DE4432966A1 - Economical injection moulding of plastics device with metal on pt. of surface - Google Patents

Abstract

The plastics device comprises a moulding (1) of a first plastics component (I) with electroconductive section(s) (4,5) produced by placing metal layer(s) (8,9) on the surface of a region, consisting of a second plastics component (II), of the shape and size corresp. to the section. The moulding is produced by 2-component injection moulding and (part of) the metal layer is produced by electroless or purely chemical deposition. (II) consists of polyamide PA 6, PA 6.6 and/or PA 6.6/6, acrylonitrile-butadiene-styrene (ABS), polyoxymethylene (POM), liquid crystal polymer (LCP, polyetherimide (PEI), polyethersulphone (PES), polypropylene (PP) and/or polycarbonate (PC). The moulded devices are also claimed.

Description

The invention relates to a method according to Ober understood claim 1 as well as a by this method manufactured component or component. Such a process or such a component are the subject of the main patent.

It has already been proposed (DE 41 25 298), a carrier plate for holding a door handle for a motor vehicle door a thermoplastic by injection make and on this carrier plate electrical traces for connecting various electrical components galvanic deposition of metal layers on the upper to form the surface of the carrier plate. This well-known ver driving has the advantage that in the spray used cast inlaid metal strips forming the conductor tracks are avoided and in particular this also makes it possible the conductor tracks on spatially shaped surfaces of the To provide support plate. However, this procedure alone already because of the galvanic application of the conductor tracks and the preparatory process steps required for this significant disadvantages.

The object of the invention is to demonstrate a method with which is even more economical and efficient, Components with integrated electrically conductive sections to manufacture.

To solve this problem, a method according to the characterizing part of claim 1 is formed.

A component according to the invention is characterized by the Features of the characterizing part of claim 15 out.  

The invention makes it particularly economical and rationally, elements or components of the under to produce a wide variety of shapes, with inte grierte, electrically conductive sections, such as Conductor tracks, contact areas, vias, heating trains etc.

The plastics for the first and second components are like this selected that the first component is a non-metallized is hard or difficult to metallize plastic, d. H. on Plastic, the surface of which after the Forms subsequent pretreatment none or almost none Undergoes change or roughening such that a me tallization is possible.

The following are particularly suitable for the first component Plastics (polyamides):

Polymers are particularly suitable for the first component, which are highly resistant to chemical pretreatment have, which in the inventive method the production of the molding in the two-component injection molding process connects.

The following polyamides are suitable, for example:

Basically, one is also suitable for the first component A number of other PA types (polyamide types), namely for example wise soot-filled PA types from various manufacturers, PA11, PA12, PPA, Grivory from EMS-Chemie. Basically can be said that an increased filler content of <50% with other PA types the metallization properties reduced and makes them usable for the first component.  

The following are preferably suitable as the second component Polymers:

Group PA6, PA6.6, PA6.6 / 6 polyamides
Acrylonitrile butadiene styrene ABS
Polyoxymethylene POM
Liquid Cristal Polymer LCP
Polyetherminide PEI
Polyether sulfone PES
Polypropylene PP
PC polycarbonate

Polymers with a glass fiber are also particularly suitable additive.

The following metals are also suitable for the second component sizable PA types with glass fiber content (GF), namely

According to a preferred embodiment, this  inventive method at least six methods steps, namely:

• 1. Injection molding a preform from the first or second component.
• 2. In-mold injection or overmolding of the pre-molded part the first process step with the second component or with the first component;
• 3. Chemical pretreatment (adhesion promotion), esp especially for the roughening of the second component surface formed in process steps 1 and 2 manufactured blank;
• 4. Activate the surface of the second component by Surface germination with metal, preferably precious metal;
• 5. Electroless metal plating of the germinated surface;
• 6. Galvanic or electroless post-metallization.

Let further advantages of the method according to the invention can be summarized as follows:

Inexpensive production even in the form of very complex components;
simple miniaturization of components;
Since the area carrying the at least one electrically conductive section is embedded in the molded body or carrier, cracks in the metal layer or in conductor tracks caused by thermal changes in length are also avoided.

Basically, all design options are there for Plastic parts are there, even with the Ver drive feasible, including the metal surfaces and conductor tracks, e.g. B. also snap or Rastele elements, for example snap hooks for attaching Microswitches etc.

