NOZZLE TERMINAL FOR INJECTORS OF PLASTIC MATERIAL INJECTION MOULDING APPARATUS

Abstract

A nozzle terminal for injectors of plastic material injection moulding apparatus, includes a tubular tip defining a flow passage for the injected plastic material and including a radially inner element made of a first abrasion resistant material, an intermediate element made of a second high thermal conductivity material, and a radially outer element made of a third corrosion resistant material. The radially inner, intermediate and radially outer elements are joined to each other in intimate mutual contact, and the radially outer element fully covers the intermediate element thus insulating it from the environment.

Claims

1. A nozzle terminal for injectors of plastic material injection moulding apparatus, comprising a tubular tip defining a flow passage for injected plastic material and a ring nut coaxial to the tip, said tip including a radially inner element made of an abrasion resistant first material, an intermediate element made of a high thermal conductivity second material, and a radially outer element made of a corrosion resistant third material, and wherein said radially inner, intermediate and radially outer elements are joined to each other in intimate mutual contact, and wherein the radially outer element fully covers the intermediate element which is thus insulated from the environment.

2. The nozzle terminal according to claim 1, wherein the intermediate element is in continuous contact with the radially inner element.

3. The nozzle terminal according to claim 1, wherein the radially outer element is in continuous contact with the intermediate element.

4. The nozzle terminal according to claim 1, wherein said radially inner, intermediate and radially outer elements are coupled to each other by interference.

5. The nozzle terminal according to claim 1, wherein the radially outer element is hermetically fixed at its ends to the radially inner element.

6. The nozzle terminal according to claim 5, wherein the ends of the radially outer element are soldered to the radially inner element.

7. The nozzle terminal according to claim 1, wherein the radially inner element comprises a distal portion having a substantially constant thickness and extending up to a free end of the tip and the intermediate element is applied to such distal portion.

8. The nozzle terminal according to claim 7, wherein the intermediate element has a constant thickness which is substantially equal to a thickness of said distal portion of the radially inner element.

9. The nozzle terminal according to claim 8, wherein the radially outer element has a thickness less than the thickness of said distal portion of the radially inner element and the intermediate element.

10. The nozzle terminal according to claim 9, wherein the radially outer element has a thickened end portion enclosing the free end of the tip.

11. The nozzle terminal according to claim 1, wherein the first material is a stainless steel of the tempered or hardened martensitic type having a high hardness.

12. The nozzle terminal according to claim 11, wherein the second material is copper or an alloy thereof.

13. The nozzle terminal according to claim 12, wherein the third material is a stainless steel of the tempered or hardened martensitic type having a high hardness.

14. The nozzle terminal according to claim 1, wherein the third material is same as the first material.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] The invention will now be described in detail, purely by way of non-limiting example, with reference to the attached drawings, wherein:

[0014] FIG. 1 is a schematic view and in partial vertical section of an injection moulding apparatus provided, by way of example, with two injectors with nozzle terminals respectively conventional and according to the invention,

[0015] FIG. 2 is partial view, and in larger scale, of the conventional nozzle terminal of FIG. 1,

[0016] FIG. 3 is a view analogous to FIG. 2 exemplifying a preferred embodiment of the nozzle terminal according to the invention,

[0017] FIG. 4 is a view in larger scale showing only the tip of the nozzle terminal of FIG. 3 and

[0018] FIG. 5 is an exploded perspective view of the tip.

DETAILED DESCRIPTION OF THE INVENTION

[0019] Initially with reference to FIG. 1, a plastic material injection moulding apparatus conventionally comprises a hot chamber 1 to which the plastic material to be injected in fluid state is supplied under pressure through two injectors 2, 3 of the pin valve type in the case of the illustrated example. Still in a conventional manner, each injector 2,3 comprises a nozzle 4 in communication with the hot chamber 1 and along which a pin valve 5 controlled through the fluid or electrical actuator 6 is axially mobile, conveniently electronically controlled.

