Method for manufacturing an electronic module and an electronic module
This publication discloses an electronic module and a method for manufacturing an electronic module, in which a component is glued to the surface of a conductive layer, from which conductive layer conductive patterns are later formed. After gluing the component, an insulating-material layer, which surrounds the component attached to the conductive layer, is formed on, or attached to the surface of the conductive layer. After the gluing of the component, feed-throughs are also made, through which electrical contacts can be made between the conductive layer and the contact zones of the component. After this, conductive patterns are made from the conductive layer, to the surface of which the component is glued.
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The present invention relates to an electronic module and a method for manufacturing an electronic module.
In particular, the invention relates to an electronic module, which includes one or more components embedded in an installation base. The electronic module can be a module like a circuit board, which includes several components, which are connected to each other electrically, through conducting structures manufactured in the module. The components can be passive components, microcircuits, semiconductor components, or other similar components. Components that are typically connected to a circuit board form one group of components. Another important group of components are components that are typically packaged for connection to a circuit board. The electronic modules to which the invention relates can, of course, also include other types of components.
The installation base can be of a type similar to the bases that are generally used in the electronics industry as installation bases for electrical components. The task of the base is to provide components with a mechanical attachment base and the necessary electrical connections to both components that are on the base and those that are outside the base. The installation base can be a circuit board, in which case the construction and method to which the invention relates are closely related to the manufacturing technology of circuit boards. The installation base may also be some other base, for example, a base used in the packaging of a component or components, or a base for an entire functional module.
The manufacturing techniques used for circuit boards differ from those used for microcircuits in, among other things, the fact that the installation base in microcircuit manufacturing techniques, i.e. the substrate, is of a semiconductor material, whereas the base material of an installation base for circuit boards is some form of insulating material. The manufacturing techniques for microcircuits are also typically considerably more expensive that the manufacturing techniques for circuit boards.
The constructions and manufacturing techniques for the cases and packages of components, and particularly semiconductor components differ from the construction and manufacture of circuit boards, in that component packaging is primarily intended to form a casing around the component, which will protect the component mechanically and facilitate the handling of the component. On the surface of the component, there are connector parts, typically protrusions, which allow the packaged component to be easily set in the correct position on the circuit board and the desired connections to be made to it. In addition, inside the component case, there are conductors, which connect the connector parts outside the case to connection zones on the surface of the actual component, and through which the component can be connected as desired to its surroundings.
However, component cases manufactured using conventional technology demand a considerable amount of space. As electronic devices have grown smaller, there has been a trend to eliminate component cases, which take up space, are not essential, and create unnecessary costs. Various constructions and methods have been developed to solve this problem.
One known solution is flip-chip (FC) technology, in which non-packaged semiconductor components are installed and connected directly to the surface of the circuit board. However, flip-chip technology has many weaknesses and difficulties. For example, the reliability of the connections can be a problem, especially in applications, in which mechanical stresses arise between the circuit board and the semiconductor component. In an attempt to avoid mechanical stresses, a suitable elastic underfill, which equalizes mechanical stresses, is added between the semiconductor component and the circuit board. This procedural stage slows down the manufacturing process and increases costs. Even the thermal expansion caused by the normal operation of a device may cause mechanical stresses large enough to compromise the long-term reliability of an FC structure.
US patent publication 4 246 595 discloses one solution, in which recesses are formed in the installation base for the components. The bottoms of the recesses are bordered by a two-layered insulation layer, in which holes are made for the connections of the component. The layer of the insulation layer that lies against the components is made of an adhesive. After this, the components are embedded in the recesses with their connection zones facing the bottom of the recess, electrical contacts being formed to the components through the holes in the insulation layer. If it is wished to make the structure mechanically durable, the component must also be attached to an installation base, so that the method is quite complicated. It is extremely difficult to use a complicated method, which demands several different materials and process stages, to profitably manufacture cheap products. In other ways too, the method does not correspond to the technology used nowadays (the patent dates from 1981).
JP application publication 2001-53 447 discloses a second solution, in which a recess is made for the component in an installation base. The component is placed in the recess, with the component's contact zones facing towards the surface of the installation base. Next, an insulation layer is made on the surface of the installation base and over the component. Contact openings for the component are made in the insulation layer and electrical contacts are made to the component, through the contact openings. In this method, considerable accuracy is demanded in manufacturing the recess and setting the component in the recess, so that the component will be correctly positioned, to ensure the success of the feed-throughs, relative to the width and thickness of the installation board.
The invention is intended to create a relatively simple and economical method for manufacturing electronic modules, with the aid of which a mechanically durable construction can be achieved.
The invention is based on the component being glued to the conductive layer, from which conductive layer conductive patterns are later formed. After the gluing of the component, an insulating-material layer, which surrounds the component attached to the conductive layer, is formed on, or attached to the conductive layer. After the gluing of the component, feed-throughs are also made, through which electrical contacts can be formed between the conductive layer and the conductive zones of the component. After this, conductive patterns are formed from the conductive layer, to which the component is glued.
Considerable advantages are gained with the aid of the invention. This because it is possible, with the aid of the invention, to manufacture mechanically durable electronic modules, which include unpackaged components embedded in an installation base.
