KR200367036Y1 - Manufacture system of triple layer pipe - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing a triple layer pipe mainly used as a water and sewage pipe, and more particularly, to an apparatus for manufacturing a triple layer pipe in which a reinforcement layer is integrally formed on the inner and outer surfaces of the main body layer.

In the conventional manufacturing apparatus, a material for molding the main body layer and a material for molding the inner and outer reinforcement layers are supplied from two extruders, respectively, so that the material for molding the inner and outer reinforcement layers is divided and supplied in two directions from the die. As a result, the reinforcement layer is formed on the inner and outer surfaces of the main body base layer, which is caused by the unevenness of the classification rate due to the difference in the type of material and the molding temperature or the extrusion pressure. In particular, several external reinforcement layer resin supply passages radially traverse the main body base resin supply passage, and as the main body base resin progresses, it hits the outer reinforcement layer resin supply passage and vortex occurs. Bubbles are generated or cracks occur in the body base to reduce the strength and durability of the pipe. Who would have a problem occurs.

The present invention separates the main body base resin supply passage and the inner and outer reinforcement base resin supply passages separately, and adds pressure regulating means to each supply passage to prevent bubbles and cracks from forming in each base, The compactness is to increase the strength and durability.

Description

Manufacture system of triple layer pipe

The present invention relates to an apparatus for manufacturing a triple layer pipe mainly used as a water and sewage pipe, and more particularly, to an apparatus for manufacturing a triple layer pipe in which a reinforcement layer is integrally formed on the inner and outer surfaces of the main body layer.

In the conventional manufacturing apparatus, as shown in FIG. 1, a material for molding the main body layer 3 and a material for molding the inner and outer reinforcement layers 4 and 5 are supplied from two extruders, respectively. The material for forming the base layers 4 and 5 is configured to be divided and supplied in two directions from the die, so that the reinforcement layers 4 and 5 are formed on the inner and outer surfaces of the main body layer 3. As the material classified into the inner and outer surface is uneven in the classification rate due to the difference of material type, molding temperature or extrusion pressure, it is a obstacle to producing high quality pipe, especially supplying several external reinforcement layer resin As the furnace 2 traverses the main body base resin supply passage 1 radially, the main body base resin proceeds and hits the outer reinforcement layer resin supply passage 2 to generate a vortex, causing air bubbles to enter the main body base layer 3. Create or crack wigs And who would have great problems tteurige down the strength and durability of the pipe occurs.

The present invention separates the main body base resin supply passage and the inner and outer reinforcement base resin supply passages separately, and adds pressure adjusting means to the respective supply passages so that bubbles and cracks are not formed in each base layer. The compactness is to increase the strength and durability.

1 is a sectional view of the main portion of the conventional manufacturing apparatus

2 is a schematic view showing the entire manufacturing apparatus of the present invention

3 is an enlarged view of the main part of the present invention

Explanation of symbols on the main parts of the drawings

10: die 11: main body resin supply port

12: main body base resin supply path 13, 16: inclined protrusion

14: inner reinforcement layer resin supply port 15: inner reinforcement layer resin supply passage

17: Outer reinforcement layer resin supply port 18: Outer reinforcement layer resin supply passage

19: dividing member 20: main body base resin extruder

30: inner reinforcement layer resin extruder 40: outer reinforcement layer resin extruder

50: cooler 60: pipe

61: main body base 62: inner reinforcement layer

63: outer reinforcement layer

2 and 3 is a schematic view showing the entire manufacturing apparatus of the present invention and the enlarged portion of the main portion, the main body base resin supply passage 11 is formed in the center of the tip in communication with the main body base resin supply passage 12 is divided into conical An inner surface reinforcement layer resin supply passage 15 formed in a V shape of the member 19 and communicating with the inner surface reinforcement layer resin supply port 14 in the lateral direction and penetrating to the center is a main body base resin supply passage 12. The die is formed in communication with the inner surface of the die formed in communication with the outer reinforcement layer resin supply port 17 in the rear side direction so that the outer reinforcement layer resin supply passage 18 is in communication with the outer surface of the main body base resin supply passage 12 ( In the main body base resin supply port 11 and the inner and outer reinforcement layer resin supply ports 14 and 17 of the main body layer resin extruder 20 and the inner and outer reinforcement layer resin extruders 30 and 40, respectively, The cooler 50 is installed at the rear of the die 10 and connected to the main body resin layer. In the 12 and the inner surface respectively inclined projection 13 to reinforce the base layer resin supplied by (15) (16) is formed represents the configured.

