DE19830540A1 - Electronic flexible type circuit board especially for power semiconductors, sensors and passive components - Google Patents

Abstract

An electronic circuit flexible board includes a basic carrier or support for the electronic components, which have at least one contact (6), and a network of conductor paths (9). The basic carrier is a plastics layer (1) having at least one recess running through it, the recess being in alignment with the corresponding contact (6) of the electronic component (2,3) fixed on the plastics layer (4). A metallisation layer (8) is provided on the plastics layer (4) and forms the network of conductors which electrically joins the contact (6) through the corresponding recess (7). The plastics layer is more specifically a plastics film or foil.

Description

The invention relates to an electronic circuit carrier with a basic carrier, with arranged on the basic carrier Electronic components, especially power semiconductors, Sen sorelemente and passive components that have at least one Have contact, and with a trace network as well as a Process for producing the electrical according to the invention Circuit carrier.

The most common circuit carriers are rigid circuit boards, Known boards or the like. On which electronic components, such as chips, IC's, electrical resistors, con arranged capacitors and interconnects connecting the latter are. In addition to the mechanical fastening of the electronic compo nenten on the circuit boards, which by gluing or plug bind can take place, the contacts of the electronics comm components with the corresponding conductor track also electrical get connected. There are some connection techniques for this known as wire bonding or soldering. In this together Hang are common techniques under the abbreviations or Be drawings COB, CSP, TAB, studbump, flip-chip, BGA known.

In the known circuit boards, it is disadvantageous that for the establishment of the electrical contact between the elec electronics component and the conductor network a large space may be necessary. Above all, this has a very disadvantageous effect for those electronic compos to be attached to circuit boards nents that have a very high contact density and therefore with the known manufacturing techniques of electrical Contacts a disproportionately large contact area on the Claim the circuit board.

Therefore, it is an object of the invention to provide an electronic To create circuit carriers that have a space-saving arrangement enables the electronic components and thus at for example electronic components with densely arranged con can record clocks.

This object is achieved in that the basic carrier is a Plastic layer with at least one continuous recess mung includes that with a corresponding contact of the Aligned plastic layer attached electronic component, and that a metallization layer on the plastic layer is arranged, which forms the conductor network and the latter with the at least one contact of the electronic component electrically ver through the corresponding recess binds.

In the circuit carrier according to the invention it is from before partly that no more wire bonding or soldering is required. In addition, by the circuit carrier according to the invention Contact areas between the electronic component and the corresponding conductor track that are smaller than Are 100 µm. In this way, micromechanical sensors light and space-saving arranged on circuit boards the.

An electronic circuit carrier according to the invention in egg ner flexible execution is created by for the Plastic layer a plastic film is used. This is especially advantageous when sensor elements such as Example pressure sensor elements are used, the Printing in a space delimited by the plastic film should vote.

It is a particularly reliable, fictional according electronic circuit carrier, if additionally on the plastic film is applied an insulation layer, the one with the corresponding continuous recess of the  Plastic film aligned passage includes, with the Application of the metallization forming the interconnect network layer on the insulation layer the connection of the conductor track network with the at least one contact of the electronic compo Realize through the passage and the recess is.

Among other things, it is provided that the electronics comm components both on the surface facing away from the conductor track network the plastic layer and glued to the insulation layer can be.

Preferably in the electrical according to the invention Circuit carrier the plastic layer with its the conductor Surface facing away from the rail network on a stabilizing plate attached, preferably glued, the at least one the area arranged facing away from the conductor network electronics component in a preferably continuous recess is inserted in the stabilizing plate. Particularly emp sensitive electronic components are preferably in the Recesses of the stabilizer through the direction of thickness plate used, with at least a side protection this is guaranteed.

Particularly advantageous when using a stabilization besides the electronic components it is also printed Resistors and / or integrated capacitors directly the area of the stabilization facing the plastic layer mounting plate.

For the insulation layer already mentioned, it is especially in the With regard to a technically safe and precise constructed interconnect network cheap, a photostructurable Polymer layer, preferably made of benzocyclobutene, to use the.  

