KR102543052B1 - Drainage Facilty Without Backfill - Google Patents

Abstract

The present invention relates to a drainage facility without backfilling, and more particularly, since the process of floor curing and formwork installation is not required, the construction time can be shortened, and the scour phenomenon can be prevented without the need for a backfilling process. , for drainage without backfilling.

Description

Drainage facility without backfill and construction method {Drainage Facility Without Backfill}

The present invention relates to a drainage facility without backfilling, and more particularly, since the process of floor curing and formwork installation is not required, the construction time can be shortened, and the scour phenomenon can be prevented without the need for a backfilling process. , drainage facilities without backfilling and their construction methods.

In general, a drainage facility such as a drain pipe is installed to exclude sewage or rainwater caused by living or business or water for irrigation. These drainage facilities are irrigation facilities constructed to allow sewage, rainwater, or irrigation water to flow by being constructed on a flat or slightly sloped slope.

In addition, at the edge of the road, drainage facilities such as drainage pipes are installed at certain intervals to drain rainwater on the road. The edge of the bridge also has these drainage facilities.

These drainage facilities are designed to ensure smooth drainage, especially during frequent rainfall in the summer. If drainage is not performed, rainwater collects on roads or bridges, resulting in hydroplaning and causing traffic accidents.

However, conventional drainage facilities have a problem in that the inflowing surface water permeates into the loose soil layer on the back of the distribution facility, and the underground infiltration water is blocked by the concrete wall of the drainage facility and flows in the direction of the slope, reducing stability and collapsing the bottom surface.

In other words, when rainfall occurs, most of the rainfall permeates into the ground at the top, flows out as surface water flowing along the surface, and flows down along the road or the surface in a short time and is safely drained through drainage facilities, but the back of the drainage facilities is backfilled with loose The soil layer is formed and the concrete wall is formed, making it difficult to drain smoothly.

In this way, the infiltration water that has permeated into the ground on the side of the road or slope slope meets the rear surface of the drainage facility while flowing along the slope. It causes a scour phenomenon that forms a gap between the drainage facility and the ground.

In this way, the infiltration water that causes the scour phenomenon stays in the lower ground of the drainage facility for a long time even if the flow rate is small, weakening the ground. However, there is a problem that damage to drainage facilities eventually leads to road collapse or slope collapse.

In order to prevent this, Patent Registration No. 10-1650285 discloses a gutter installed on the slope of a ridge or incision and into which surface water flows down the surface, a gutter buried in the ground located directly below the gutter, and the gullet. Including the surface layer improvement formed between the gutter and the gutter, it is intended to prevent the scour phenomenon caused by the underground penetrating water and the collapse accident of the slope by draining the underground penetrating water through the culvert.

However, the above prior art has problems in that it is difficult to excavate, high cost is required, and construction period is long because a separate culvert must be buried in the ground directly below the drainage facility.

KR 10-1650285 BI 2016.09.16.

An object of the present invention is to provide a drainage facility without backfilling that can be completed within 4 days, including curing time, because the construction time is small because the process of installing and removing the formwork is not required, and the thickness of the cement mortar is thin.

In addition, another object of the present invention is to provide a drainage facility without backfilling that can prevent a scour phenomenon occurring at a backfilling position without requiring a backfilling process.

In addition, another object of the present invention is to spray the porous structure layer 70 by supplying a high-pressure hose and an air nozzle from a flat land to a drainage facility, so that there is no backfill that can be operated simply. to provide drainage.

In addition, another object of the present invention is to provide a drainage facility without backfilling capable of improving strength and durability after curing the fast-setting polymer cement mortar by using the three-dimensional honeycomb porous structural layer 70.

In addition, another object of the present invention is to provide a drainage facility without backfilling in which the amount of mortar administered to the same area is reduced because sufficient strength is exhibited even when mortar is adsorbed only to the honeycomb porous structural layer (70).

In addition, an object of the present invention is to lower the peripheral edge of the upper part of the drainage facility at an angle and finish with soil on it, so that even if rainwater penetrates into the soil, the penetration of rainwater by the cement mortar combined with the porous structure layer 70 It is to provide a drainage system without backfill that can suppress the

An object of the present invention is to be made of a flexible material and can be installed in contact with the ground formed by excavation, and the space between the ground and the drainage pipe can be minimized by combining the shape of the strongly built-up ground with the drainage pipe as it is. It is to provide a drainage facility without backfill that can strongly support the lower part of the drainage facility.

Another object of the present invention is to provide a drainage facility without backfilling that can be applied even when a crack occurs in a part of an already installed drain pipe and is repaired.