The invention permits a quite simple manufacturing method, in which relatively few different materials are required. For this reason, the invention has embodiments, with the aid of which electronic modules can be manufactured at low cost. For example, in the technique disclosed in US patent publication 4 246 595, (the references are to FIG. 8 of the patent) a support layer 24, an insulating layer 16, and an adhesion layer 17 are required. In addition, a fourth insulating material (not shown in the embodiment of FIG. 8), i.e. filler with the aid of which the component is attached to the support layer 24, is also required, in order to create a mechanically sturdy attachment. In the solution of the JP application publication 2001-53 447 too, a corresponding attachment that entirely surrounds the component requires about 3-4 separate insulating materials, or insulating layers (publication FIGS. 2 and 4).
Unlike the reference publications, our invention has embodiments, in which the component can be entirely surrounded using 2-3 insulating materials, or insulating layers. This because the contact surface of the component is glued to a conductive layer, so that, in preferred embodiments, the adhesive attaches the component essentially over the entire area of its contact surface. Elsewhere, in such an embodiment, the component is attached with the aid of an insulating-material layer, which acts as the base material for the electronic module being formed. The insulating-material layer is formed after the gluing of the component, so that in preferred embodiments it can be made around the component to conform to the shape of the component. In such embodiments, it is possible to achieve a comprehensive attachment of the component with the aid of an adhesive layer and a base-material layer formed from 1-2 insulating-material sheets.
In the embodiments of the invention, it is thus possible to manufacture a circuit board, inside which components are embedded. The invention also has embodiments, with the aid of which a small and reliable component package can be manufactured around a component, as part of the circuit board. In such an embodiment, the manufacturing process is simpler and cheaper than manufacturing methods in which separate packaged components are installed and connected to the surface of the circuit board. The manufacturing method can also be applied to use the method to manufacture Reel-to-Reel products. Thin and cheap circuit-board products containing components can be made by using the methods according to the preferred embodiments.
The invention also permits many other preferred embodiments, which can be used to obtain significant additional advantages. With the aid of such embodiments, a component's packaging stage, the circuit board's manufacturing stage, and the assembly and connecting stage of the components, for example, can be combined to form a single totality. The combination of the separate process stages brings significant logistical advantages and permits the manufacture of small and reliable electronic modules. A further additional advantage is that such an electronic-module manufacturing method can mostly utilize known circuit-board manufacturing and assembly techniques.
The present invention discloses also several novel electronic module structures that prevent efficiently warpage within the electronic modules containing at least one embedded component inside an installation base. Warpage may occur after manufacturing of electronic modules containing embedded components normally before dicing phase when the electronic modules are in panel or strip level. Warpage may affect huge losses in yields of manufacturing electronic modules. Warpage occurs especially in panel level when huge semiconductor components, high amount of silicon components, microcircuit chips or other silicon based chips; in other words: the silicon area density is on high level; are embedded in an electronic module. Warpage of electronic modules, strips and panels containing embedded components is a result of different coefficients of thermal expansion (CTE) of different materials used within the electronic modules. Namely, the silicon based components have usually lower CTE than any other materials typically used in PCB and packaging industry, and especially different insulation materials, used within electronic modules containing embedded components. Furthermore, the totally cured (c-stage) resin, i.e. laminate layer hardly shrinks when heat and pressure is conducted to it.
According to the embodiments of the invention presented below, warpage can be prevented within the electronic modules, strips and panels when there are high silicon area density, i.e. huge embedded electronic components or high amount of silicon components.
In a preferred embodiment of the invention the comprises one relatively thick lamination layer (c-stage). The lamination layer has a prefabricated hole for a component to be embedded. The lamination layer is fastened with aid of a thin bonding sheet or thin resin layer to the conductor layer. The embedding of the component will be implemented by laminating a RCC foil or a b-stage resin layer at the back side of the component. In another embodiment a separate filler material can be used in embedding the component.
The invention provides several advantages. When using relatively thick lamination layer internal strains can be effectively reduced and thus warpage is controlled. The adequate amount of resin for embedding the component is guaranteed by using a b-stage layer, RCC foil or other like precured or uncured layer.
Embodiments that use bonding resin sheets instead of prepregs provide even further advantages over the solutions utilizing prepregs. A CTE of a bonding resin sheet that ties the laminate and conductor layer together can be chosen lower than that of a typical prepreg layer. Furthermore, the bonding resin sheet is typically thinner than a prepreg layer. There are also the following advantages when using a bonding resin sheet. The thinner the bonding resin sheet the thinner the complete electronic module. Further, even if the shrinkage of the material is the same, the strain will be lower due to decreased amount of used b-stage materials. The shrinkage refers to a phenomenon in which materials shrink during the manufacturing process due to other reasons than thermal expansion. Contraction of a material occurs mainly due to polymer curing during the high temperature processes. The lamination layer keeps its dimensions better than a prepreg layer. This provides for the holes for the components to be embedded being even of smaller size and more accurate in positioning than with the prepregs. This also increases silicon area density.
In some embodiments two or several separate lamination layers can be used. In these embodiments the lamination layers can be tied together with the bonding resin sheets, prepreg layers or other similar respective layers.