When using sensors with very tight-fitting cones clocking is often sufficient for a conductor track lying on one level no longer for contacting all contacts of the Electronic components. That's why it's fictional modern electronic circuit carrier is advantageous, conductor rail networks in several levels by at least one more Conductor network insulation layer combination on top of each other bring to the conductor tracks required for the contacts To make available.

To protect the electrical circuit carrier from influences from the Protecting the outside environment can result in a dense top layer the surface of the plastic facing away from the conductor track network layer or the stabilizing plate can be applied. This cover layer is preferably made of Cu over the entire surface provides good heat dissipation from the electronic compo realizing. In particular, through the deck provide good protection against EMC radiation continuous

When using sensor elements, such as Pressure sensor elements, the electri according to the invention circuit carrier into the cover layer an opening brings so that the pressure acting on the pressure sensor is not is falsified due to the top layer.

The cover layer is preferably covered by a laminated Fo lie, by sputtering a metal layer or by filling of the recesses arranged in the stabilizing plate formed with a potting compound.

According to the circuit carrier according to the invention, a process for its production is created in that

• a) in a plastic layer at least one continuous Recess is incorporated,  
• b) electronic components on a surface of the plastic be attached in such a way that at least one con clock of an electronic component with the corresponding one Recess is aligned,
• c) a metallization layer on top of the electronic compo nente facing surface of the plastic layer under Her position of an electrical connection between the con clock of the electronic component and the metallization layer is applied through the recess and
• d) a conductor track network by means of a suitable planarization process for the metallization layer is generated.

This method according to the invention is advantageous in that regard liable that the contacting of all contacts on the scarf electronic components with the ent speaking traces by a single process step, namely by applying the metallization layer that is carried out.

A particularly economical manufacturing process will be uses when the conductor track network by a photo structuring ver driving is made.

The continuous recess is preferred in art layer of fabric laser drilled or plasma etched.

To make the manufacturing process particularly economical ten, when incorporating the corresponding account clock of the electronic components aligned, continuous Recesses in the plastic film registration marks for a late Res incorporation of the appropriate passage of the insulation location as well as for the later photostructuring process.

Safe establishment of an electrical contact between the contacts of the electrical component and the conductor track  network-forming metallization layer is guaranteed if the latter on the plastic layer, especially on the Plastic film or insulation layer, is sputtered.

For a stable arrangement of the plastic layer, this is on attached to a stabilizing plate, preferably glued, the surface facing away from the conductor track network arranged electronic components in a recess the stabilizing plate can be used.

The recess is preferably in the stabilizing plate punched, lasered, etched or caused by die casting. A top layer required for good heat dissipation is used as a closed metal layer on the conductor track surface of the plastic layer or the stabilizer facing away from the network Application plate applied, preferably sputtered and if necessary galvanized.

Further advantages and features of the invention are characterized by the Description of the accompanying drawings, in which demonstrate:

Fig. 1 shows the structure of an electronic circuit substrate according to the invention in a first embodiment;

Figure 2 shows the schematic structure of a circuit carrier according to the invention in a second embodiment with a stabilizing plate.

FIG. 2a shows a detailed illustration of the layer structure of a circuit carrier according to the invention in an enlarged area I according to FIG. 2;

Fig. 3 shows a use example of an inventive electronic circuit substrate;

Fig. 4 shows another example of use for an electronic circuit carrier according to the invention with a sensor element; and

Fig. 5 shows an inventive circuit carrier in a third embodiment.

Fig. 1 shows an electronic circuit substrate 1 in which two electronic components in the form of a pressure sensor 2, and a chip 3 can be identified. The electronic components 2 , 3 are glued to a plastic film 4 , a Kapton E-film with a thickness of 50 μm being preferred for the circuit carrier 1 according to the invention. In the areas of electronics components 2 , 3 , a thin layer of adhesive 5 is recognizable.

The plastic film 4 includes a corresponding basket clock 6 of the electronic components 2 , 3 aligned in the thickness direction through recesses 7 , which have a laser-drilled or plasma-etched diameter of about 70 microns.