In the method according to the invention, the entire component undergo chemical pretreatment after molding, with a chemical nickel plating on the  metallizable plastic ends. On this stop ver Nickelung can then further layers of metal under various types can be applied. By using it the different plastics become structured Metallization (only on the surface of the second component and not on the surface of the first component) without masking techniques etc.

With the invention it is possible in particularly economical Licher and rational way components in different to produce the best shape, with integrated electrically conductive sections, for example conductors tracks, contact areas, vias, etc. can.

In particular, it is also possible with the invention to conductors track-bearing support plates with associated function elements, e.g. B. lamp holders, etc., to be made in one piece, so that assembly work to attach such function elements on printed circuit boards are omitted, as are additional ones Fasteners, which simplifies manufacturing and result in considerable weight savings.

The fact that both the molded body and the first component as well as the at least one integrated into this molded body Area from the second component each made of thermoplastic chemical plastic material, is that with the inventions Component manufactured according to the method also problem ready to be recycled.

Are thermoplastics with high heat resistance speed used, the corresponding components or Components can also be soldered.

Further developments of the invention are the subject of the Unteran claims.

The invention is based on the figures Exemplary embodiments explained. Show it:  

1 shows a perspective partial view of a fabricated plastic function or device having provided on two surfaces of this component conductor tracks.

Fig. 2 shows a section along the line II of Figure 1 in the various steps of the manufacturing process.

Figures 3 and 4 in partial representation further possible execution forms of a component in perspective and in section;

FIGS. 5 and 6 designed as a lamp socket device in side view and in section.

The component 1 shown in FIGS . 1 and 2 has a three-dimensional body which is made in one piece from thermoplastic by injection molding and has, for example, a plurality of wall sections adjoining one another at an angle or in some other way, of which only the two wall sections 2 in FIG. 1 and 3 are given again.

Electrical conductor tracks are formed on the outer surface of the three-dimensional component 1 , which follow the surface of the component or its body. For the sake of simplicity, only two such conductor tracks 4 and 5 are shown in FIG. 1, which run parallel to one another and at a distance from one another.

The preparation of the device takes place in several Ver method steps, for example, so that in a first process step in a suitable mold at first the body or shaped body of the device 1, 1 that is in the representation of Fig., The two angles interconnected, integrally formed with each other WALL COMP sections 1 and 2 are formed, and from component K1 ( Fig. 2, position a).

Where later a conductor track 4 or 5 is to run, a groove-shaped recess 6 is cut out by a tool part, for example a slide, which extends over the entire course of the later conductor track 4 or 5 ( FIG. 2, position a).

In a second process step, the cavity or the recess 6 is then filled in by injection of a second plastic or a second component K2, with the molded body remaining in the mold, so that where later a conductor track 4 or 5 is to run on the relevant surface of the A band-shaped region 7 , which is exposed on this surface and firmly embedded in the first component K1, is formed from the second thermoplastic material or the second component K2. This area 7 also extends over the entire length of the subsequent conductor track 4 or 5 ( FIG. 2, position b).

In a third process step, the blank produced using components K1 and K2 is chemically pretreated in such a way that this chemical pretreatment roughenes the surface formed by second component K2, ie the surface of area 7, or particles are built into this surface enable a selective application of the metallization in the subsequent process steps.

Each portion 7, in a fourth process step then selectively on the exposed surface of a seed layer, for example of a metal such. B. from a noble metal, for example made of gold, applied without current or by purely chemical deposition.

In a fifth process step is then electroless or by purely chemical deposition on the germinated upper surfaces, a stop metallization (layer 8 ) z. B. in an immersion bath into which the molded part is introduced. The thickness of this layer 8 is, for example, 0.5-2.0 µm. The layer 8 extends over the entire length of each region 7 ( FIG. 2; position c).

In a further process step is then also applied in an immersion bath purely chemical on each layer 8 an the actual conductor forming layer 9, the layer thickness is selected to the respective application according to and adjustable by the length of time the mold is in the in the second immersion bath. Layer 9 is, for example, a nickel layer. B. in the second immersion bath layer thicknesses of about 10-30 microns per hour ( Fig. 2, position d).

The component 1 produced in this way can then optionally be further galvanically treated without any problems.