The composite process according to the embodiment referred to above is, as a totality, simpler than manufacturing a circuit board and attaching a component to the circuit board using, for example, the flip-chip technique. By using such preferred embodiments, the following advantages are obtained, compared to other manufacturing methods:
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- Soldering is not needed in the connections of the components, instead an electrical connection between the connection zones on the surface of the component and the metal film of the installation base is created by a via-method. This means that the connection of a component does not need metal being maintained molten for a long time with its associated high temperature. Thus, the construction is made more reliable than soldered connections. The brittleness of the metal alloys creates large problems particularly in small connections. In a solderless solution according to a preferred embodiment, it is possible to achieve clearly smaller constructions than in soldered solutions.
- As smaller structures can be manufactured using the method, the components can be placed closer together. Thus, the conductors between the components also become shorter and the characteristics of the electronic circuits improve. For example, losses, interferences, and transit-time delays can be significantly reduced.
- The method permits a lead-free manufacturing process, which is environmentally friendly.
- When using a solderless manufacturing process, fewer undesirable intermetallics also arise, thus improving the long-term reliability of the construction.
- The method also permits three-dimensional structures to be manufactured, as the installation bases and the components embedded in them can be stacked on top of each other.
The invention also permits other preferred embodiments. For instance, flexible circuit boards can be used in connection with the invention. Further, in embodiments, in which the temperature of the installation base can be kept low during the entire process, organic manufacturing materials can be used comprehensively.
With the aid of embodiments, it is also possible to manufacture extremely thin structures, in which, despite the thinness of the structure, the components are entirely protected inside their installation base, such as a circuit board.
In embodiments, in which the components are located entirely inside the installation base, the connections between the circuit board and the components will be mechanically durable and reliable.
The embodiments also permit the design of electronic-module manufacturing processes requiring relatively few process stages. Embodiments with fewer process stages correspondingly also require fewer process devices and various manufacturing methods. With the aid of such embodiments, it is also possible in many cases to cut manufacturing costs compared to more complicated processes.
The number of conductive-pattern layers of the electronic module can also be chosen according to the embodiment. For example, there can be one or two conductive-pattern layers. Additional conductive-pattern layers can be manufactured on top of these, in the manner known in the circuit-board industry. A total module can thus incorporate, for example, three, four, or five conductive-pattern layers. The very simplest embodiments have only one conductive-pattern layer and indeed one conductor layer. In some embodiments, each of the conductor layers contained in the electronic module can be exploited when forming conductive patterns.
In embodiments, in which the conductor layer connected to a component is patterned only after the connection of the component, the conductor layer can include conductor patterns even at the location of the component. A corresponding advantage can also be achieved in embodiments, in which the electronic module is equipped with a second conductive-pattern layer, which is located on the opposite surface of the base material of the module (on the opposite surface of the insulation material layer relative to the conductive-pattern layer connected to the component). The second conductor layer can thus also include conductive patterns at the location of the component. The placing of conductive patterns in the conductor layers at the location of the component will permit a more efficient use of space in the module and a denser structure.
In the following, the invention is examined with the aid of examples and with reference to the accompanying drawings.
In the methods of the examples, manufacturing starts from a conductive layer 4, which can be, for example, a metal layer. One suitable manufacturing material for the conductive layer 4 is copper film (Cu). If the conductive film 4 selected for the process is very thin, or the conductive film is not mechanically durable for other reasons, it is recommended that the conductive film 4 be supported with the aid of a support layer 12. This procedure can be used, for example, in such a way that the process is started from the manufacture of the support layer 12. This support layer 12 can be, for example, an electrically conductive material, such as aluminium (Al), steel, or copper, or an insulating material, such as a polymer. An unpatterned conductive layer 4 can be made on the second surface of the support layer 12, for example, by using some manufacturing method well known in the circuit-board industry. The conductive layer can be manufactured, for example, by laminating a copper film (Cu) on the surface of the support layer 12. Alternatively, it is possible to proceed by making the support layer 12 on the surface of the conductive layer 4. The conductive film 4 can also be a surfaced metal film, or some other film including several layers, or several materials.
Later in the process, conductive patterns are made from the conductive layer 4. The conductive patterns must then be aligned relative to the components 6. The alignment is most easily performed with the aid of suitable alignment marks, at least some of which can be made already in this stage of the process. Several different methods are available for creating the actual alignment marks. One possible method is to make small through-holes 3 in the conductive layer 4, in the vicinity of the installation areas of the components 6. The same through-holes 3 can also be used to align the components 6 and the insulating-material layer 1. There should preferably be at least two through-holes 3, for the alignment to be carried out accurately.
The components 6 are attached to the surface of the conductive layer 4 with the aid of an adhesive. For gluing, an adhesive layer 5 is spread on the attachment surface of the conductive layer 4, or on the attachment surface of the component 6, or on both. After this, the components 6 can be aligned to the positions planned for the components 6, with the aid of alignment holes 3, or other alignment marks. Alternatively, it is possible to proceed by first gluing the components to the conductive layer 4, positioned relative to each other, and after this making the alignment marks aligned relative to the components. The term attachment surface of the component 6 refers to that surface, which faces the conductive layer 4. The attachment surface of the component 6 includes the contact zones, by means of which an electrical contact can be formed with the component. Thus, the contact zones can be, for example, flat areas on the surface of the component 6, or more usually contact protrusions protruding from the surface of the component 6. There are generally at least two contact zones or protrusions in the component 6. In complex microcircuits, there can be a greater number of contact zones.
