KR0116870Y1 - Underground buried spiral tube - Google Patents

Abstract

The present invention relates to underground buried spiral pipes used for transporting sewage such as wastewater and wastewater by embedding in the ground. In order to efficiently absorb local impact from the outside and improve durability of the product, a metal plate ( 19. The spirally curved coated metal plate 10, which is integrally coated with the adhesive synthetic resin 11 on both sides of the surface 19, has a cross section of the tube wall 12 having a maximum point 12a, an inflection point 12b, and a minimum point 12c. In the spiral tube continuously supported in the form of a waveform having a wave shape, the outer surface of the tube wall 12 has a thicker thickness of the portion of the maximum point (12a) according to the protruding spiral portion and gradually becomes thinner toward the inflection point (12b) to the inflection point ( 12b) is further formed with an outer skin reinforcing resin layer 20, which is integrally coated with a synthetic resin in a cross-sectional shape gradually disappearing, and the flesh thickness of the very small point (12c) portion along the protruding spiral portion is formed on the inner surface of the pipe wall (12). Thick and inflection The endothelial reinforcement resin layer 30, which is formed in a cross-sectional form gradually thinner toward the point 12b and gradually disappears after the inflection point 12b, is additionally formed, thereby forming the skin reinforcement resin layer 20 and The endothelial reinforcement resin layer 30 is characterized in that it directly corresponds to the physical force applied from the outside.

Description

Underground buried spiral tube

The present invention is used to transport sewage such as wastewater and waste water by embedding it in the ground. Especially, it is easy to be exposed to external local impacts in a spirally manufactured tube made of a goth metal plate coated with synthetic resin on both sides. Reinforcing spiral layer for improving the durability of the product by forming a reinforcing resin layer coated with synthetic resin in the protruding spiral portion to efficiently absorb the impact from the outside of the reinforcing resin layer. will be.

In general, a metal tube made of metal as a spiral material has excellent resistance to load applied from the outside due to the properties of the metal material and the characteristics of the spiral structure.

However, these metal tubes have a disadvantage in that corrosion is easily progressed by surface contact of water, as well as wastewater contaminated with chemical toxicity.

Therefore, such a metal tube was not suitable for use for the purpose of transporting sewage by embedding it in the ground where water is present without surface treatment.

Previously, in the field of metal tube manufacturing, developments to actively compensate for the weak points of corrosion resistance while actively utilizing the strength of the load resistance strength of the metal tube have been actively conducted.

As one of them, the three-layer flexible pipe for piping of Japanese Patent Application Laid-Open No. 1-67391 is introduced.

As shown in Fig. 1, the three-layer flexible pipe for piping integrally coats the thermoplastic resin layers 2 and 3 on the inner circumferential surface and the outer circumferential surface of the corrugated metal tube 1, which has a corrugated cross section of three layers. Characterized in that the structure.

In this technical configuration of the three-layer flexible pipe for piping, since the thermoplastic resin layers 2 and 3 are formed on the outer surface of the metal tube 1, the resin layer is easily oxidized by contact with chemicals. By shielding the outer surface of (1), there is an effect of improving the corrosion resistance while maintaining the excellent load bearing ability of the corrugated metal tube.

However, since the three-layer flexible pipe for piping has a cross-sectional structure in which the waveform is continuously repeated, when the sewage such as wastewater and wastewater is discharged in the ground, intensive action such as load or impact is applied to the outer wall surface of the corrugated peak portion. Local damage is caused to the resin layer of the parts by locally hitting the inner wall surface of the corrugated minimum point portion such as a foreign body that is swept by the flow of water flowing into the inside of the tube, and the resin layer of the portion is relatively thinly coated. During transport and installation work, it is easily exposed to the external environment of the surface of the metal tube shielded by the resin layer due to various reasons such that the coating resin layer is easily peeled off by only a small contact with a foreign object.

As a result, this exposed metal surface is affected by the external environment while being installed underground, and corrosion occurs in this area, resulting in shortening the life of the product.

On the other hand, in the configuration of the three-layer flexible pipe for the pipe to form a relatively thick thermoplastic resin layer (2) (3) that shields the outer surface of the metal tube (1) may be coped with locally applied impact, This raises another problem that increases the cost of pipe making and is not a fundamental solution.

Therefore, if a new pipe-making technique has been developed to solve the above problems properly and widely used, it will have a beneficial effect in many aspects not only in the field of underground burial pipes for transporting sewage but also in the overall industrial field.

