DE3525736C1 - Hot runner nozzle for injection moulding - Google Patents

Abstract

Hot runner nozzle for injection moulding in which a core 14 provided with a heating element 18 delimits an annular channel 29, 31 for plastic to be fed through the nozzle, terminates at the front in a tip in a nozzle opening 8 and is provided with a temperature sensor 26 the measuring part 27 of which is arranged in a tip piece 17 delimiting an annular channel. In a nozzle of this kind, it is desirable if the temperature sensor uses the temperature of the plastic for controlling the heating element. This is achieved in that the measuring part 27 is arranged outside the core 14 in the annular channel 31. The temperature of the plastic and thus its degree of fluidity can be controlled with improved accuracy, which is important in the injection moulding of many types of plastic. <IMAGE>

Description

The invention relates to a hot runner nozzle for injection molding, accordingly the preamble of claim 1.

With a known Device of this type (DE-GM 76 04 533) is the measuring part of the tempera Door sensor arranged within the core and can therefore only the respective temperature of the tip of the core play. Changes in the temperature of the plastic itself can only be determined insofar as they are in the Work the tip of the core up to the measuring part. Because with the temperature sensor the heat output of the heating element can be controlled this control changes the plastic temperature only clumsy and imprecise follow.

The object of the invention is therefore to provide a hot runner nozzle to create the type mentioned at the temperature  sensor the temperature of the plastic to control the heating element. The hot runner nozzle according to the invention is solving this problem, characterized in that the measuring part is arranged outside the core in the ring channel.

The temperature of the plastic will be as close as possible the nozzle opening and thus the supply of heat from controlled the heating element in the plastic. It can be now the temperature of the plastic and thus its flow regulate the degree of fluidity with improved accuracy, Injection molding of some types of plastic is important. The invent proper arrangement of the measuring part is particularly in such Nozzles attached that have a constantly open nozzle opening have, in which case the plastic, if not ge is sprayed, is liquid in and behind the nozzle opening. Surprisingly, the measuring part of the temperature sensor is the Strains grown on him from the pouring Plastic are exercised. The measured value is recorded in the flowing plastic mass and in a calm Plastic flow zone. The sensor is between the core and coat in the product flow.

It is particularly expedient and advantageous if the measuring part at the free end of the temperature sensor wires taking tube located on the core from the outside. The tube guides the measuring part the respective temperature of the Core too, so that the controller also the core temperature can take into account. With just one temperature sensor, the Control made dependent on two temperature variables.  

It is particularly expedient and advantageous if the The core is in a jacket free of heating elements and that Tube of the temperature sensor lies against the jacket. Because of this design also affects the temperature of the jacket Measured value, the jacket due to its contact with the core is heated by this.

It is also particularly expedient and advantageous if that Tubes placed in a groove on the surface of the core is. Here is the contact between the core and the tube so that the transfer of heat from the core to the measuring part ver improves.

The temperature sensor is usually a thermocouple. The Sheath is usually from the other hot runner tool stored separately and insulated. Because the isolation of this Nozzle cartridge opposite the other hot runner mold in Connection with the precise temperature control by means of a Temperature sensor is important, the following features are individual or in combination of special interest:

The jacket of the nozzle cartridge is at a distance from one surrounded cladding tube, the contact surface between the core and Sheath is approximately equal to the interface between the channel and jacket, along the heated area of the core the circumference changes the contact surface between the core and the jacket with the contact surface between the channel and the jacket Cladding tube is in the axial direction on flanges on the jacket  pushed, lies on a step in the axial direction and is fixed by friction fit.

In the drawing is a preferred embodiment of the hot runner nozzle according to Invention shown and shows

Fig. 1 pour a first longitudinal section through the hot runner nozzle for injection,

Fig. 2 shows a 90 ° offset with respect to FIG. 1, the second longitudinal section of the hot runner nozzle according to Fig. 1 and

Fig. 3 is a section according to line III-III in FIG. 1.

The hot runner nozzle according to the drawing comprises a wall 1 which delimits a mold cavity (not shown in more detail) and is formed by a tool part 2 . At a distance from this tool part 2 , a counter plate 3 is provided as a further tool part, which is braced relative to the tool part 2 in a manner not shown but known per se. Between the tool part 2 or the wall 1 and the counter plate 3 , a nozzle cartridge 4 is inserted, which has a flat end face 5 at the back and rests flat against one another on a flat area of the counter plate 3 . The nozzle cartridge 5 has at the rear a large, single inlet opening 11 which merges into a hole 12 in the counterplate 3 , to which a cross-section supply line 13 for plastic is connected.