In many embodiments, it is preferable to spread so much adhesive on the attachment surface, or attachment surfaces, that the adhesive entirely fills the space remaining between the components 6 and the conductive layer 4. A separate filler is then not required. The filling of the space between the components 6 and the conductive layer 4 reinforces the mechanical connection between the component 6 and the conductive layer 4, thus achieving a structure that is mechanically more durable. The comprehensive and unbroken adhesive layer also supports the conductive patterns 14 to be formed later from the conducting layer 4 and protects the structure during later process stages.
The term adhesive refers to a material, by means of which the components can be attached to the conductive layer. One property of the adhesive is that the adhesive can be spread on the surface of the conductive layer, and/or of the component in a relatively fluid form, or otherwise in a form that will conform to the shape of the surface. Another property of the adhesive is that, after spreading, the adhesive hardens, or can be hardened, at least partly, so that the adhesive will be able to hold the component in place (relative to the conductive layer), at least until the component is secured to the structure in some other manner. A third property of the adhesive is its adhesive ability, i.e. its ability to stick to the surface being glued.
The term gluing refers to the attachment of the component and conductive layer to each other with the aid of an adhesive. Thus, in gluing, an adhesive is brought between the component and the conductive layer and the component is placed in a suitable position relative to the conductive layer, in which the adhesive is in contact with the component and the conductive layer and at least partly fills the space between the component and the conductive layer. After this, the adhesive is allowed (at least partly) to harden, or the adhesive is actively hardened (at least partly), so that the component sticks to the conductive layer with the aid of the adhesive. In some embodiments, the contact protrusions of the component may, during gluing, extend through the adhesive layer to make contact with the conductive layer.
The adhesive used in the embodiments is typically a thermally hardening epoxy, for example an NCA (non-conductive adhesive). The adhesive is selected to ensure that the adhesive used will have sufficient adhesion to the conductive film, the circuit board, and the component. One preferred property of the adhesive is a suitable coefficient of thermal expansion, so that the thermal expansion of the adhesive will not differ too greatly from the thermal expansion of the surrounding material during the process. The adhesive selected should also preferably have a short hardening time, preferably of a few seconds at most. Within this time, the adhesive should harden at least partly, to such an extent that the adhesive is able to hold the component in position. Final hardening can take clearly more time and the final hardening can be planned to take place in connection with later process stages. The adhesive should also withstand the process temperatures used, for example, heating to a temperature in the range 100-265° C. a few times, and other stresses in the manufacturing process, for example, chemical and mechanical stress. The electrical conductivity of the adhesive is preferably in the same order as that of the insulating materials.
A suitable insulating-material layer 1 is selected as the base material of the electronic module, for example, the circuit board. Using a suitable method, recesses, or through-holes are made in the insulating-material layer 1, according to the size and mutual positions of the components 6 to be attached to the conductive layer 4. The recesses or through-holes can also be made to be slightly larger than the components 6, in which case the alignment of the insulating layer 1 relative to the conductive layer 4 will not be so critical. If an insulating-material layer 1, in which through-holes are made for the components 6, is used in the process, certain advantages can be achieved by using, in addition, a separate insulating-material layer 11, in which holes are not made. Such an insulating-material layer 11 can be located on top of the insulating-material layer 1 to cover the through-holes made for the components.
According to another embodiment of the invention insulating-material layer 1, also called core layer in some later embodiments, comprises a core sheet or several core sheets and a bonding layer. The core sheet is typically rigid material which does not change (or changes very little) compared to other materials in a panel, strip, block and even module level during the manufacturing phases. The bonding layer runs at least on the longitudinal surface of the core sheet and is faced towards the conductive layer 4. If several core sheets are used they can be bonded together with respective amount of bonding layers. The function of the core sheet is to keep the panel, strip, block and module as stable as possible during the manufacture. Thus the core layer has relatively low CTE in X-Y direction and low shrinkage during the final pressing or lamination process. The function of the bonding layer is to bond securely the core layer to the conductive layer 4. A separate insulating-material layer 11 may contain filling material that fills the space of a cavity formed through the core layer or the core sheet for a component to be embedded inside the panel, strip, block and module. The separate insulating-material layer 11, also called a filling layer may also contain a second conductive layer 9 on top of the filling layer. The function of the filling layer is to embed the component inside an insulation material with aid of sufficient amount of filler material. The filler material may be activated by heat and pressure or by printing or spreading the filler material inside a cavity.
If it is desired to make a second conductive layer in the electronic module, this can be made, for example, on the surface of the insulating-material layer 1. In embodiments, in which a second conductive layer 9 is used, the conductive layer can be made on the surface of this second conductive layer 9. If desired, conductive patterns 19 can be made from a second conductive layer 9. The conductive layer 9 can be made, for example, in a corresponding manner to the conductive film 4. The manufacture of a second conductive film 9 is not, however, necessary in simple embodiments and when manufacturing simple electronic modules. A second conductive film 9 can, however, be exploited in many ways, such as additional space for conductive patterns and to protect the components 6 and the entire module against electromagnetic radiation (EMC shielding). With the aid of a second conductive film 9 the structure can be reinforced and warping of the installation base, for example, can be reduced.