In order to achieve the above object, the present invention provides the following means.

The present invention, the step of leveling the ground (S 10); First nonwoven fabric 10 / first adhesive 20 / waterproof film 30 / second adhesive 40 / second nonwoven fabric 50 / third adhesive according to the shape of the bottom surface 80 formed by leveling the ground (60)/cutting the drainage pipe body 90 in which the porous structure layer 70 is integrated (S 20); Placing the drain pipe body 90 on the bottom surface 80 formed by leveling the ground (S 30); By fixing the drain pipe body 90 to the bottom surface 80 using the fixing means 75, the valley 81, the valley upper side 82 and the valley upper side edge 83 of the bottom surface 80 and the above Contacting the first nonwoven fabric 10 of the drain pipe body 90 face to face (S 40); Spraying a fast setting type polymer cement mortar 71 on the porous structure layer 70 (S50); and forming the drainage facility 100 by curing the fast-setting polymer cement mortar 71 (S60).

The rapid curing type polymer cement mortar 71 sprayed on the porous structure layer 70 of the present invention is sprayed using a high-pressure hose and an air nozzle.

In the present invention, the edge ground extending from the upper side surface 82 of the valley of the bottom surface 80 slopes downward as it moves away from the upper side surface 82 of the valley, and the first nonwoven fabric 10 of the drain pipe body 90 It is inclined downward to make face-to-face contact with the edge extending downwardly inclined from the bone upper side surface 82.

The drainage pipe body 90 of the drainage facility construction method without backfilling of the present invention includes a first nonwoven fabric 10; A first adhesive 20 applied to the first nonwoven fabric; a waterproof film 30 laminated on the first adhesive; A second adhesive 40 applied to the waterproof film; a second nonwoven fabric 50 laminated to the second adhesive; a third adhesive 60 applied to the second nonwoven fabric; a porous structure layer 70 laminated on the third adhesive; and fast-setting polymer cement mortar 71 sprayed on the porous structure layer; Including, but the first nonwoven fabric 10 is formed of 100 ~ 300g per 1㎡, the first adhesive 20 is applied by spraying an amount of 5 ~ 20g per 1㎡, the waterproof film 30 The thickness of is 0.1 ~ 0.5mm, the second adhesive 40 is applied by spraying an amount of 5 ~ 20g per 1㎡, the second nonwoven fabric 50 is formed of 100 ~ 300g per 1㎡, the The third adhesive 60 is applied by spraying an amount of 5 to 20 g per 1 m2, and the thickness of the porous structure layer 70 is 10 to 30 mm.

The porous structure layer 70 of the present invention is formed in a three-dimensional honeycomb structure and uses polyethylene.

The first adhesive 20, the second adhesive 40, and the third adhesive 60 of the present invention use at least one selected from the group consisting of acrylic adhesive, urethane adhesive, epoxy adhesive, and silicone adhesive, and the waterproof The film 30 uses at least one selected from the group consisting of polyurethane, polybutylene terephthalate, polyethylene glycol, polytetramethylene glycol, HDPE (High Density Polyethylene), and bentonite, and the fast-hardening polymer cement mortar (71 ) contains 50-65% by weight of fast-setting cement mixture, 25-40% by weight of polymer mixture, and 5-15% by weight of aggregate, and the fast-setting cement mixture contains 50-60% by weight of ultra-fine cement and 10-20% blast furnace slag % by weight, 10 to 20% by weight of calcium carbonate, 5 to 10% by weight of aluminate fastening agent, 1.0 to 2.0% by weight of aluminate expanding agent, 1.0 to 2.0% by weight of fluidizing agent, 1.0 to 2.0% by weight of dispersing agent, 1.0 to 2.0% by weight of antifoaming agent %, 0.1 to 0.5% by weight of shrinkage reducing agent and 0.1 to 0.2% by weight of fiber reinforcing material, and the polymer mixture contains 80 to 90% by weight of any one resin selected from acrylic resin or SBR resin, and 0.1 to 10% by weight of pigment. , Antifoaming agent 0.5 ~ 1% by weight, dispersing agent 0.5 ~ 1% by weight, thickener 0.5 ~ 1% by weight, water reducing agent 0.5 ~ 1% by weight, hydration retardant 0.5 ~ 1% by weight, smoothing agent 1 ~ 2% by weight, shrinkage reducing agent 1 -2% by weight, 3-5% by weight of aluminum stearate and 1-2% by weight of ethylene glycol.