Towards the front, the nozzle cartridge 5 forms an annular end face 6 which is perpendicular to the central axis and from which a circular projection 7 projects in the middle, in which the nozzle opening 8 is arranged in the center. The approach 7 is inserted exactly into a hole 9 in the wall 1 and the tool part 2 comprises the nozzle cartridge 4 at the front end area with a circumferential ledge 10 . Otherwise, the nozzle cartridge 4 is not in contact with tool parts. The adjacent to the nozzle cartridge 4 and other, the nozzle cartridge neigh disclosed, not shown tool parts, usually have a device for cooling.

The nozzle cartridge 4 has a core 14 which is pushed into a jacket 15 on which a cylindrical cladding tube 16 is seated. Both the front end face 6 and the shoulder 7 and the rear end face 5 are formed by the jacket 15 . The core 14 has a pointed end piece 17 which tapers conically towards the front, the tip of which lies in the nozzle opening 8 . At the tip end piece 17 , an elongated core piece connects to the rear, in which an elongated heating element 18 is placed. The elongated core piece continues behind the heating element 18 like a tube and has a radially outwardly projecting flange 19 at the rear end. In the Rohrbe rich a mushroom-like end piece 20 is inserted from behind, the head of which is adapted to the cross section of the core 14 . The stem of the end piece 20 is provided with a slot 21 which is pushed onto a pin 22 which passes through the core 14 and both ends of which protrudes into the jacket 15 in order to secure the core 14 and its end piece against rotation.

This design makes it possible to push the heating element 18 into the core 14 from behind and then to close it off with the end piece 20 . Somewhat in front of the end piece 20 , a nozzle 23 protrudes radially from the core 14 and forms a protective tube. Through the nozzle 23 , two connecting wires 24 for the heating element 18 in the core 14 and a tube 25 of a temperature sensor 26 , which leaves the nozzle 23 inside the jacket 15 , but outside the core 14 . The temperature sensor tube 25 runs forward in contact with the core 14 and the jacket 15 , to the region of the pointed end piece 17 , as close as possible to the tip thereof. The temperature sensor tube 25 lies in a groove of the core 14 , close to this nestled. In a manner not shown, but known per se, two insulated wires made of different metals run in the tube 25 and are connected to one another at the front end by a welding bead, ie a measuring part 27 , so as to form a thermocouple.

The jacket 15 forms a substantially cylindrical cavity which tapers conically in the region of the pointed end piece 17 towards the nozzle opening 8 . From the end piece 17 towards the rear, the core 14 rests on two mutually opposite sides of the jacket 15 along a circular arc-shaped contact surface 28 , the circular arc extending over more than 90 ° on each side. Between these arcs 28 , the core 14 is flattened behind the end piece 17 on two opposite sides, so that two channels 29 run between the core 14 and the jacket 15 , which form an arcuate contact surface 30 with the jacket 15 , the arc on each side extends over less than 90 °. Each channel 29 extends from the pointed end piece 17 with a constant cross section to the rear of the end piece 20th The two channels 29 merge into a conical annular channel 31 in the region of the end piece 17 , which opens into the nozzle opening 8 .

The jacket 15 forms an elongated jacket piece 32 , which has the nozzle opening 8 at the front and abuts at the rear with a striking surface 39 against the flange 19 of the core 14 . The jacket piece 32 is provided at the rear end region with an outer thread of a screw connection 33 , onto which the inner thread is screwed an end cap 34 which engages behind the core 14 or its end piece 20 and forms the inlet opening 11 . The end piece 20 forms two bevels 35 away from a center line, each of which leads to one of the channels 29 or forms the end widening of the channel. The bevels 35 leading away from the center line divide the plastic coming through the inlet opening 11 and guide it into the channels 29 of constant diameter. Following the end cap 34 , the jacket piece 32 forms a stop step 36 for the cladding tube 16 , which rests on two flanges 37 at its front and rear ends. The cladding tube 16 is spaced 38 from the jacket 15 all around.

Claims (4)

1. Hot runner nozzle for injection molding, in which a core provided with a heating element limits an annular channel for plasticizer to be guided through the nozzle, runs out into a pointed end piece at a nozzle opening and is provided with a temperature sensor, the measuring part in the area of the pointed end piece delimiting part of the ring channel, characterized in that the measuring part ( 27 ) is arranged outside the core ( 14 ) in the ring channel ( 31 ). 2. Hot runner nozzle according to claim 1, characterized in that the measuring part ( 27 ) is located at the free end of a tube receiving the temperature sensor wires ( 25 ) which bears against the core ( 14 ) from the outside. 3. Hot runner nozzles according to claim 2, characterized in that the core ( 14 ) is in a jacket ( 15 ) free of heating elements and the tube ( 25 ) of the temperature sensor ( 26 ) abuts the jacket ( 15 ). 4. Hot runner nozzle according to claim 2 or 3, characterized in that the tube ( 25 ) is inserted into a groove on the surface of the core ( 14 ).