NL193610C - Method for extruding plastic pipes. - Google Patents

Description

1 193610

Method for extruding plastic pipes

The invention relates to a method for extruding plastic pipes with a solid wall and with a ribbed outer surface, in which a hose is extruded from a plastic material between a doom and a ring-shaped surrounding the mandrel, in webs closed in itself all-round molded parts are passed through cooling molds with internal molded ribs and move sequentially in the longitudinal direction of the device; while sleeve parts are formed in the hose by pressing hose parts into recesses, which are formed in the molding surfaces of the cooling molds and have a shape similar to that of the sleeve parts, the hose parts being pressed into the recesses by exposing the inner surface of the hose at a higher pressure of a medium than its outer surface, a space for the high pressure medium inside the hose being bounded by seals formed by plastic material present between the core body and the cooling molds.

Such a method is known from US patent US-A-3,919,367. In the known method, an internally and externally smooth hose is extruded and both the ribs and the sleeve parts are pressed against the molds by means of compressed air. The finished pipe also obtains ribs on the inner surface. The compressed air acts on the pipe throughout the casting zone, that is, from the time the pipe leaves the extruder until it reaches a sealing plug assembly. In order to prevent blow cavities in the formation of the sleeve parts, it is necessary to reduce the compressed air pressure periodically.

The object of the invention is now to obtain a pipe with a smooth inner surface and to further prevent the formation of bladder cavities without the need to adjust the compressed air pressure for this purpose.

The method according to the invention is therefore characterized in that the mandrel is extended by a core body of constant diameter for directly extruding the hose having a smooth inner surface with ribs and that the space for the high-pressure medium inside the hose extends up to the area of the depression in the mold is bounded by the seals formed adjacent to the front and rear walls of the depression, while the differential pressure is generated at the core body when the cooling mold rib positioned first after the depression is through an inlet point of the plastic material has been reached or passed. The method according to the invention is effective in that the hose can be given its final shape immediately, except for the sleeve parts.

According to the invention it is preferred that the pressure difference is generated when the said rib has reached the core body.

The invention will now be further elucidated with reference to the drawing, which shows an exemplary embodiment of the invention.

Figure 1 is an overview of an apparatus for manufacturing corrugated or corrugated pipes.

Figure 2 is an enlarged longitudinal sectional view of a detail of an apparatus used for the manufacture of corrugated pipes.

Figure 3 shows a finished ribbed pipe.

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The apparatus shown in Figure 1 includes chains of cooling mold halves 1 and 2 which circulate along two endless tracks and meet within the region of guide rails 3 to form a chain of adjacent cylindrical cooling molds. An extrusion jacket 4, which is connected to a nozzle 6 of an extruder 5, projects into the mold. Figure 1 further shows how a finished pipe 745 protrudes from the other end of the chain of cooling molds.

Figure 2 is a more detailed view of those parts of the device that participate in forming the pipe. A mandrel 8 with a straight section and a conical widening section is placed on the central axis of the device, while a core body 9 of constant diameter forms an extension of the mandrel. Cavities (not shown) for a coolant are provided in the free end of the core body. The extrusion jacket 4 and the core body 9 define an annular nozzle 10 therebetween, through which a plasticized plastic material in the form of a hose 11 is fed into the ring space formed between the cooling molds and the mandrel. In order to provide the pipe with a ribbed outer surface, the inner surface of the cooling molds is provided with annular ribs 12, between which annular grooves 13 are formed, into which the plastic material for molding 55 ribs 14 is pressed. The grooves 13 of the cooling molds, as shown in Figure 2, can communicate with the atmosphere through channels 15 extending from the bottom of the grooves to the outer surface of the cooling mold.