The drainage facility construction according to the present invention has the advantage of requiring less construction time because it does not require the process of installing and removing formwork, and can be completed within 4 days including curing time due to the thin thickness of the cement mortar.

In addition, the present invention does not require a backfilling process, and thus has an effect of preventing a scour phenomenon occurring at the backfilling position.

In addition, the present invention has the advantage of being able to work simply because it can be sprayed on the porous structural layer 70 by supplying a high-pressure hose and an air nozzle from a flat land to a drainage facility.

In addition, the present invention has the advantage of improving strength and durability after curing the fast-setting polymer cement mortar by using the three-dimensional, honeycomb-shaped porous structure layer 70 .

In addition, the present invention has an advantage in that the amount of mortar applied to the same area is reduced because sufficient strength is exhibited even when mortar is adsorbed only to the honeycomb porous structure layer 70 .

In addition, the present invention lowers the upper peripheral edge of the drainage facility at an angle and finishes with soil on top of it, so that even if rainwater penetrates into the soil, the porous structure layer 70 and cement mortar combined with it suppresses the penetration of rainwater There are advantages to doing so.

The present invention is made of a flexible material and can be installed in face-to-face contact with the ground formed by digging, and the shape of the strongly built-up ground can be combined with the drainage pipe as it is to minimize the space between the ground and the drainage pipe, resulting in drainage It has the effect of strongly supporting the lower part of the facility.

The present invention has an effect that can be applied even when a crack occurs in a portion of an already installed drain pipe and is repaired.

1 is a perspective view of a drain pipe body 90 according to an embodiment of the present invention,
2 is a state diagram of forming a drainage facility 100 by spraying a fast curing polymer cement mortar 71 on a drainage pipe body 90,
3 is a state diagram in which the drain pipe body 90 is placed on the ground leveled floor,
4 is a state diagram in which a drainage facility 00 is installed,
5 is a cross-sectional view of the drain pipe body 90 placed on the bottom surface 80,
6 is a partial repair state diagram in which the drain pipe body 90 is placed on the crack of the general drain pipe,
7 is a process diagram of constructing the drainage facility 100.

Hereinafter, the present invention will be described in detail.

1 is a perspective view of a drain pipe body 90 according to an embodiment of the present invention.

First, referring to FIG. 1, a drainage facility 100 without backfilling according to the present invention will be described.

The drainage facility 100 without backfilling of the present invention,

a first nonwoven fabric (10);

A first adhesive 20 applied to the first nonwoven fabric 10;

a waterproof film 30 laminated on the first adhesive 20;

A second adhesive 40 applied to the waterproof film 30;

a second nonwoven fabric 50 laminated to the second adhesive 40;

a third adhesive 60 applied to the second nonwoven fabric 50;

a porous structure layer 70 laminated on the third adhesive 60; and

a fast-setting polymer cement mortar 71 sprayed on the porous structural layer 70;

includes

The first non-woven fabric 10 serves to prevent the waterproof film 30 from being damaged or torn by stones, tree branches, etc.

The first nonwoven fabric 10 is preferably formed in an amount of 100 to 300 g per 1 m 2 .

The first adhesive 20 serves to adhere the first nonwoven fabric 10 and the waterproof film 30.

The first adhesive 20 is preferably applied by spraying an amount of 5 to 20 g per 1 m 2 .

As the first adhesive 20, at least one selected from the group consisting of acrylic adhesive, urethane adhesive, epoxy adhesive, and silicone adhesive may be used.

The waterproof film 30 serves to increase watertightness by preventing soil collapse, soil inflow, and scour phenomena during surface water, rainwater, and rainy season.

The waterproof film 30 preferably has a thickness of 0.1 to 0.5 mm.

The waterproof film 30 may use at least one selected from the group consisting of polyurethane, polybutylene terephthalate, polyethylene glycol, polytetramethylene glycol, HDPE (High Density Polyethylene), and bentonite.

The second adhesive 40 serves to adhere the waterproof film 30 and the second nonwoven fabric 50.

The second adhesive 40 is preferably applied by spraying an amount of 5 to 20 g per 1 m 2 .

The second adhesive 40 may be the same as that of the first adhesive 20 .

The second non-woven fabric 50 serves to protect the waterproof film 30 and prevent loss of the fast-setting polymer cement mortar 71.

The second nonwoven fabric 50 is preferably formed in an amount of 100 to 300 g per 1 m2.

The third adhesive 60 serves to adhere the second nonwoven fabric 50 and the porous structure layer 70 to each other.

The third adhesive 60 is preferably applied by spraying an amount of 5 to 20 g per 1 m 2 .