The thermoplastic used for component 1 and the thermoplastic used for the areas 7 are coordinated so that both plastics or components K1 and K2 form a firm connection, yet are so different in their characteristics that without further measures se selective chemical deposition of the metallizations, ie the layer 8 , but also the layer 9 , takes place exclusively on those surfaces which are formed by a region 7 or by the thermoplastic used for this purpose.

The plastics of the first component and the are preferred second component those of the same basis.

As stated above, the plastic is for the first Component K1 selected so that this plastic is not or only compared to the plastic of the second component very difficult to metallize in the chemical process.

A metallizable plastic is for the second component selected.  

The manufacturing method described above for the component 1 with the conductor tracks 4 and 5 is extremely simple in terms of the method sequence and, above all, also permits economical and rational production of components or molded parts with integrated conductor tracks. The course of the conductor tracks results exclusively from the course of the regions 7 , which can be easily implemented using the multi-component injection molding technique.

The possibility of a more economical and rational Manufacturing exists especially against all gal vanic process.

The described method can also be used to make complex ones Manufacture components or component without problems. Especially it is also possible with the technique described for certain components or components particularly small To achieve sizes.

The components produced can be easily taken care of, since the respective component 1 and the regions 7 on which the conductor tracks are formed can be realized by components of the same type.

FIGS. 3 and 4 show a plate-shaped component or form part 1 a, on its surface sides in each case a conductor track 10 and, specifically, each of these conductor tracks 11 is formed, in turn, to an event in the component K1 Bettenen area 7 of the component K2.

In the middle of the component 1 a, the two conductor tracks 10 and 11 are electrically connected to one another by a via 12 . This plated-through hole is realized in that, in the first process step, not only the cavities 6 for the regions 7 were saved out by parts of the mold, but also an opening connecting the two surface sides of the component 1 a, in which an in the second process step the wall of this opening adjoining sleeve-like area 13 was formed from component K2, in such a way that both areas 7 merge into this area 13 . The area 13 forms a continuous opening 14 , through which the chemical bringing on of the layer 8 and of the further layer 9 is also possible on the area of the area 13 surrounding the opening 14 .

FIGS. 5 and 6, finally, show a further example of a device or mold 1 b with the form of a circuit board 15 with integrated lamp holder 16 for a lamp 17.

Conductor paths 18 and 19 and a contact thread 20 and a contact surface 21 are in turn formed as connections for the lamp 17 , the contact surface 21 being connected to the conductor path 19 by a through-contact 22 corresponding to the through-contacting 12 .

All conductor tracks, contact areas, contact threads and Vias are by chemical deposition of the metallizations on the activated for this deposition ten, d. H. Areas made from component K2 generated, the latter in turn by forms of the Component or molded body in the two component spray procedures are realized.

The invention has been described above using exemplary embodiments described. It is understood that changes as well as variance lungs are possible without thereby of the invention leave the underlying inventive concept.

With 23 in FIGS. 1 and 4 each a pin on the top of the component 1 or 1 a projecting contact is designated. This is made of metal and embedded in a so-called in-mold process in the manufacture of the component in both the component K1 and the component K2 and therefore projects beyond the area 7 formed by the component K2, so that after the application of the Layers 8 and 9 , ie after the production of the conductor track 5 or 10, the contact pin 23 is electrically connected to this conductor track.

Reference list

1 , 1 a, 1 b molded part
2 , 3 wall section
4 , 5 conductor track
6 cavity
7 area
8 layer (stop metallization)
9 more layers
10 , 11 conductor track
12 through-plating
13 area
14 opening
15 circuit board
16 lamp holder
17 lamp
18 , 19 conductor track
20 contact thread
21 contact surface
22 plated-through holes

Claims (30)