Feed-throughs, through which electrical contacts can be formed between the contact zones of the components 6 and the conductive layer 4, are made in the electronic module. Holes 17 are made in the conductive layer 4 for the feed-throughs, at the positions of the contact zones (in the figures, the contact protrusions 7) of the components 6. Holes 3, or other available alignment marks can be utilized in the alignment. The holes 17 are made in such a way that they also penetrate through the adhesive layer that has been left on top of the contact zones, or contact protrusions 7. The holes 17 thus extend to the material of the contact protrusions 7 or other contact zones. The holes 17 can be made, for example, by drilling with a laser device, or by using some other suitable method. After this, conductive material is introduced to the hole 17, so that an electrical contact is formed between the components 6 and the conductive layer 4.
The manufacturing processes according to the examples can be implemented using manufacturing methods, which are generally known to those versed in the art of manufacturing circuit boards.
In the following, the stages of the method shown in
Stage A (
In stage A, a suitable conductive layer 4 is selected as the initial material of the process. A layered sheet, in which the conductive layer 4 is located on the surface of a support base 12, can also be selected as the initial material. The layered sheet can be manufactured, for example, in such a way that a suitable support base 12 is taken for processing, and a suitable conductive film for forming the conductive layer 4 is attached to the surface of this support base 12.
The support base 12 can be made of, for example, an electrically conductive material, such as aluminium (Al), or an insulating material, such as polymer. The conductive layer 4 can be formed, for example, by attaching a thin metal film to the second surface of the support base 12, for example, by laminating it from copper (Cu). The metal film can be attached to the support base, for example, using an adhesive layer, which is spread on the surface of the support base 12 or metal film prior to the lamination of the metal layer. At this stage, there need not be any patterns in the metal film.
In the example of
Stage A can also be performed in the same way in embodiments in which a self-supporting conductive layer 4 is used and from which thus totally lacks a support layer 12.
Stage B (
In stage B, an adhesive layer 5 is spread on those areas of the conductive layer 4, to which the components 6 will be attached. These areas can be termed attachment areas. The adhesive layers 5 can be aligned, for example, with the aid of the through-holes 3. The thickness of the adhesive layer is selected so that the adhesive suitably fills the space between the component 6 and the conductive layer 4, when the component 6 is pressed onto the adhesive layer 5. If the component 6 includes contact protrusions 7, it would be good for the thickness of the adhesive layer 5 to be greater, for example about 1.5-10 times, the height of the contact protrusions 7, so that the space between the component 6 and the conductive layer 4 will be properly filled. The surface area of the adhesive layer 5 formed for the component 6 can also be slightly larger than the corresponding surface area of the component 6, which will also help to avoid the risk of inadequate filling.
Stage B can be modified in such a way that the adhesive layer 5 is spread on the attachment surfaces of the components 6, instead of on the attachment areas of the conductive layer 4. This can be carried out, for example, by dipping the component in adhesive, prior to setting it in place in electronic module. It is also possible to proceed by spreading the adhesive on both the attachment areas of the conductive layer 4 and on the attachment surfaces of the components 6.
The adhesive being used is thus a electrical insulator, so that electrical contacts are not formed in the actual adhesive layer 5, between the contact zones (contact protrusions 7 in the example) of the component 6.
Stage C (
In stage C, the component 6 is set in place in the electronic module. This can be done, for example, by pressing the components 6 into the adhesive layer 5, with the aid of an assembly machine. In the assembly stage, the through-holes 3 made for alignment, or other available alignment marks, are used to align the components 6.
The components 6 can be glued individually, or in suitable groups. The typical procedure is for the conductive layer, which can be termed the bottom of the installation base, to be brought to a suitable position relative to the assembly machine, and after this the component 6 is aligned and pressed onto the bottom of the installation base, which is held stationary during the aligning and attaching.
After this phase the manufactured intermediate part is called as a base layer 50.
Stage D (
In stage D, an insulating-material layer 1, in which there are pre-formed recesses 2 or recesses for the components 6 to be glued to the conductive layer 4, is placed on top of the conductive layer 4. The insulating-material layer 1 can be made from a suitable polymer base, in which recesses or cavities according to the size and position of the components 6 are made using some suitable method. The polymer made can be, for example, a pre-preg base known and widely used in the circuit-board industry, which is made from a glass-fibre mat and so-called b-state epoxy. It is best to perform stage D only once the adhesive layer 5 has been hardened, or it has otherwise hardened sufficiently for the components 6 to remain in place during the placing of the insulating-material layer 1.
When manufacturing a very simple electronic module, the insulating-material layer 1 can be attached to the conductive layer 4 in connection with stage D and the process continued with the patterning of the conductive layer 4.
Stage E (
In stage E, an unpatterned insulating-material layer 11 is placed on top of the insulating-material layer 1 and on top of it a conductive layer 9. Like the insulating-material layer 1, the insulating-material layer 11 can be made from a suitable polymer film, for example, the aforesaid pre-preg base. The conductive layer 9 can, in turn, be, for example, a copper film, or some other film suitable for the purpose.
Stage F (
In stage F, the layers 1, 11, and 9 are pressed with the aid of heat and pressure in such a way that the polymer (in the layers 1 and 11) forms a unified and tight layer between the conductive layer 4 and 9 around the components 6. The use of this procedure makes the second conductive layer 9 quite smooth and even.
When manufacturing simple electronic modules and those including a single conductive-pattern layer 14, stage E can even be totally omitted, or the layers 1 and 11 can be laminated to the construction, without a conductive layer 9.