The third adhesive 60 may be the same as that of the first adhesive 20 .

The porous structure layer 70 is formed in a three-dimensional honeycomb-shaped porous structure, and the fast-hardening polymer cement mortar 71 is added to the honeycomb-shaped porous structure to cure the fast-hardening polymer cement mortar to maintain its shape play a role

The present invention is characterized in that strength and durability can be improved after curing the fast-setting polymer cement mortar 71 by using the three-dimensional honeycomb-shaped porous structural layer 70 .

The thickness of the porous structure layer 70 is preferably 10 to 30 mm.

The porous structure layer 70 is preferably made of polyethylene.

The present invention is a fixing means for fixing the first nonwoven fabric 10, the waterproof film 30, the second nonwoven fabric 50, and the porous structure layer 70 (hereinafter referred to as 'drain pipe body' 90) to the ground may additionally include.

The fixing means may use, for example, a reinforcing bar pin, but is not limited thereto.

The fast-setting polymer cement mortar 71 serves to form the drainage facility 100 by being cured for a certain period of time after being put into the honeycomb porous structure of the porous structural layer 70 .

The fast-setting polymer cement mortar 71 includes 50 to 65% by weight of a fast-setting cement mixture, 25 to 40% by weight of a polymer mixture, and 5 to 15% by weight of aggregate.

The fast-setting cement mixture is characterized by rapid hydration of ultrafine cement, short-term solidification and high initial strength, and does not affect contraction and expansion.

The polymer mixture is adsorbed to the second nonwoven fabric 50 and serves to enhance durability of the drainage facility.

The aggregate serves to adsorb the second nonwoven fabric 50 and maintain cement.

The fast-setting cement mixture includes 50 to 60% by weight of ultrafine cement, 10 to 20% by weight of blast furnace slag, 10 to 20% by weight of calcium carbonate, 5 to 10% by weight of aluminate fast economy, 1.0 to 2.0% by weight of aluminate expanding agent, 1.0 to 2.0% by weight of fluidizing agent, 1.0 to 2.0% by weight of dispersing agent, 1.0 to 2.0% by weight of antifoaming agent, 0.1 to 0.5% by weight of shrinkage reducing agent and 0.1 to 0.2% by weight of fiber reinforcement.

The ultra-fine cement is very fine compared to the Blaine fineness of 2,800-3,500 cm 2 / g of normal Portland cement, and the contact surface area is large in contact with water, so the hydration reaction of cement is fast. Therefore, the initial strength of polymer cement It not only improves the long-term strength, but also plays a role in reducing bleeding, brightening the color, and lightening the specific gravity.

The blast furnace slag and calcium carbonate are inorganic fine powders that enhance the strength and density of cement to enhance chemical durability.

The aluminate fast economy shows high compressive strength in several hours when in contact with water.

The aluminate expanding agent serves to prevent the occurrence of cracks and deterioration in durability due to rapid solidification and compressive strength.

The fluidizing agent is used for the purpose of enhancing fluidity without increasing the unit quantity of cement, and serves to facilitate pouring and compaction without deteriorating cement quality.

The dispersant is a type of surfactant having opposite properties of lipophilic and hydrophilic properties in a molecule, uniformly dispersing solid particles such as inorganic and organic pigments that are difficult to disperse in a liquid, preventing sedimentation or aggregation of solid particles, and stable It serves to form the suspension.

The antifoaming agent serves to effectively reduce the air content in concrete.

The shrinkage reducing agent serves to alleviate shrinkage by reducing the surface tension of water to reduce the capillary tension generated in the capillaries during drying.

The fiber reinforcing material serves to prevent cracking and enhance durability of cement. As the fiber reinforcing material, at least one selected from the group consisting of steel fiber, glass fiber, asbestos fiber, synthetic chemical fiber, and natural fiber may be used.

The polymer mixture includes 80 to 90% by weight of any one resin selected from acrylic resin or SBR resin, 0.1 to 10% by weight of pigment, 0.5 to 1% by weight of antifoaming agent, 0.5 to 1% by weight of dispersant, 0.5 to 1% by weight of thickener, 0.5 to 1% by weight water reducing agent, 0.5 to 1% by weight hydration retardant, 1 to 2% by weight smoothing agent, 1 to 2% by weight shrinkage reducing agent, 3 to 5% by weight of aluminum stearate and 1 to ethylene glycol 2% by weight.

Any one resin selected from the acrylic resin or SBR resin is preferably an aqueous solution having a solid content of 5 to 20% by weight. This increases and there is a problem that workability deteriorates.