When the main substrate resin is supplied from the main substrate resin extruder 20 as shown in FIG. 2, the main substrate resin is divided into a cylindrical shape through the main substrate resin supply passage 12 and extruded to the rear. At the same time, the internal reinforcement layer resin, which is supplied from the internal reinforcement layer resin extruder 30 through the internal reinforcement layer resin supply port 14, is pre-extruded and transferred through the internal reinforcement layer resin supply passage 15. The inner reinforcement layer 62 is formed while being conformed to the inner surface and extruded, and the outer reinforcement layer resin supplied from the outer reinforcement layer resin extruder 40 through the outer reinforcement layer resin supply port 17 is the outer reinforcement layer. It has a triple layer by passing through the cooler 50 after forming the outer reinforcement layer 63 while being matched with the outer surface of the main body base layer 61 which is extruded and conveyed through the resin supply path 18. It will be produced pipe 60.

On the other hand, the main body base resin supplied through the main body base resin supply passage 12 may generate a vortex while hitting a part of the inner surface reinforcement layer resin supply passage 15, wherein the main body base resin is formed on the inclined protrusion 13. Due to the instantaneous stagnation phenomenon, the pressure is increased, and bubbles and cracks that can be generated during vortex disappear, and the tissue is dense and passes smoothly through the inclined protrusions 13 while being smoothly transferred by the widened supply path. At the same time, the inner surface reinforcement layer resin supplied through the inner surface reinforcement layer resin supply path 15 also has the same phenomenon by the inclined protrusions 16, so that the inner surface reinforcement layer 62 of the dense structure is formed.

In addition, the outer reinforcement layer 63 is also separately supplied by the outer surface reinforcement layer resin extruder 40, so that the supply amount and the pressure can be easily adjusted, so that the outer reinforcement layer 63 having the desired thickness is provided. It can be formed.

As described above, the present invention prevents the formation of air bubbles and cracks in the manufacture of triple-layer pipes, thereby preventing the occurrence of bubbles and cracks, thereby making it possible to manufacture dense products, thereby minimizing defect rates and improving the strength and durability of finished products. It is provided with a very large effect that is augmented.

Claims (3)

The main body base resin supply passage 12 is formed in a V shape by the conical partition member 19 in communication with the main body base resin supply port 11 formed at the center of the tip, and the inner side reinforcement layer resin supply port from the side direction. An inner surface reinforcement layer resin supply passage 15 communicating with the center 14 and penetrating to the center is formed to communicate with an inner surface of the main body layer resin supply passage 12, and the outer reinforcement layer resin supply opening 17 in the rear side direction. The main body base resin supply port 11 and the inner and outer reinforcement layer resin supply ports 14 of the die 10 which are in communication with each other so that the outer reinforcement layer resin supply passage 18 communicates with the outer surface of the main body base resin supply passage 12. Manufacture of a triple layer pipe in which the main body layer resin extruder 20 and the inner and outer reinforcement layer resin extruders 30 and 40 are respectively connected to each other, and the cooler 50 is installed at the rear of the die 10. Device. 2. The apparatus for manufacturing a triple layer pipe according to claim 1, wherein an inclined protrusion (13) is formed in the main body base resin supply passage (12). The apparatus for manufacturing a triple layer pipe according to claim 1, wherein an inclined protrusion (16) is formed in the inner surface reinforcement layer resin supply passage (15).