Claims (2)

193610 2 At least some cooling molds, instead of the ribs 12 and the grooves 13, have a larger annular recess 16, the side and bottom walls of which correspond in shape to the outer surface of the sleeve portion of the pipe, which recess 16 therefore generally is both deeper and longer in the axial direction of the device than the grooves 13. In turn, the core body 95 is provided with a circumferential groove 17 formed on its surface, while one having a source (not shown) of a printing medium, such as air, communicating channel 18 opens into the side wall of the groove 17. The channel 18 is formed with a valve 19. The groove 17 acts as a thermal barrier between the hot part of the core body closest to the doom and the cold part at the free end of the core body. Figure 2 shows that the plastic material filling the space between the cooling molds and the core body forms seals 20 and 21 close to the front wall and the rear wall of the recess 16, while the distance from the groove 17 to the sealing point 21 is greater then the length of the depression 16 in the axial direction of the device. The length of the core body in the axial direction is at least equal to the length of the depression 16 in the same direction. The device shown in Figure 2 operates in the following manner. To produce a ribbed plastic pipe, plasticized plastic material is fed through the nozzle 10 in the form of a hose 11 to the space formed between the cooling molds 1, 2 and the doom 8. When cooling molds with ribs and grooves 12, 13 on their molding surface are located at the nozzle 10, as shown in Figure 2, the plastic material completely fills the space between the cooling molds and the mandrel, as shown in Figure 2. When the moving cooling molds 2 in figure 2 to the right, a plastic pipe with a solid wall with a ribbed outer surface and a smooth inner surface is formed. However, when the recess 16 reaches the nozzle 10, the hose 11 is unable to fill the entire recess due to its large volume, but the hose forms a layer slightly thicker than the normal wall thickness around the core body 9, the increased thickness results from the omission of the ribs 14. This is continued until the entire depression has passed through the nozzle 10, and the formation of a ribbed pipe is resumed. Figure 2 shows a situation in which the depression 16 has just passed through the nozzle 10, while a groove 13 positioned first after the depression has already been filled with the plastic material. Since the hose 11 thereby fills the space between the cooling molds and the core body, an insulated area 30 is formed at the depression 16. After the front wall of the depression has passed through the groove 17 of the core body, compressed air is blown from the groove, see the arrows, whereby the hose resting against the core body is pressed against the walls of the depression in the manner shown in the figure. . Compressed air can be continuously supplied from groove 17; however, it is also possible to control the air supply by means of the valve 19, in such a way that air is only supplied when the recess 16 is located at the groove. The channels 15 communicating with the atmosphere allow the air to be forced out of the recess to form the sleeve portion. The sleeve part is indicated by reference numeral 22. The pipe formed in the device is cooled by means of a cooling liquid, which flows through the channels (not shown) into the free end of the core body 9 and into the cooling molds 1, 2. Figure 3 shows a part of a pipe manufactured by means of the device. A tubed pipe is cut off in the center of the socket section to form two pipes, while one end of each pipe is provided with a socket. As can be seen from the figure, a shallow groove 23 is provided on the inside of the pipe at the cutting point. This groove can be easily formed by a corresponding shape of the bottom of the depression. The groove simplifies pressing a straight 45 pipe end into the sleeve. If desired, the pipe within the device can be cut at the groove 23 by increasing the internal pressure of the pipe to a value where the breaking limit of the hose is exceeded, so that the socket positioned at the groove is removed through the channels 15. Instead of working with compressed air, or in addition to this, a suction action can be applied for pressing the hose against the walls of the depression 16 by connecting the channels 15 opening into depression 50 to a vacuum source. A method for extruding plastic pipes with a solid wall and with a ribbed outer surface, in which a hose is extruded from a plastic material between a mandrel and a mandrel, surrounded by molded parts circulating in self-closed webs 3 193610 with internal molded ribs are passed through and move sequentially in the longitudinal direction of the device; while sleeve parts are formed in the hose by pressing hose parts into recesses formed in the mold surfaces of the cow molds and having a shape similar to that of the sleeve parts, the hose parts being pressed into the recesses by exposing the inner surface of the hose at a higher pressure of a medium than its outer surface, a space for the high pressure medium inside the hose being bounded by seals formed by plastic material present between the core body and the cooling molds, characterized, that the mandrel is extended by a constant diameter core body to extrude directly with ribs the hose 10 having a smooth inner surface and the space for the high pressure medium inside the hose (11) to the region of the depression (16) in the form is bounded by the seals (20, 21) which are adjacent to the front and rear walls of the storey and formed, while the differential pressure is generated at the core body when the cooling mold rib (12) positioned first after the mold recess is reached or passed through an inlet point (10) of the plastic material, Method according to claim 1, characterized in that the pressure difference is generated when said rib (12) has reached the core body (9). Hereby 2 sheets drawing