DE2552774C2 - Heavy duty corrugating device - Google Patents

Description

Drive sprockets and guide rails 25, 26 and 27, 28 are formed. Each half-shape 16 is complementary formed into a half-mold of the other half of the molding device. The half-molds form along the Forward strand between them an axially extending tunnel with a hollow cylindrical shape and a corrugated wall. The chains of the half-molds are synchronized with each other by the drive sprockets driven. Due to the chutes 10 resting on wheels, the molding devices can be in such a position be brought so that a spray head 29 can be arranged at the entrance of the tunnel. The spray head is seated at the nozzle of an injection molding machine, which is arranged coaxially to the tunnel. If necessary, the Molding devices are moved away from the spray head 29 to provide access to this.

The spray head 29 itself has a special shape for use in connection with the device according to the invention. From the F i g. 4 and 5, in which the spray head is shown in a position at the entrance to the tunnel, it can be seen that the head c ^; .n has intermediate piece 38 which is provided with several radial channels. A tubular part 39 is connected to the spray head and extends axially away from the spray head 29 and which has a runner 40 at the free end which rests against the inside of a shaped tube 41 in order to support this end. The tubular part 39 carries a seal 42 which is formed from three ring seals. These are arranged at an axial distance from the end of the spray head in order to form a first air space 43 between the latter and the seal 42. The tubular part also carries a second seal 44 which is formed from an annular seal. This ring seal is at a distance from the first seal 42 in order to form a second air space 45 therebetween. The spray head 29 comprises a first air duct 46 which is in communication with a first air inlet 47. Compressed air is supplied through this to the duct. The air duct 46 leads into the air space 43 to introduce the pressurized air through which the hot extruded tube 41a of thermoplastic material is expanded to bear against the wall of the mold. A second air inlet 48 is in communication with a second air duct 49 which is arranged in the tubular part 39 and is in communication with the second air space 45. The tubular part 39 has openings 50 which are distributed over its length within the air space 45, as follows that the second air inlet 48 supplied cooling air is directed towards the thermoplastic material to cool and solidify the material. In order to support the cooling effect of this cooling air ″, a heat exchanger coil 51 is arranged around the tubular part 39 and is connected to two channels 52, 53 which are located inside the tubular part 39. Inlet and outlet ducts 54 and 55 for cooling air are connected to these ducts.

As in Fig. 1 and 2, each mold further includes an air distribution duct 57, 58, which extends along the return strand of the associated endless path and is so arranged - "net is that cooling air is passed to the exposed inner surfaces of the half-molds 16 while they are in the Run along the return run. The air distribution ducts 57, 58 are connected to cooling air fans 59, 60. Each molding device also has a heat reducer 61, 2 "> 62, which is formed by a cooling water tank. Cooling water can be circulated through this tank. Inlet and outlet water connections are provided for this purpose 63, 64 or 63a, 64a are provided. The housing of the molding devices can be on this i »way to be cooled during the molding process. Around Tin to avoid wasting material at the beginning of the molding process can keep the water in the housings however, they can be heated to the required temperature by electrical immersion heaters 65, 66. The diving) "' they are set in the walls of the housing.

An advantageous further embodiment of the invention is shown in FIG. 1 in that the Support structure 13 includes mechanical winches 82 which connect the upper and lower forming devices with one another. connect to the other and can be put into operation in such a way that the upper device of the lower can be moved away to allow easy access for maintenance.

For this purpose 3 sheets of drawings

Claims (6)