On the electronics components 2 , 3 facing away from the plastic film 4 is a metallization layer 8 made of TiPd sputtered, this metallization layer 8 both the electronics components 2 , 3 facing away from the plastic film 4 and the walls of the continuous recesses 7 of the plastic Foil 4 occupied and through this, finally, the contacts 6 of the electronic components 2 , 3 are touched. By means of a photostructuring method, a conductor track network 9 formed by the metallization layer 8 is generated, with which each contact 6 is electrically connected to the corresponding conductor track.

In the area of the pressure sensor 2 , an additional opening 11 is provided through which the most direct contact possible between the medium in which the pressure to be determined prevails and the pressure sensor 2 is to be ensured.

For radiation protection and better heat dissipation for the electronic components 2 , 3 , the surface of the plastic film 4 facing the electronic components 2 , 3 and the free surfaces of the electronic components 2 , 3 are surrounded with a cover layer 12 , which is formed from copper by sputtering and is then galvanically reinforced.

In Fig. 2, an inventive electronic scarf device carrier can be seen, the plastic film 4 on a stabilizing plate 13 by means of an adhesive layer 5 BEFE Stigt. This adhesive layer 5 also serves the electric nikkomponenten 3 at which the stabilizer plate 13 facing surface of the plastic film 4 to be attached, wherein the electronic components 3 are in a turned in the thickness direction through recess 14 in the stabilizer plate 13 sets. In the plastic films 4 , the recesses 7 are laser-drilled such that the recesses 7 are aligned with the contacts 6 of the electronic components 3 and the adhesive layer 5 in the region of the contact 6 and the recess 7 are removed by means of laser drilling or plasma etching.

The layer structure in the region of the contact 6 can be clearly seen in FIG. 2a, since this is only indicated schematically in FIG . On the stabilizing plate 13 abge facing surface of the plastic film 4 , an insulation layer 15 is flung. The photostructurable polymer layer made of benzocyclobutene used for the insulation layer 15 covers the plastic film 4 and fills the continuous recesses 7 . In the filled recesses 7 , passages 16 are freely developed in the polymer material by means of photostructuring so that the passage 16 extends into the recess 7 . So that the passage 16 forming polymer material sits as a lining on the side walls of the recess 7th

Ideally, for the sputtering of the metallization layer 8, the passages 16 have a shape that tapers continuously from the rounded edge 17 of the passage 16 (cf. FIG. 2a). In this way, "shadow areas" are avoided, which would otherwise not be accessible from the sputter particles impinging on the device carrier 1 , which could lead to contact interruptions.

The metallization layer 8 is sputtered on the surface of the insulation layer 15 facing away from the plastic film 4 and covers the walls of the passage 16 of the insulation layer 15 . Thus, the electrical contact between the contact 6 of the electronic component 3 and the layer through the metallization 8 in turn formed by a photostructuring method interconnect network 9 is produced.

According to Fig. 2 can be applied to the plastics film 4 opposite surface of the stabilizing plate to be applied to the radiation protection and better heat dissipation, the cover layer 12 13, which is realized by laminating a film.

A stabilizing plate 13 suitable for the electronic circuit carrier according to the invention is formed from Al ₂ O ₃ , green ceramic, glass, LTCC from a copper plate or is produced in particular by an aluminum die casting process.

In Fig. 3 an application example of the electronic circuit carrier 1 according to the invention is shown, in which a sta bilization plate 13 is used. The stabilizing plate 13 has recesses 14 in which only chips 3 are used. These in the recesses 14 of the stabilizing plate 13 electronic components 2 , 3 are attached to the plastic film 4 by means of an adhesive layer 5 and carried by this. The plastic film 4 , as already explained in FIGS . 1 and 2, has recesses 7 for the electrical contact between the conductor network 9 forming the metalization layer 8 ( not shown in FIG. 3) and the contacts of the electronic components 2 To manufacture 3 .

As can also be seen in FIG. 3, electronics components 20 are in the form of SMD components, ICs, passive construction elements, plugs, sensors and the like. The like. Additionally arranged on the metallization layer 8 facing surface of the plastic film 4 .