Conventionally, in order to construct a drainage facility, it takes more than three weeks to dig the ground, cure the floor, install the formwork, and pour the cement and aspect. Conventional cement requires a long curing and hardening time because a mortar layer must be formed with a considerable thickness to maintain strength and prevent rainwater infiltration by installing forms and pouring between them.

In addition, a process to remove the installed formwork after the cement cured was required. Above all, since the soil was removed from the lower part of the pipeline formed by cement casting due to the formwork, backfilling work was required. Since this backfilling is a process that is carried out after the drainage facility is completed, strong embankment is difficult due to the drainage facility, so rainwater infiltrating the side of the drainage facility causes a scour phenomenon in which subsidence occurs in the backfilled part, and due to the instability of the drainage facility It is also connected and can cause collapse during torrential rain.

In contrast, the construction of the drainage facility 100 according to the present invention does not require the process of curing the floor and installing the formwork, and above all, the thickness of the drainage pipe 90 formed of cement is thin, so it takes 4 days, including the construction time and curing time It has the advantage of being able to complete within a short period of time.

In addition, since the drain pipe body according to the present invention has a non-woven fabric and a porous structure layer rather than a formwork, it can be flexibly bent and can accommodate the curve of the floor surface as it is, so it is in contact with the cured shape of the floor face-to-face, so backfilling is required. does not exist.

Furthermore, the drainage pipe body 90 according to the present invention is manufactured integrally in a factory, and since the non-woven fabric and the porous structure layer can be easily extended to the side, it extends while contacting the ground to the left and right sides of the bottom trough, so that the bottom by rainwater Infiltration can be significantly inhibited, and scour phenomena can be remarkably reduced.

That is, since the drainage pipe according to the present invention contacts the floor surface after leveling the ground face-to-face, there is no need to dig the lower part of the drainage pipe body further, so there is no need for backfilling after cement curing, and it can be directly combined with the strongly built-up floor surface, It has the advantage of suppressing the scour phenomenon by extending the side of the drain pipe in contact with the bottom surface and preventing rainwater penetrating into the side of the pipe.

Next, the construction method of the drainage facility 100 without backfilling of the present invention will be described.

The construction method of the drainage facility 100 without backfilling of the present invention,

Leveling the ground (S 10);

First nonwoven fabric 10 / first adhesive 20 / waterproof film 30 / second adhesive 40 / second nonwoven fabric 50 / third adhesive according to the shape of the bottom surface 80 formed by leveling the ground (60)/cutting the drainage pipe body 90 in which the porous structure layer 70 is integrated (S 20);

Placing the drain pipe body 90 on the bottom surface 80 formed by leveling the ground (S 30);

By fixing the drain pipe body 90 to the bottom surface 80 using the fixing means 75, the valley 81, the valley upper side 82 and the valley upper side edge 83 of the bottom surface 80 and the above Contacting the first nonwoven fabric 10 of the drain pipe body 90 face to face (S 40);

Spraying a fast setting type polymer cement mortar 71 on the porous structure layer 70 (S50); and

Forming a drainage facility 100 by curing the fast-hardening polymer cement mortar 71 (S60);

includes

In the present invention, the 'drain pipe body 90' is a subject manufactured in a factory, and the first nonwoven fabric 10 / first adhesive 20 / waterproof film 30 / second adhesive 40 / second nonwoven fabric 50 / means that the third adhesive 60 / porous structure layer 70 is integrally formed,

The 'drainage facility 100' refers to a state in which the fast curing type polymer cement mortar 71 is sprayed on the drain pipe body 90. The drainage facility 100 is a concept that includes both before and after the curing of the fast-curing polymer cement mortar 71 in a broad sense, and in a narrow sense, the fast-curing polymer cement mortar 71 is cured on a flat surface or on a slope such as the edge of a road Indicates the type of facility installed.

The S 10 is a step of selecting the ground of the place where the drainage facility 100 is to be installed. The bottom surface 80 formed by digging a slope such as a flat land or road edge with an excavator, etc., is a step in which a worker removes a protruding or further dented surface using a tool and flattens the side and bottom surfaces of the bottom surface 80. The S 10 compacts the trough 81 and the trough upper side 82 through which water flows on the bottom surface 80 so that the first nonwoven fabric 10 extends the trough to the upper side of the tubular body in S 30.

The edge 83 of the upper side of the valley extending from the upper side of the valley 82 is the ground before operation, and is provided with an incline so as to gradually deepen as the distance from the valley 81 increases. thus. In the bottom surface 80, the top side of the valley 82 is the highest, the valley 81 is the lowest, and the height gradually decreases from the top side of the valley 82 to the edge 83 of the top side of the valley.