Patent claims: 1. Heavy duty corrugating device for manufacturing of corrugated thermoplastic plastic pipe, with two complementary shaping devices that each consist of an endless chain of articulated half-forms and Have means for guiding the half-forms along an endless path, the forms in i < > in the closed position form a tunnel with a cylindrical shape and a corrugated wall and where a spray head attachable to the nozzle of an injection molding machine for producing the pipe coaxially in the tunnel is arranged and a tubular part connected to the spray head extends axially extends into the tunnel which carries a seal which forms an air space between itself and the spray head, and the spray head has a first air duct for introducing the compressed air into the air space for inflating the extruded pipe, characterized in that the spray head (29) and the tubular part (39) have a second air duct (49) which extends downstream to behind the seal (42) for distributing cooling air to the interior of the tube (4 ta) . 2. High-performance corrugating device according to claim 1, characterized in that a further seal (44) is arranged on the tubular part (39) downstream of the seal (42) and with this forms a second air space (45) to which the cooling air is fed from the second channel (49). 3. Hochleistungswellvo.richtung according to claim 2, characterized by a Wärmeaustauscher- i ^r > serpentine (51) which is arranged on the tubular part (39) within the second air space (45), and by channels (52, 53), which with the heat exchanger coil; (51) are connected to the line of cooling medium. 4. high-performance corrugating device according to claim 1 to 3, characterized in that each forming device (14, 15) comprises a cooling air fan (59, 60) and an air distribution duct (57, 58) which extends along the return run of the chains (17, 18; 19, 20) « extends and serves to apply cooling air to the exposed inner sides of the half-molds (16). 5. High-performance corrugating device according to one of claims 1 to 4, characterized in that each Forming device (14, 15) also one by a so Cooling water tank formed heat reducer (61,62) and means for adjusting the temperature of the Comprises heat reducer for preheating or cooling the half-molds (16). 6. High-performance corrugating device according to one of claims 1 to 5, characterized in that an intermediate piece (38) is arranged between the spray head (29) and the tubular part (39), which has several channels, the first air channel (46) with the Air inlet (47) for guiding the compressed air, the second air duct (49) with the air inlet (48) for supplying the cooling air and the inlet and outlet ducts (54, 55) for supplying cooling medium to the heat exchanger coil (51) are provided. ^b5 The invention relates to a high performance corrugating device for the production of corrugated thermoplastic plastic pipe according to the preamble of the claim 1 according to DE-AS 12 53 446. Known corrugating devices of this type are, with regard to their operating speed, that to be produced Pipe size and the quality of the pipe produced are very limited. The main limiting factor is the speed with which the formed pipe from the plastic state to a Temperature at which it can be safely removed from the mold. At a known device of this type (DE-AS 12 53 446) is the thermoplastic plastic, which by a Spray nozzle is applied to the interior of the molding device by blowing air flowing into an intermediate the spray nozzle and a thickening space is introduced into the grooves of the by half-molding formed molding device pressed into it. After the widened plastic tube the thickening has happened, a cold liquid cooling medium acts on the plastic hose. To prevent the To prevent cooling medium, the plastic hose is raised after it has cooled down a little out, so that the liquid cooling medium is held in the hose. However, this is only possible as long as the hose to be cooled moves slowly forward. If there is a slightly faster movement, will the pockets formed by the transverse grooves move the liquid cooling medium along with the hose. The known methods of cooling are for high-performance production of high quality pipes unusable. The invention is based on the object of creating a corrugating device of the type mentioned, in which faster cooling of the molded thermoplastic material is achieved than was previously possible has been. According to the invention, this object is achieved by the features of the characterizing part of the main claim solved. Additional cooling devices for cooling the half-molds are advantageously built into the device. The invention is explained in more detail below using an exemplary embodiment in the drawing. It shows F i g. 1 is a side view of a heavy duty corrugating device according to the invention; F i g. 2 shows a section along the line 2-2 in FIG. 1; F i g. 3 guides for half-molded housing; 4 shows a longitudinal section through an internal cooling system the device and F i g. 5 shows a section along the line 5-5 in FIG. 4th According to FIGS. 1 and 2, the corrugating device has a on wheeled construction comprising a carriage 10 seated on wheels 11. The wheels run on rails 12. A support structure 13 is arranged on the carriage 10 and carries two complementary ones upper and lower mold assemblies 14, 15. Each mold assembly comprises an endless chain of Half-molds 16 which are hingedly connected to one another. Each half-shape extends in the transverse direction between opposite links of two endless conveyor chains 17, 18 and 19, 20, as in FIG. 2 shown is. The chains run around drive sprockets 21, 22 and 23, 24 (Figs. 1, 2 and 3) around and are guided for movement along endless paths passing through the