Stage G (
In stage G, the support base 12 is detached or otherwise removed from the construction. Removal can take place, for example, mechanically or by etching. Stage G can naturally be omitted from embodiments that do not employ a support base 12.
Stage H (
In stage H, holes 17 are made for the feed-throughs. The holes 17 are made through the conductive layer 4 and the adhesive layer 5, in such a way that the material of the contact protrusions 7, or other contact zones of the components 6 is exposed. The holes 17 can be made, for example, by drilling with a laser. The holes 17 can be aligned, for example, with the aid of holes 3.
Stage I (
In stage I, conductive material 18 is grown into the holes 17 made in stage H. In the example process, the conductive material is grown at the same time also elsewhere on top of the base, so that the thickness of the conductive layers 4 and 9 also increases.
The conductive material 18 being grown can be, for example, copper, or some other sufficiently electrically conductive material. The choice of conductive material 18 should take into account the ability of the material to form an electrical contact with the contact protrusions 7 of the component 6. In one example process, the conductive material is mainly copper. Copper-metallizing can be performed by surfacing the holes 17 with a thin layer of chemical copper and then continuing the surfacing using an electrochemical copper-growing method. Chemical copper is used, for example, because it also forms a surface on top of the adhesive and acts as an electrical conductor in electrochemical surfacing. The growth of the metal can thus be performed using a wet-chemical method, in which case the growing will be cheap.
In the example process, the holes 17 of the feed-throughs are first cleaned using a three-stage desmear treatment. After this, the feed-throughs are metallized in such a way that an SnPd coating catalysing the polymer is first formed, after which a thin layer (about 2 μm) is deposited on the surface. The thickness of the copper is increased using electrochemical deposition.
Stage I is intended to form an electrical contact between the component 6 and the conductive layer 4. In stage I, it is therefore not essential to increase the thickness of the conductive layers 4 and 9, instead the process can equally well be planned in such a way that in stage I the holes 17 are only filled with a suitable material. The conductive layer 18 can be made, for example, by filling the holes 17 with an electrically conductive paste, or by using some other metallizing method suitable for micro-vias.
In the later figures, the conductive layer 18 is shown with the conductive layers 4 and 9 merged.
Stage J (
In stage J, the desired conductive patterns 14 and 19 are formed from the conductive layers 4 and 9 on the surface of the base. If only a single conductive layer 4 is used in the embodiment, the patterns are formed on only one side of the base. It is also possible to proceed in such a way that the conductive patterns are only formed from the conductive layer 4, even though a second layer 9 is also used in the embodiment. In such an embodiment, the unpatterned conductive layer 9 can act, for example, as a mechanically supporting or protective layer of the electronic module, or as a protection against electromagnetic radiation.
The conductive patterns 14 can be made, for instance, by removing the conductive material of the conductive layer 4 from outside of the conductive patterns. The conductive material can be removed, for example, using one of the patterning and etching methods that are widely used and well known in the circuit-board industry.
After stage J, the electronic module includes a component 6, or several components 6 and conductive patterns 14 and 19 (in some embodiments only conductive patterns 14), with the aid of which the component or components 6 can be connected to an external circuit, or to each other. The conditions for manufacturing a functional totality then exist already. The process can thus be designed in such a way that the electronic module is already finished after stage J and
On the basis of the example of
The sub-modules (bases 1 with their components 6 and conductors 14 and 19) of a multi-layered electronic module can be manufactured, for example, using one of the electronic-module manufacturing methods described above. Some of the sub-modules to be connection to the layered construction can, of course, be quite as easily manufactured using some other method suitable for the purpose.
After the base layer 50 (
The following embodiments describe the structural examples of warpage controlled electronic modules 100.
According to an embodiment of the invention, the insulating-material layer 1 or the core layer 60 (in later embodiments), comprises core sheet 62 and a bonding layer 64 at least on the longitudinal surface of the core sheet 62 towards the conductive layer 4 or the thin insulation layer 56.
The function of the core sheet 62 is to keep the electronic module 100 as stable as possible during the manufacture. Thus the core sheet 62 has relatively low CTE. The core sheet 62 may be for example totally cured epoxy sheet or sheets also called as c-stage epoxy. Also other materials can be used such as typical PCB laminate e.g. FR-2, FR-3, FR-4, FR-5, BT, Aramid or other reinforced polymer sheet or other suitable material. The core sheet 62 can be manufactured from one, two or several prepreg layers with aid of heat and pressure. A desired and very precise thickness can be easily achieved by knowing the thickness and CTE values of prepreg layers and used heat and pressure during the manufacture phase, i.e. curing treatment. The thickness of a core sheet 62 may vary between 30 to 600 micrometers. Furthermore, the core sheet 62 may comprise several separate core sheets or layers. The core sheet 62 can also be a prefabricated single or multilayer PCB.
The function of the bonding layer 64 is to bond securely the core sheet 62 to the base layer 50. The bonding layer 64 may be for example a thin layer of insulation material that also contains good adhesive properties, e.g. ABF (Ajinomoto Build-up film), Adflema (Namics bonding film) or other typically epoxy based bonding film. The thickness of a bonding layer 64 may vary between 3 to 60 micrometers, preferably between 15 to 30 micrometers. The bonding layer 64 can be laminated over the rigid core sheet by vacuum treatment, for example.