When using a rigid stabilizing plate 13 , it is particularly advantageous to arrange passive components 21 , such as electrical resistors or capacitors, directly on the plastic layer 4 facing surface of the stabilizing plate 13 , which in turn generates considerable space savings for the circuit carrier 1 become.

To the metallization layer 8 facing side of the stabilizing plate, a housing 22 may at this subsequent SEN, so that an electronics compartment 23 and an outer space 24 is formed.

In order to also hermetically seal the electronics interior 23 from the exterior 24 , the stabilization plate separating them, in particular from the recesses 14 , the plate 13 facing away from the metallization layer 8 of the stabilization plate 13 , the plastic film 4 and the free surfaces of the Plastic film 4 glued electronic components 2 , 3 sputtered on a cover layer 12 made of Cu and the latter optionally galvanically reinforced.

FIG. 4 shows a further example of use which corresponds to that according to FIG. 3 over long distances. Corresponding components are provided with identical reference numerals and therefore do not need to be discussed again. Only the differences are described. Thus, in the application example shown in FIG. 4, in addition to the chips 3 , a pressure sensor 2 is also arranged in a recess 14 , which is intended to determine the pressure of a medium located in the outer space 24 . For direct contact of the medium, an opening 11 is worked into the cover layer 12 in the area of the pressure sensor. Analogously to this, the plastic film 4 is provided with an opening 11 in order to measure the pressure of the medium located in the interior 23 , as a result of which the difference between the pressures prevailing in the interior 23 and exterior 24 can be determined.

In Fig. 5 a third embodiment is shown which corresponds to the FIG. 1 over long distances. Similar components are provided with identical reference numerals and therefore do not need to be explained again. Only the differences are described. Fig. 5 shows the cover layer 12 , which forms on the electronics components 2 , 3 facing surface of the plastic film and on the free surfaces of the electronics components 2 , 3 by sputtering ge and then optionally galvanically reinforced. In order to produce different potentials in the cover layer 12 in the area of the electronic component 3 , an interruption 25 is introduced around the electronic component 3 into the section 26 connecting the electronic components. In this way, a cover layer section 29 is insulated from the remaining cover layer 12 . Via recesses 27 , 28 additionally introduced into the plastic layer 4 , who realizes the connections for the potential supplied by the conductor track network 9 .

A preferred production method for the circuit carrier according to the invention is now explained below. This includes the following process steps:

• - In the stabilizing plate 13 continuous recesses 14 are punched, milled, lasered or etched in the thickness direction, which are slightly larger than the chips 3 or sensors 2 to be inserted into the recesses. A metal plate made of copper should be used for the stabilizing plate 13 .
• - On the processed stabilizing plate 13 , a plastic layer 4 , namely a Kapton E-foil with egg ner thickness of 50 microns, is laminated.
• - In the film, recesses 7 are laser-drilled, which have a diameter of approximately 70 μm and whose positions correspond to those of the contacts 6 of the chips 3 or sensors 2 to be contacted.
• - During this process step, registration marks are also made for the subsequent photostructuring processes set.
• - If necessary, a required openings 11 are introduced into the Kapton E-foil 4 in the area of pressure sensors.
• - The chips 3 or the sensors 2 are glued to the Kapton E-foil 4 in the recesses 14 of the stabilizing plate 13 provided for this purpose. It is important to ensure that the position of the contacts 6 , the chips 3 or sensors 2 are aligned with the recesses 7 in the Kapton E-foil 4 .
• - Then on the stabilizing plate 13 facing away from the Kapton E-foil 4, the photostructuable polymer layer 15 , for. B. Benzocyclobutene, which is manufactured by the DOW company, spun all over.
• - By means of photostructuring in the polymer layer 15 with the recesses 7 in the Kapton E-foil 4 cursing and extending into these passages 16 freely developed, which have a diameter of about 50 microns sen.
• - If necessary, any adhesive residues can be removed using a CF ₄ O ₂ plasma or a laser.
• - On the Kapton E-film 4 facing away from the polymer layer 15 , a metallization layer 8 of the type is sputtered over the entire surface that an electrical contact between the metallization layer 8 and the contacts 6 of the chips 3 or sensors 2 is produced.
• - Then the conductor track network 9 is developed from the metallization layer 8 by means of the photostructuring method.
• - If necessary, additional SMD components, IC's, sensors, connectors, passive components and. Like. Be arranged at the top of the circuit carrier 1 of the invention.
• - On the Kapton E-film 4 facing away from the sta bilization plate 13 , a hermetically sealed, in particular oil-tight, layer 12 of copper is sputtered on and then galvanically reinforced.