1. A method for producing a component made of plastic, with a molded body formed by a first component (K1) of a plastic, with at least one electrically conductive section ( 4 , 5 ; 10 ) provided on the molded body ( 1 , 1 a, 1 b), 11 ; 18 , 19 ; 12 , 20 , 21 ), which is produced by applying at least one metal layer ( 8 , 9 ) to a surface ( 7 ) which corresponds to the shape and the course of the section and which consists of a second component (K2 ) of a plastic, the molded body ( 1 , 1 a, 1 b) and the area ( 8 , 13 ) provided in this molded body being produced in a two-component injection molding process, the application of at least part of the thickness of the electrically conductive section forming metal layer ( 3 , 9 ) by electroless or purely chemical deposition and for the first component (K1) a non-metallizable plastic or in comparison to the second component (K2) weld rer metallizable plastic is selected, according to patent. . . (Patent application P 44 16 986.8), characterized in that at least one plastic according to the following groups is used for the second component (K2): polyamides from group PA6, PA6.6, PA6.6 / 6
Acrylonitrile butadiene styrene ABS
Polyoxymethylene POM
Liquid Cristal Polymer LCP
Polyetherminide PEI
Polyether sulfone PES
Polypropylene PP
PC polycarbonate. 2. The method according to claim 1, characterized in that the polymer constituting the second component is glass fiber fillers having.   3. The method according to claim 1 or 2, characterized in that in the two-component injection molding process in a first process step using the second component of the region to be metallized ( 7 ) or part produced as a pre-molded part and then without removing this pre-molded part from the Mold in the in-mold process in a second process step using the first component (K), the part or molded body not to be metallized on its surface is produced. 4. The method according to claim 1 or 2, characterized in that in the two-component injection molding process in the first process step with the first component (K1) of the part or molded body not to be metallized and in the second process step without removing this molded body from the Mold in the in-mold process, the part or region ( 7 ) to be metallized is produced using the second component (K2). 5. The method according to any one of claims 1-4, characterized characterized in that in a third step a chemical pretreatment (adhesion promotion) like this that the second component (K2) formed surface of the molding roughening is carried out in a fourth step each chemically pretreated by the second compo nente formed surface with metal, preferably with Precious metal is germinated, preferably by electroless application that in a fifth process step of electroless metal plating the germinated surface, and that in one sixth process step a galvanic and / or Electroless post-metallization takes place. 5. The method according to any one of claims 1-5, characterized characterized in that the second component (K2) Plastic with a compared to the first compo nente (K1) is higher moisture absorption.   7. The method according to any one of claims 1-6, characterized in that the surface of the area formed by the second component (K2) for the metallization is first chemically dissolved and germinated with a metal or noble metal and / or with a stop layer ( 8 ) made of metal or precious metal, for example gold, and that in a further process step is also produced by chemical deposition in the immersion bath, a further metal layer, preferably a nickel layer ( 9 ). 8. The method according to any one of claims 1-7, characterized records that the one forming the second component (K2) Plastic one from the group PA6, PA66, PA66 / 6, PMMA, ABS, PVC, PUR, UP is. 9. The method according to any one of claims 1-8, characterized in that the at least one electrical section is a conductor track ( 4 , 5 ; 10 , 11 ; 18 , 19 ). 10. The method according to any one of claims 1-9, characterized in that the at least one section is a contact surface ( 20 , 21 ). 11. The method according to any one of claims 1-10, characterized in that the electrically conductive section is a via ( 12 , 22 ) having an electrically conductive section ( 10 , 19 ) on a surface side of the component ( 1 b) with an electrically conductive section ( 11 , 22 ) on the other surface side of the component electrically connects, and that the through contact ( 12 , 22 ) is made in that a continuous opening ( 14 ) is formed in the component by means of the two-component injection molding process, and that the area delimiting this opening is at least partially formed by an area consisting of the second component (K2). 12. The method according to any one of claims 1-11, characterized characterized in that the first component (K1) and the the second component (K2) forming plastic in each case are of the same basis. 13. The method according to any one of claims 1-12, characterized characterized by the electroless or chemical Deposition a metal stop layer applied is, and then on this stop layer as a conductor a metal layer of greater density is applied. 14. The method according to any one of claims 1-13, characterized characterized that in one and the same tool first in a first shot that from the first Component (K1) formed base or molded body and in a second shot from the second component (K2) formed base layer are generated. 