In S 10, since the leveling of the ground can directly fill the valleys 81 of the bottom surface 80, it is possible to level the valleys 81 of the floor surface firmly because it can be piled very strongly.

The S20 is a step of cutting the drain pipe body 90 to fit the valley 81 of the bottom surface 80 formed by the leveling of the ground.

The present invention is not to connect the units after being manufactured in a certain unit, but to transport and mount the drainage pipe body 90 integrally manufactured in the factory, thereby reducing the construction time. There are advantages to doing so.

It is a step of cutting the drain pipe body 90 manufactured and transported in the factory to fit the shape of the bottom surface 80 that is leveled for drainage, and after calculating the length to correspond to the depth of the bottom valley, the drain pipe body ( 90) is cut.

The S 30 is a step of placing the integrated drainage pipe body 90 on the valley 81 of the bottom surface 80 formed by the leveling of the ground.

S 30 is a feature of the present invention, and is spread so that the first nonwoven fabric 10 of the drain pipe body 90 is in contact with the bottom surface valley 81 formed by being depressed underground, face-to-face. It extends to the edge of the upper side of the valley 83 to prevent rainwater from penetrating into the side of the drainage facility 100 formed after the curing of the fast-hardening polymer cement mortar 71 in the future.

In addition, the work is finished by placing the integrated drainage pipe body 90 manufactured and transported at the factory without installing a formwork in S 30 in accordance with the bottom valley 81.

Therefore, there is no space between the first nonwoven fabric 10 under the drain pipe body 90 and the bottom surface trough 81, so there is no space to backfill after the fast curing type polymer cement mortar 71 is cured, and there is no space to fill with strong embankment work. The drainage facility 100 may be coupled to the bone 81 as it is.

In particular, in S 30, the drain pipe body 90 is extended from the bone upper side 82 to the bone upper side edge 83, but the extended drain pipe body 90 and the bone upper side edge 83 are in face-to-face contact. Infiltration of rainwater around the drainage facility 100 is suppressed.

The drainage pipe body 90 of the present invention is manufactured as a wide surface at the factory and transported to the construction site, and is cut to fit the width and depth of the bottom surface 80 and the width of the upper side edge 83 of the valley and used at the site, Since it is made of non-woven fabric or the like and its shape is flexibly changed, it can make surface contact with the compacted bottom surface 80. Since the drain pipe body 90 is placed on the bottom surface 80 by cutting in this way, the present invention can be used regardless of the width and depth of the bottom surface 80, so the construction work is more costly than when a formwork of a predetermined size is installed. It can be said that the flexibility is higher.

As shown in FIG. 4, the S 40 is the integrated drain pipe body 90, the first nonwoven fabric 10 / the first adhesive 20 / the waterproof film 30 / the second adhesive 40 / the second nonwoven fabric 50 / This is a step of fixing the third adhesive 60 / porous structure layer 70) to the bottom surface 80 by penetrating a fixing means 75 such as a fastener.

The fixing means 75 is not particularly limited, and it is sufficient if the drainage facility 100 can be fixed to the ground with a fastener having strong hardness, such as a reinforcing bar pin.

S 30 of the present invention is a fixing means (75) to couple the drain pipe body (90) face-to-face to the lower and side surfaces of the bone (81), and from the upper side to the position extending from the upper side to the magnetic edge (83) of the upper side of the bone (83) Drive it into the ground and fix it. The number of the fixing means 75 is not limited, and it is sufficient if they can be fixed to minimize the separation space between the bottom surface 80 and the drain pipe body 90.

The S 50 is a step of spraying the fast-setting polymer cement mortar 71 on the porous structure layer 70 of the drainage pipe body 90 .

In the present invention, since the fast curing type polymer cement mortar 71 can be supplied from a flat land to the drainage facility construction site using a high-pressure hose and an air nozzle and sprayed on the porous structure layer 70, the cement mortar can be applied to the drainage facility construction site. It has the advantage of not requiring access to pouring equipment.

S 50 is a process of spreading the fast-setting polymer cement mortar 71 on the porous structural layer 70. Since the fast-setting polymer cement mortar 71 according to the present invention is not inserted between forms, it does not require reinforcing bars and the like, and it is sufficient to uniformly pour into the porous structural layer 70 having a low thickness. The porous structure layer 70 has a very small height of 3 cm or less, and is split like a honeycomb structure, and a fast-setting polymer cement mortar 71 is inserted between them.