Yet in another embodiment the bonding layer 64 may contain high CTE material to control and compensate warpage in an electronic module 100. The elastic bonding film 64 is laminated over the base layer 50 after the cavity manufacturing and before installation of a core sheet 62. In this example the high CTE bonding film will cover also the component to be embedded.
In a preferred embodiment thickness of the core layer 60 can be chosen such that the core layer 60 is as thick as the component 6 to be embedded, or slightly thicker. These dimensions guarantee that in any circumstance the component 6 to be embedded will not be damaged, for example during pressing phase. The thickness of the core layer 60 may also be thinner than the component to be embedded. This is very useful embodiment when the backside of the component will be left open. Such embodiments are for example MEMS, efficient heat conducting, or other like purposes.
After that, the holes 66 for components 6 to be embedded are formed through the core layer 60. In a preferred embodiment of the invention, the holes 66 are slightly larger than the components 6, for example the holes 66 may be 150 micrometers larger per side than the components 6 to be embedded.
According to an embodiment of the invention a separate insulating-material layer 11, which is called a filling layer 70 in later embodiments, contains filling material 72 that fills the hole 66 earlier formed through the lamination layer 60 for a component 6 to be embedded inside the electronic module 100. The filling layer 70 may also contain a second conductive layer 9 on top of the filling material 72. The second conductive layer 9 may be similar than the conductive layer 4 of the base layer 50. The function of the filling layer 70 is to embed the component 6 inside an insulation material with aid of sufficient amount of filler material 72. The filler material 72 may be activated by heat and pressure or by printing or spreading the filler material inside the cavity. Suitable filling layer 70 is resin coated carrier (RCC) for example. For embodiments printing or spreading the filler material into the hole 66 a high CTE resin is recommended to be used.
The figure series 12 presents an example of panel, strip, block and module level items according to an embodiment of the invention.
The figure series 13-19 present several embodiments of manufacturing warpage controlled electronic modules containing an embedded component.
Warpage as a phenomenon occurs also in larger level than within an individual electronic module. Furthermore, warpage can be detected especially after the heat and pressure treatment within a manufacturing process of electronic modules. At this intermediate phase of manufacture, electronic products can be for example in blocks, strips or panels of which each contains tens, hundreds or even thousands of electronics modules.
The manufacturing process comprises several manufacturing process steps which are done in different process temperatures. During the manufacturing process different materials are adhering to each other in different temperatures and in different process phases. Due to the CTE mismatch and differences in adhering temperatures the zero stress temperature of different material interfaces or layers varies and due to that also the residual stress in different material interfaces or layers varies and might cause warpage in e.g. operating temperature. The zero stress temperature is a temperature where the materials are adhered to each other and the stress caused by the CTE mismatch is minimal. This temperature can be different for different interfaces and layers if the adhering has occurred during different process phase or temperatures.
In some embodiments component thickness can be freely adjusted during component preparation process steps (wafer grinding and thinning) It should be noted that thickness of some component (e.g. discrete passives) is fixed by the component manufacturer and due to that might define the minimum thickness of the final module. In preferred embodiments the thickness of the thickest component determines the minimum core thickness because of the miniaturization requirements. In certain embodiments some of the embedded components may be thinner than the core sheet. In the latter case the Z-direction of the thinner components can be adjusted in desired manner by achieving improved product warpage.
For example, the adhesive layer 5 within the base layer 50 is totally cured when the final pressing and heating is started during the phase according to
As has been described above, an embodiment provides an electronic module comprising:
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- an insulating layer having a first surface and a second surface, said insulating layer comprising at least one core sheet having at least one hole;
- a first conductive-pattern layer arranged on the first surface of the insulating layer;
- at least one bonding layer between the at least one core sheet and the first conductive-pattern layer, said at least one bonding layer forming part of the insulating layer;
- at least one component within the insulating layer, said component having contact zones arranged towards the first conductive layer and wherein at least a portion of the component is located within the at least one hole;
- a hardened adhesive layer between the component and the first conductive-pattern layer, said hardened adhesive layer forming part of the insulating layer; and
- a plurality of feedthroughs penetrating the hardened adhesive layer and forming electrical contacts between the first conductive-pattern layer and the contact zones of the component.
The at least one hole in the core sheet can suitably located such that the component can be located in the hole. Then, the core sheet can be of rigid material.
In one embodiment, the at least one core sheet is centered between the first surface and the second surface. This means that the distance from the core sheet to the first surface is generally equal to the distance from the core sheet to the second surface.
In another embodiment, the at least one component is centered between the first surface and the second surface. This means that the distance from the core sheet to the first surface is generally equal to the distance from the core sheet to the second surface.
In a further embodiment, the at least one core sheet and the at least one component are both centered between the first surface and the second surface.
There are also embodiments, wherein the at least one core sheet is placed in a non-centered position between the first surface and the second surface.
A further embodiment is such that the at least one component is placed in a non-centered position between the first surface and the second surface.
It is also possible that the at least one core sheet and the at least one component are both placed in a non-centered position between the first surface and the second surface. In such an embodiment, the non-centered position of the core sheet can be selected such as to compensate for the non-centered position of the component, or vice versa.
In an embodiment, the insulating layer further comprises filler material at least in said hole.