15. The method according to any one of claims 1-13, characterized characterized in that in a single form in one First shot of the respective metal layer or conductor-carrying part on the second component (K2) and in a second shot of the basic or form body are made. 16. Component made of plastic, with a molded body formed by a first component (K1) of a plastic, with at least one electrically conductive section ( 4 , 5 ; 10 , 11 ; 18 ) on the molded body ( 1 , 1 a, 1 b) 19 ; 12 , 20 , 21 ) which is produced by applying at least one metal layer ( 8 , 9 ) to a surface ( 7 ) corresponding to the shape and shape of the section of an area ( 7 ) made of a second component (K2) of a plastic there is, the molded body ( 1 , 1 a, 1 b) and the area ( 8 , 13 ) seen in this molded body in a two-component injection molding process, the application of at least part of the thickness of the electrically conductive portion forming metal layer ( 3 , 9 ) is carried out by electroless or purely chemical deposition and for the first component (K1) a non-metallizable plastic or in comparison to the second component (K2) heavier metallizable Kun Ststoff is selected, according to patent. . . (Patent application P 44 16 986.8), characterized in that the second component is a polymer from the following group: polyamides group PA6, PA6.6, PA6.6 / 6
Acrylonitrile butadiene styrene ABS
Polyoxymethylene POM
Liquid Cristal Polymer LLCP
Polyetherminide PEI
Polyether sulfone PES
Polypropylene PP
PC polycarbonate. 17. The component according to claim 16, characterized in that the the second component forming polymer glass fiber fill has fabrics. 18. Component according to claim 16 or 17, characterized in that in the two-component injection molding process in a first process step using the second component of the region ( 7 ) or part to be metallized as a pre-molded part and then without removing this pre-molded part from the Mold in the in-mold process in a second process step using the first component (K), the part or molded body not to be metallized on its surface is produced. 19. Component according to claim 16 or 17, characterized in that in the two-component injection molding process in the first process step with the first component (K1) the part or molded body not to be metallized and in the second process step without removing this molded body from the Mold in the in-mold process, the part or region ( 7 ) to be metallized is produced using the second component (K2). 20. Component according to one of claims 16-19, characterized characterized in that in a third step a chemical pretreatment (adhesion promotion) like this that the second component (K2) formed surface of the molding roughening is carried out in a fourth step each chemically pretreated by the second compo nente formed surface with metal, preferably with Precious metal is germinated, preferably by electroless application that in a fifth process step of electroless metal plating the germinated surface, and that in one sixth process step a galvanic and / or Electroless post-metallization takes place. 21. Component according to one of claims 16-20, characterized characterized in that the second component (K2) Plastic with a compared to the first compo nente (K1) is higher moisture absorption. 22. Component according to one of claims 16 or 17, characterized in that the surface of the region formed by the second component (K2) for the metallization is first chemically dissolved and germinated with a metal or noble metal and / or with a stop layer ( 8 ) made of metal or precious metal, for example gold, and that in a further process step is also produced by chemical deposition in the immersion bath, a further metal layer, preferably a nickel layer ( 9 ). 23. Component according to one of claims 16-22, characterized characterized in that the second component (K2) plastic forming one from the group PA6, PA66, PA66 / 6, PMMA, ABS, PVC, PUR, UP is.   24. Component according to one of claims 16-23, characterized in that the at least one electrical section is a conductor track ( 4 , 5 ; 10 , 11 ; 18 , 19 ). 25. Component according to one of claims 16-24, characterized in that the at least one section is a contact surface ( 20 , 21 ). 26. Component according to one of claims 16-25, characterized in that the electrically conductive section is a via ( 12 , 22 ), which is an electrically conductive section ( 10 , 19 ) on a surface side of the component ( 1 b) with a From electrically conductive section ( 11 , 22 ) on the other surface side of the component electrically connects, and in that the through-contacting ( 12 , 22 ) is made in that a continuous opening ( 14 ) is formed in the component by means of the two-component injection molding process, and that the area delimiting this opening is at least partially formed by an area consisting of the second component (K2). 27. Component according to one of claims 16-26, characterized characterized in that the first component (K1) and the the second component (K2) forming plastic in each case are of the same basis. 28. Component according to one of claims 16-27, characterized characterized by the electroless or chemical Deposition a metal stop layer applied is, and then on this stop layer as a conductor a metal layer of greater density is applied. 29. Component according to one of claims 16-28, characterized characterized that in one and the same tool first in a first shot that from the first  Component (K1) formed base or molded body and in a second shot from the second component (K2) formed base layer are generated. 30. Component according to one of claims 16-29, characterized characterized in that in a single form in one First shot of the respective metal layer or conductor-carrying part on the second component (K2) and in a second shot of the basic or form body are made.