The purpose of the present invention is to form a reinforcing resin layer on the protruding spiral portion easily exposed to local impact in the spiral tube coated with synthetic resin on the inner and outer surfaces of the metal tube, so that the overall load is excellent and the load is applied from the outside. It is to provide a underground buried spiral tube that can sufficiently improve the durability of the product by sufficiently responding to the local impact.

1 is a cross-sectional view of a conventional three-layer flexible pipe for piping

Figure 2 is a partially cutaway front view of the underground buried spiral tube according to the present invention.

3 is a detailed view of a partial cross section of FIG.

* Explanation of symbols for main parts of the drawings

10: coated metal sheet 11: adhesive synthetic resin

12: pipe wall 12a: maximum point

12b: inflection point 12c: minimum point

19: Metal plate 20: Sheath reinforcement resin layer

30: endothelial resin layer

Hereinafter, the technical configuration of the present invention in detail.

This invention also spirally bends the coated metal plate 10 coated with the adhesive synthetic resin 11 integrally on both sides of the metal plate 19 so that the cross section of the tube wall 12 is the maximum point 12a, the inflection point 12b, In the case of the spiral tube including the structure which is continuously supported in the form of a waveform having the minimum point 12c, the technical concept is the same as the conventional one.

However, underground buried spiral tube 100 of the present invention, as shown in Figures 2 and 3,

On the outer surface of the tube wall 12, the synthetic resin is integrally coated in a cross-sectional shape that gradually increases in thickness toward the inflection point 12b along the protruding spiral portion and becomes thinner gradually toward the inflection point 12b. An outer skin reinforcement resin layer 20 is further formed, and the inner surface of the pipe wall 12 has a thicker thickness of the micro point 12c along the protruding spiral portion and is gradually thinner toward the inflection point 12b, thereby forming an inflection point 12b. The endothelial reinforcement resin layer 30, in which synthetic resin is integrally coated in a cross-sectional shape gradually disappearing after passing through), is further formed, so that the skin reinforcement resin layer 20 and the endothelial reinforcement resin layer 30 are applied from the outside. It is a basic feature of the technical configuration to respond directly to.

According to the present invention constituted as described above, unlike the conventional plastic pipes coated with only a thin thermoplastic resin on both sides, they are vulnerable to external local loads or impacts. These structurally increase the surface strength of the parts easily exposed to external physical forces.

That is, the outer shell reinforcement resin layer 20 formed on the outer wall of the tube from the external load or impact from the outside, the inner layer reinforced resin layer 30 formed on the inner wall of the tube to the impact that may occur during the movement of the foreign body swept by the water flow It effectively absorbs the damage of the synthetic resin coating layer and also provides sufficient buffer even when contacted with foreign objects during transport and installation, so that the surface of the coated metal tube coated with the synthetic resin on the inner surface It is perfectly protected.

As described above, according to the present invention, the reinforcement resin layer is formed on the protruding spiral portion easily exposed to the local impact in the spiral tube coated with the synthetic resin on the inner and outer surfaces of the metal tube, so that the overall load is excellent. It can fully cope with the local impact applied from the outside has the effect of greatly improving the durability of the product.

Claims (1)

By spirally bending the coated metal plate 10 coated with the adhesive synthetic resin 11 on both sides of the metal plate 19 in a spiral manner, the cross section of the tube wall 12 has a maximum point 12a, an inflection point 12b, and a minimum point ( In the spiral tube continuously supported in the form of a waveform having a 12c), the outer surface of the tube wall 12 is thickened along the protruding spiral portion of the maximal point (12a) and gradually thinner toward the inflection point (12b) to the inflection point An outer skin reinforcing resin layer 20 having a synthetic resin integrally coated in a cross-sectional shape gradually disappearing after passing through 12b is formed, and the inner wall of the tube wall 12 has a flesh thickness of a portion 12c along the protruding spiral. The endothelial reinforcement resin layer 30, in which a synthetic resin is integrally coated in a cross-sectional shape that gradually becomes thinner and becomes thinner gradually toward the inflection point 12b and gradually disappears after the inflection point 12b, is formed, and thus the outer reinforcement resin layer ( 20) and the endothelial reinforcement resin layer (30) A underground buried spiral tube, characterized in that it directly responds to a physical force applied from the outside.