and sewage The purpose is to provide.

The above object is any one of steel fiber, synthetic fiber, glass fiber and carbon fiber made of carbon steel and stainless steel as fiber reinforcement materials and AE agent, AE water reducing agent, waterproofing agent, rust preventive agent, fluidizing agent, and coagulation hardening regulator which are performance improving materials. The cement slurry kneaded with at least one of the cement is continuously extruded from the upper open body so that the drain groove is formed in the longitudinal direction through the mold and cured at high temperature and high pressure, and the bottom surface of the drain groove has a gradient toward the center. By a drain trench unit characterized in that the inclined surface is formed.

The apparatus may further include a plurality of hollow parts formed on at least one of both sides and a bottom of the drain groove of the body, and further include a plurality of protrusions or grooves formed on at least one of both side surfaces and the bottom surface of the body.

As described above, in the present invention, first, since the drain trench unit used for drainage trench construction is extruded and subjected to high temperature and high pressure curing treatment, the present invention is not subject to twist or reverse gradient regardless of specifications (length, width, depth of drainage groove, etc.). As the molding problem does not occur as described above, the drainage trench unit may be molded and manufactured to an optimum length corresponding to the length to be constructed, and thus, there is an effect of minimizing the fear of secondary work due to the linkage construction.

 Second, the inclined surface is formed so that the bottom surface of the drain groove of the drain trench unit forms a gradient toward the central body, to enlarge the cross-sectional area of the drain groove through which the depth of the drain groove and the flow rate flow, and the sewage flows into the center by the slope. According to the present invention, the flow velocity can be increased, so that the drainage of the wastewater can be prevented.

Third, by forming a plurality of hollows in the body of the drain trench unit, greatly reducing the weight of the product to facilitate transport and transportation, as well as to facilitate the work during the linkage construction.

Referring to the configuration and operation of the drainage trench unit according to the present invention as described above with reference to FIGS. 4 and 5 as follows.

First, cement is an important building material that can mix and knead various performance improving agents and excipients together to produce various products having the same strength as rock when cured in a certain mold.

Therefore, using cement, window frames, wall panels, etc. can be produced in a variety of building materials such as continuous extrusion or injection method, of which is used as window frames, wall panels, etc. using an extrusion molding method.

The manufacturing method of the drain trench unit 101 according to the present invention shown in FIG. 4 will be briefly described as follows.

In other words, after adding inorganic powder raw materials such as cement and silica powder and other admixtures such as asbestos and plasticizers, the fiber yarns such as asbestos and pulp are decomposed, and cement, silica doors, asbestos and plasticizers and other admixtures are dry mixed in a dry mixer. do.

As described above, when mixing is completed, water is added to perform wet mixing together with dry mixing. When wet mixing (mixing) is completed, homogeneous mixing is carried out with a kneader, and then fed into an extruder, pug screws, vacuum chamber, auger screw, By allowing the gate and the final die to pass through, the drain trench unit 101 having a plurality of hollow portions 103 and continuously configured as a body of a '└┘' cross section, which is an upper opening type, can be molded by an extrusion molding method.

The extruded drainage trench unit 101 is cut into the required length and width while being moved by the conveyor belt, and is cured at high temperature and high pressure, thereby finally producing the drainage trench unit 101.

In other words, when curing is first performed, physical warpage and surface condition are inspected, and then secondly cut and cured in an autoclave again.

As described above, when the high temperature and high pressure curing of the autoclave is completed, the final product is shipped after undergoing a final processing after various inspections.

The performance improving material kneaded in the present invention refers to asbestos (石,) and the like, such a performance improving material is strong in fire resistance or friction resistant and excellent in chemical resistance, in particular, the maintenance of the shape of the molded article during extrusion molding, cement and It refers to conventional additives that are excellent in adhesion, stable chemical resistance, and the like.

As described above, the drainage trench unit 101 according to the present invention is manufactured by extrusion molding in a desired width, thickness, width and length.

5 is a view illustrating a cross-sectional structure of the waterproof trench unit 101 according to the present invention. As shown in FIG. 5, the body has a structure of '└┘', and a drain groove forming a flow path to drain the sewage thereon. 102 is formed as an upper open type.

Here, the bottom surface 104 of the drain groove 102 is formed with a slope inclined downward toward the center or the center.

Therefore, in the drain trench unit 101 according to the present invention, when the sewage or the like flows into the drain groove 102 of the drain trench unit 101 from the wall surface or the bottom of the structure, the wastewater is rapidly abruptly along the inclined surface. The flow rate is increased by the gradient along the longitudinal direction of the drain groove 102 formed while constructing the drainage trench unit 101 at the same time as flowing into the design is designed to allow the drainage of the sewage quickly.

Here, as shown in FIGS. 4 and 5, the body of the drain trench unit 101 is manufactured by forming a mold such that a plurality of hollows 103 are formed at both sides and the bottom or both sides or the bottom of the drain groove 102. By extruding, the load of the drain trench unit 101 is minimized, and thus, even if the length of the unit product is increased, the product is lighter, so that transportation and transportation can be easily performed, and construction can be performed smoothly.

Here, a plurality of protrusions or grooves (not shown) formed on at least one of both sides and the bottom of the body is formed so that when the concrete is poured, the concrete is intervened into the grooves, or the projections in the cross-sectional structure of the concrete By intervening, it is desirable to strengthen the coupling structure between the drain trench unit 101 and the concrete.

Therefore, in addition to placing concrete at a position spaced a predetermined distance from the outer wall to the drain trench unit 101 shown in FIG. 4 according to the present invention, while constructing the drain trench unit 101 as shown in FIG. The construction is to be formed along the slope at a constant inclination angle so that the sewage is guided to the sump (not shown) to drain.

As a result, even a small amount of sewage has potential energy and kinetic energy toward the central portion C along the inclined surface, thus adding potential energy and kinetic energy to the sewage flowing along the drainage groove 102. As shown, the sewage flowing into the central portion C is joined with the sewage flowing in the drainage groove 102 in the direction of the arrow to increase the flow rate.

In addition, as shown in Figure 5, the drain trench unit 101 according to the present invention, since the inclined surface is formed on both sides in the central portion (C) irrespective of the direction in which wastewater flows into the drain groove 102 At the same time the flow rate can be increased by the slope.

Therefore, the water retention phenomenon of the bottom surface 104 of the drain groove 102 of the drain trench unit 101 can be reduced, thereby preventing the incubation of microorganisms and suppressing the occurrence of odors, thereby creating a sanitary and comfortable environment. You can do it.

1 is a view showing the structure of a conventional drain trench.

Figure 2 is a perspective view showing the structure of a conventional drain trench unit.

3 is a view showing the construction of a conventional drain trench unit.

4 shows a drain trench unit according to the invention.

5 is a view showing a construction structure of a drain trench unit according to the present invention.

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

101: drain trench unit 102: drain groove

103: hollow portion 104: bottom surface of the drain groove

Claims (2)

At least one of steel fiber, synthetic fiber, glass fiber and carbon fiber made of carbon steel and stainless steel, which are fiber reinforcement materials, and AE agent, AE water reducing agent, waterproofing agent, rust preventive agent, fluidizing agent, coagulation hardening regulator and cement The cement slurry kneaded is cured at high temperature and high pressure by continuously extruding the upper open body so that the drain groove is formed in the longitudinal direction through the mold, and the bottom surface of the drain groove is inclined to form a gradient toward the center. A drain trench unit characterized by the above-mentioned. The method of claim 1, The drain trench unit further comprises a plurality of hollows formed on at least one of both sides and the bottom of the drain groove of the body.

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