The fast-setting polymer cement mortar 71 injected into the porous structural layer 70 can change the shape of the porous structural layer 70 by pressing the protruding honeycomb structure of the porous structural layer 70 when concentrated. , By placing an air pipe connected to the compressor and an air nozzle connected to the air pipe, the quick-curing type polymer cement mortar 71 is sprayed by scattering without putting it into a small space at once.

At this time, the fast-curing polymer cement mortar 71 is sprayed so as to be uniformly applied to the downwardly sloped valley upper side edge 83 of the drainage facility 100 extending around the valley upper side 82.

Since the thickness of the fast curing type polymer cement mortar 71 sprayed in this way is very low, the drainage facility 100 according to the present invention is very light and has a fast curing speed.

The S 60 is a step of curing the fast-curing polymer cement mortar 71 at 1 to 25° C. for 2 to 3 days to complete the drainage facility 100. 5 shows the state of S60 in a perspective state.

After the above S 60 , a soil finishing step (S 70 ) of covering soil on both edges of the drainage hole 100 sloping downward may be added. The drainage facility 100 is formed to slope downward from the upper side of the valley to the edge (periphery) to prevent rainwater from directly penetrating into the lower part of the drainage facility 100, and to prevent the side edge of the drainage facility 100 from being exposed. Cover 3 to 10 cm of soil on the side edge of (100). The reason for covering the edge of the drainage facility 100 through this soil finish is to prevent scouring.

The lateral edge of the drainage facility 100 and the bottom surface 80 of the valley upper side edge 83 extending from the valley upper side 82 have the same downward slope so that the valley upper side edge 83 and the drainage facility 100 ) so that there is no separation space at the side edge.

On the other hand, since the drain pipe body 90 of the present invention is made of a very thin and flexible material, it is useful even when repairing an already installed drain pipe. If a crack occurs in a drain pipe installed with general concrete, it must be repaired because rainwater or sewage penetrates into the floor and the crack gradually grows. Crack repair of such a general drain pipe is carried out after fixing the repair plate flange with an opening hole that exposes only the crack portion to the drain pipe, and then repair work is performed. There is also a problem that the repair point protrudes and cracks occur again at the location where it is added under continuous pressure from the flow of sewage or rainwater.

In contrast, in the drainage pipe body 90 of the present invention, as shown in FIG. 6, after drilling around cracks in a general drainage pipe, fixing the drainage pipe body 90 and the drainage pipe with a fixing means, and then applying a fast-hardening polymer cement mortar 71 to the porous It is possible to repair cracks by spraying on the structural layer 70.

The drain pipe body 90 of the present invention is a first nonwoven fabric 10 / first adhesive 20 / waterproof film 30 / second adhesive 40 / second nonwoven fabric 50 / third adhesive 60 / Since it is made of a porous structure layer 70 and the fast-curing polymer cement mortar 71 is sprayed thereon, cracks can be minimized because the corresponding part is thin and strong even if it is added on the cracked drainage pipe.

Hereinafter, the configuration and effects of the present invention will be described in more detail through examples. These examples are only for illustrating the present invention, but the scope of the present invention is not limited by these examples.

The first nonwoven fabric 10 was formed at 150 g per 1 m 2 . The first adhesive 20 was applied to the first nonwoven fabric 10 by spraying an amount of 10 g per 1 m 2 . A waterproof film 30 was laminated on the first adhesive 20 to a thickness of 0.1 mm. The second adhesive 40 was applied to the waterproof film 30 by spraying an amount of 10 g per 1 m 2 . The second nonwoven fabric 50 was laminated on the second adhesive 40 at an amount of 150 g per 1 m 2 . The third adhesive 60 was applied to the second nonwoven fabric 50 by spraying an amount of 10 g per 1 m 2 . A three-dimensional, honeycomb-shaped porous structure layer 70 was laminated on the third adhesive 60 to a thickness of 15 mm. The first adhesive 20, the second adhesive 40, and the third adhesive 60 use epoxy adhesive, the waterproof film 30 uses HDPE (High Density Polyethylene), and the porous structure layer 70 ) used polyethylene.

After spraying the quick-curing type polymer cement mortar 71 on the porous structure layer 70 of Example 1, curing it at 25° C. for 3 days to manufacture a drainage facility 100.