In the exemplary embodiment shown in FIG. 5, it is necessary to carry out the production of the cover layer 12 by means of Cu sputtering before the metallization layer 8 is applied and before the recesses 7 or passages 16 are worked in , if a in the area of the electronic component 2 3 sputtered cover layer 12 with different potentials to be applied to individual cover layer sections 29 . For this purpose, an interruption 25 surrounding an electronic component 3 is worked into the cover layer 12 . In the Kapton E-foil 4 recesses 27 , 28 and passages 16 are additionally incorporated in such a way that an electrically conductive connection between the cover layer section 29 insulated by the interruption 25 and the conductor track network 9 is made possible by the subsequent application of the metallization layer 8 .

Claims (22)

1. Electronic circuit carrier ( 1 )

• - with a basic carrier,
• - With arranged on the base support electronics components ( 2 , 3 ), in particular power semiconductors, sensor elements and passive components which have at least one contact ( 6 ), and
• - with a conductor track network ( 9 ),
  characterized in that
• - The base support a plastic layer ( 4 ) with at least at least one continuous recess ( 7 ) which is aligned with a corresponding contact ( 6 ) of the plastic layer ( 4 ) attached electronic component ( 2 , 3 ), and
• - A metallization layer ( 8 ) on the plastic layer ( 4 ) is arranged, which forms the conductor network ( 9 ) and the latter with the at least one contact ( 6 ) of the electronic component ( 2 , 3 ) through the corre sponding recess ( 7 ) electrically connects.

2. Electrical circuit carrier according to claim 1, characterized in that the plastic layer ( 4 ) comprises a plastic film. 3. Electrical circuit carrier according to claim 2, characterized in that the plastic film comprises an additional Lich on the conductor track network ( 9 ) facing surface of the plastic film applied insulation layer ( 15 ) which one in the corresponding recess ( 7 ) Plastic-extending passage ( 16 ) comprises, wherein the metallization layer ( 8 ) forming the interconnect network is arranged on the insulation layer ( 15 ) and through the passage ( 16 ) through the interconnect network ( 9 ) with the at least one contact ( 6 ) the electronic component ( 2 , 3 ). 4. Electrical circuit carrier according to one of claims 1 to 3, characterized in that Elektronikkompo components ( 2 , 3 ) on the conductor network ( 9 ) facing away surface of the plastic layer ( 4 ) are glued. 5. Electrical circuit carrier according to claim 3 or 4, characterized in that electronic components ( 2 , 3 ) are glued to the insulation layer ( 15 ). 6. Electrical circuit carrier according to one of claims 1 to 5, characterized in that the plastic layer ( 4 ) with its the conductor track network ( 9 ) facing surface attached to a stabilizing plate ( 13 ), preferably glued, the at least one on the conductor web ( 9 ) facing away from the plastic layer ( 4 ) arranged electronic component ( 2 , 3 ) is inserted into a preferably continuous recess ( 14 ) in the stabilizing plate ( 13 ). 7. Electrical circuit carrier according to claim 6, characterized in that on the plastic layer ( 4 ) facing surface of the stabilizing plate ( 13 ) further electronic components ( 2 , 3 ), preferably printed resistances and / or integrated capacitors, are applied. 8. Electrical circuit carrier according to one of claims 2 to 7, characterized in that the insulation layer ( 15 ) is formed from a photostructurable polymer layer, preferably from benzocyclobutene. 9. Electrical circuit carrier according to one of claims 1 to 8, characterized in that on the conductor rail network ( 9 ) at least one further conductor network insulation layer combination is applied. 10. Electrical circuit carrier according to one of claims 1 to 9, characterized in that on the Lei terbahnnetz facing surface of the plastic layer ( 4 ) or the stabilizing plate ( 13 ) a tight cover layer ( 12 ) is applied. 11. Electrical circuit carrier according to claim 10, characterized in that when the at least one electronic component ( 2 , 3 ) is designed as a sensor element, the cover layer ( 12 ) has at least one opening ( 11 ) in the region of the sensor element. 12. Electrical circuit carrier according to one of claims 10 or 11, characterized in that the cover layer ( 12 ) through a laminated film, by sputtering egg ner metal layer or by filling in the stabilization plate ( 13 ) arranged recesses ( 14 ) with a Potting compound is formed. 13. Electrical circuit carrier according to one of claims 10 to 12, characterized in that an interruption ( 25 ) in the cover layer ( 12 ) is arranged such that a cover layer portion ( 29 ) in the region of an electronic component ( 2 , 3 ) of the remaining cover layer ( 12 ) is insulated, with at least one recess ( 7 ) in the plastic layer ( 4 ) and optionally additionally at least one passage ( 16 ) in the insulation layer ( 15 ) for electrical contacting of the conductor network ( 9 ) and insulated Cover layer section ( 29 ) are arranged. 14. A method for producing the electrical circuit carrier according to one of claims 1 to 13, characterized in that