[0020] The lower end of the pin valve 5 cooperates with a nozzle terminal, to be addressed further hereinafter, to open or close the flow of the plastic material through the injection passage (gate) of a mould.

[0021] The injector 2 is provided with a conventional nozzle terminal, i.e. according to the prior art, indicated with reference n 7 and illustrated further in detail in FIG. 2. It comprises an inner tubular body 8, called tip and formed by a single piece made of high thermal conductivity material (typically copper or its alloys), and a hollow element 9, made of a lower thermal conductivity material, called ring nut. The ring nut 9 projects beneath the tip 8 for sealing coupling, at the free end thereof, with a mould at the relative injection passage. The injector 3 represented on the right part of FIG. 1 is instead provided with a nozzle terminal according to the invention, indicated in its entirety with 10 and represented further in detail in FIGS. 3 to 5. Even in this case, it comprises the ring nut 9, substantially analogous to that according to the prior art, and an inner tubular body or tip indicated in its entirety with 11.

[0022] According to the distinctive characteristic of the invention, the tip 11 is formed by three components, permanently joined to each other in continuous intimate mutual contact: A a radially inner element 12 made of a first abrasion resistant material, an intermediate element 13 made of a second high thermal conductivity material, and a radially outer element 14 made of a third corrosion resistant material.

[0023] The radially inner element 12 has a thickened proximal portion 15, inserted and locked in the nozzle 4 as represented in FIG. 3, and a distal portion 16 which projects outside the nozzle 4 and with the lower end of the pin valve 5 cooperates. The distal portion conveniently has a constant thickness.

[0024] The intermediate element 13 surrounds and winds the distal portion 16 of the radially inner element 12 externally in a coaxial fashion, substantially over the entire axial extension of the latter save for a portion corresponding to the free end 17 of the tip 11. The intermediate element 13 is made of a second material, different from the first material, and it also has a thickness constant and substantially equal to that of the distal portion 16 of radially inner element 12.

[0025] The radially outer element 14, whichas mentioned fully covers the intermediate element 13 thus hermetically insulating from the external environmentis made of a third material, equal or different with respect to the first material of the radially inner element 12, and it preferably has a thickness considerably smaller than that of the intermediate element 13 and the distal portion 16 of the inner element 12. As clearly visible in FIG. 4, the radially outer element 14 is soldered at the ends 14a, 14b thereof to the distal portion 16 of the radially inner element 12. The end 14b thereof is conveniently thickened and surrounds the free end 17 of the radially inner element 12, thus fully winding it.

[0026] As observed previously, the three elements 12, 13 and 14 of the tip 11 are at close contact with respect to each other: the intermediate element 13 is applied in an interfering fashion against the outer surface of the distal portion 16 of the inner element 12 and the outer element 14 is applied in an interfering fashion against the outer surface of the intermediate element 13.

[0027] The first material, with which the radially inner element 12 is made, which is at contact with the polymeric material slidingly towards the mould cavity during the injection, is a material with high mechanical resistance, high resistance against wear, oxidation, abrasion and chemical agents: it is preferably a stainless steel, especially of the tempered or hardened martensitic type and characterised with high hardness (49-51 HRC).

[0028] The second material which forms the intermediate element 13 is a high conductivity material, selected as a function of the polymeric material to limit the drawbacks that may arise during the moulding (for example stringing and drooling): given that it is not at direct contact with the polymeric material, it is preferably made of copper or its alloys.

[0029] The third material of the radially outer element 14, also capable of guaranteeing high mechanical resistance as well as resistance against oxidation, wear, high temperatures and corrosion caused by the gases released during the moulding process, is preferably a stainless steel, especially of the tempered or hardened martensitic type.

[0030] The radially outer element 12 and the radially outer element 14 can be obtained using the same material.

[0031] Obviously, the construction details and the embodiments of the tip may widely vary with respect to what has been described and illustrated by way of example. In addition, though the invention has been described with reference to a nozzle terminal for injectors of the valve pin type, it also equally advantageously applies to any type of injector, for example also with free or torpedo flow, and any type of ring nut (in the figure or external).