The fast-setting polymer cement mortar was prepared by mixing 60% by weight of the fast-setting cement mixture, 30% by weight of the polymer mixture, and 10% by weight of aggregate, and then stirring for 25 minutes. The fast-setting cement mixture contains 55% by weight of ultrafine cement, 15% by weight of blast furnace slag, 15% by weight of calcium carbonate, 8.3% by weight of aluminate fast economy, 1.5% by weight of aluminate expanding agent, 1.5% by weight of fluidizer, and 1.5% by weight of dispersant. , After mixing 1.5% by weight of antifoaming agent, 0.5% by weight of shrinkage reducing agent and 0.2% by weight of fiber reinforcing material, it was prepared by stirring for 25 minutes. The polymer mixture contains 80% by weight of acrylic resin (aqueous solution containing 10% by weight of resin solids), 4% by weight of pigment, 1% by weight of antifoaming agent, 1% by weight of dispersant, 1% by weight of thickener, 1% by weight of water reducing agent, and 1% by weight of hydration retardant. , 2% by weight of a leveling agent, 2% by weight of a shrinkage reducing agent, 5% by weight of aluminum stearate and 2% by weight of ethylene glycol were mixed and stirred for 25 minutes.

At this time, it was manufactured by bending the first nonwoven fabric 10 assuming that the bottom surface 80 was curved.

10: first nonwoven fabric 20: first adhesive
30: waterproof film 40: second adhesive
50: second nonwoven fabric 60: third adhesive
70: porous structural layer 71: fast-setting polymer cement mortar
75: fixing means
80: bottom surface
81 bone 82 bone upper side
83: bone upper lateral edge 90: drainage pipe
100: drainage facility

Claims (7)

delete delete delete a first nonwoven fabric (10);
A first adhesive 20 applied to the first nonwoven fabric;
a waterproof film 30 laminated on the first adhesive;
A second adhesive 40 applied to the waterproof film;
a second nonwoven fabric 50 laminated to the second adhesive;
a third adhesive 60 applied to the second nonwoven fabric;
a porous structure layer 70 laminated on the third adhesive; and
a fast-setting polymer cement mortar 71 sprayed on the porous structure layer;
Using a drainage pipe 90 containing a,
The first nonwoven fabric 10 is formed of 100 to 300 g per 1 m2,
The first adhesive 20 is applied by spraying an amount of 5 to 20 g per 1 m2,
The waterproof film 30 has a thickness of 0.1 to 0.5 mm,
The second adhesive 40 is applied by spraying an amount of 5 to 20 g per 1 m2,
The second nonwoven fabric 50 is formed of 100 to 300 g per 1 m2,
The third adhesive 60 is applied by spraying an amount of 5 to 20 g per 1 m2,
The porous structure layer 70 has a thickness of 10 to 30 mm.
Drainage without backfill.
According to claim 4,
The porous structure layer 70 is formed of a three-dimensional honeycomb porous structure,
using polyethylene,
Drainage without backfill.
According to claim 4,
The first adhesive 20, the second adhesive 40, and the third adhesive 60 use at least one selected from the group consisting of acrylic adhesive, urethane adhesive, epoxy adhesive, and silicone adhesive,
The waterproof film 30 uses at least one selected from the group consisting of polyurethane, polybutylene terephthalate, polyethylene glycol, polytetramethylene glycol, HDPE (High Density Polyethylene) and bentonite,
The fast-setting polymer cement mortar 71 includes 50 to 65% by weight of a fast-setting cement mixture, 25 to 40% by weight of a polymer mixture, and 5 to 15% by weight of aggregate,
The fast-setting cement mixture contains 50 to 60% by weight of ultrafine cement, 10 to 20% by weight of blast furnace slag, 10 to 20% by weight of calcium carbonate, 5 to 10% by weight of fast aluminate, 1.0 to 2.0% by weight of aluminate expanding agent, 1.0 to 2.0% by weight of fluidizing agent, 1.0 to 2.0% by weight of dispersant, 1.0 to 2.0% by weight of antifoaming agent, 0.1 to 0.5% by weight of shrinkage reducing agent and 0.1 to 0.2% by weight of fiber reinforcement,
The polymer mixture contains 80 to 90% by weight of any one resin selected from acrylic resin or SBR resin, 0.1 to 10% by weight of pigment, 0.5 to 1% by weight of antifoaming agent, 0.5 to 1% by weight of dispersant, 0.5 to 1% by weight of thickener, 0.5 to 1% by weight water reducing agent, 0.5 to 1% by weight hydration retardant, 1 to 2% by weight leveling agent, 1 to 2% by weight shrinkage reducing agent, 3 to 5% by weight of aluminum stearate and 1 to ethylene glycol Containing 2% by weight,
Drainage without backfill.
delete

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