• a) at least one continuous recess ( 7 ) is worked into a plastic layer ( 4 ),
• b) electronic components ( 2 , 3 ) are attached to a surface of the plastic layer in such a way that at least one contact ( 6 ) of an electronic component ( 2 , 3 ) is aligned with the corresponding recess ( 7 ),
• c) a metallization layer ( 8 ) on the electronics component ( 2 , 3 ) facing away from the surface of the plastic layer ( 4 ) by establishing an electrical connection between the contact's ( 6 ) of the electronics component ( 2 , 3 ) and the metallization layer ( 8 ) the recess is made through
• d) a conductor track network ( 9 ) is generated by a suitable planarization method for the metallization layer ( 8 ).

15. Manufacturing method according to claim 14, characterized in that the plastic layer ( 4 ) is produced by applying an insulation layer ( 15 ) on a conductor track network ( 9 ) facing surface of a plastic film. 16. Manufacturing method according to one of claims 14 or 15, characterized in that the conductor track network ( 9 ) is produced by a photostructuring method. 17. Manufacturing method according to one of claims 14 to 16, characterized in that the continuous recess ( 7 ) in the plastic layer ( 4 ) is laser drilled or plasma etched. 18. Manufacturing method according to one of claims 15 to 17, characterized in that when working in with the corresponding contact ( 6 ) of the electronic components ( 2 , 3 ) aligned, continuous recess ( 7 ) in the plastic film registration marks for later incorporation of a corresponding passage ( 16 ) of the insulation layer ( 15 ) and for the later photostructuring process. 19. Manufacturing method according to one of claims 14 to 18, characterized in that the metallization layer ( 8 ) on the plastic layer ( 4 ), in particular on the plastic film or insulation layer ( 15 ) is sputtered. 20. Manufacturing method according to one of claims 14 to 19, characterized in that the plastic layer ( 4 ) with its surface facing away from the conductor track network is attached to a stabilizing plate ( 13 ), preferably glued, the surface facing away from the conductor track network ( 9 ) che arranged electronic components ( 2 , 3 ) are each inserted into a recess ( 14 ) in the stabilizing plate ( 13 ). 21. Manufacturing method according to claim 20, characterized in that the recess ( 14 ) in the stabilizing plate ( 13 ) is punched, lasered, etched or caused by pressure casting. 22. Manufacturing method according to one of claims 14 to 21, characterized in that a cover layer ( 12 ) as a closed metal layer on the conductor track network ( 9 ) facing away from the plastic layer ( 4 ) or the stabilizing plate ( 13 ) applied, preferably sputtered and optionally is galvanized.