In an embodiment, the at least one core sheet has a first coefficient of thermal expansion, the at least one component has a second coefficient of thermal expansion lower than the first coefficient of thermal expansion and the filler material has a third coefficient of thermal expansion higher than the first coefficient of thermal expansion.
In a further embodiment, the third coefficient of thermal expansion is at least two times higher than the first coefficient of thermal expansion.
In a further embodiment, the first coefficient of thermal expansion is between 8 and 30, the second coefficient of thermal expansion is between 3 and 15, and the third coefficient of thermal expansion is between 50 and 150.
In an embodiment, the module further comprised a second conductive-pattern layer arranged on the second surface of the insulating layer and at least one bonding layer between the at least one core sheet and the second conductive-pattern layer.
In a further embodiment, there is filler material present between the component and the second conductive-pattern layer.
In a further embodiment, there is filler material present between the at least one core sheet and the second conductive-pattern layer.
According to one embodiment, the filler material present between the component and the second conductive-pattern layer and the filler material present between the at least one core sheet and the second conductive-pattern layer are same materials than the filler material, which is present in said hole in the core sheet. In another embodiment, all the filler materials are different materials. Also any other combination is possible, e.g. that two of the filler materials are of the same material and one is of a different material. Of course, also any of the filler materials can also be omitted.
In an embodiment, the insulating layer further comprises an additional insulation layer, which is present between the hardened adhesive layer and the first conductive-pattern layer as well as between the at least one core sheet and the first conductive-pattern layer.
In an embodiment, the electronic module further comprised
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- a second insulating layer arranged over the first conductive-pattern layer on the first surface of the insulating layer; and
- a third conductive-pattern layer arranged on the second insulating layer.
In an embodiment, the electronic module has an operating temperature range and the insulating layer further comprises:
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- a first amount of insulating material between the core sheet and the first surface, said first amount of insulating material having sufficient first properties such that it is capable of inducing a first strain due to thermal expansion and shrinkage;
- a second amount of insulating material between the core sheet and the second surface, said second amount of insulating material having sufficient second properties such that it is capable of inducing a second strain due to thermal expansion and shrinkage substantially equal to the first strain at least within the operating temperature range.
In an embodiment:
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- the insulating layer has third properties within the area wherein the insulating layer comprises said at least one core sheet, said third properties being capable of inducing a third strain due to at least thermal expansion and shrinkage;
- the component has fourth properties capable of inducing a fourth strain due to at least thermal expansion;
- the insulating layer comprises a volume of filler material having fifth properties capable of inducing a fifth strain due to at least thermal expansion and shrinkage;
- wherein the third strain, fourth strain and fifth strain substantially compensate each other.
In an embodiment, the at least one core sheet is a rigid sheet of substantially cured epoxy with glass-fibre reinforcement. In this embodiment, it is good to have said at least one hole made in the glass-fibre reinforcement so that the glass-fibre reinforcement will not be laminated against the surface of the component.
In an embodiment, the at least one bonding layer has at least one hole such that said at least one bonding layer is not present between the component and the first conductive-pattern layer.
In an embodiment:
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- the at least one component is capable of inducing a fourth strain due to at least thermal expansion;
- the insulating layer comprises materials and interfaces between the materials as well as an interface with the at least one component, said materials and interfaces capable of inducing a sixth strain due to at least thermal expansions and shrinkages of the materials; and
- the at least one component is placed in one of a centered position or a non-centered position between the first surface and the second surface such that the fourth strain is capable of at least partially compensating the effect of the sixth strain.
According to another embodiment, there is provided an electronic module comprising:
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- an insulating layer having a first surface and a second surface, said insulating layer comprising at least one core sheet, said at least one core sheet containing at least one glass-fibre mat and having at least one hole in said at least one glass-fibre mat;
- at least one component within the insulating layer, said component having contact zones arranged towards the first surface and wherein at least a portion of the component is located within said at least one hole;
- a first conductive-pattern layer arranged on the first surface of the insulating layer;
- attachment areas between each of said at least one component and said first conductive-pattern layer;
- a hardened adhesive layer substantially within the attachment areas, said hardened adhesive layer forming part of the insulating layer; and
- a plurality of feedthroughs penetrating the hardened adhesive layer and forming electrical contacts between the first conductive-pattern layer and at least a plurality of the contact zones of said at least one component.
In an embodiment, such an electronic module is such that:
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- the first surface has a first surface area;
- the hardened adhesive layer has a second surface area substantially parallel with the first surface, said second surface area being smaller than the first surface area; and
- the at least one component has a third surface area substantially parallel with the first surface said third surface area being smaller than the second surface area.
In an embodiment, the electronic module comprised at least one bonding layer between the at least one core sheet and the first conductive-pattern layer outside the attachment areas, said at least one bonding layer forming part of the insulating layer.
In an embodiment, the at least one bonding layer has a fourth surface area substantially parallel with the first surface such that the sum of said fourth surface area and said second surface area is substantially equal to said first surface area.
According to a further embodiment, there is provided an electronic module comprising:
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- an insulating layer having a first surface and a second surface, said insulating layer comprising at least one core sheet, said at least one core sheet containing at least one glass-fibre mat and having at least one hole in said at least one glass-fibre mat;
- at least one component within the insulating layer, said component having contact zones arranged towards the first surface and wherein at least a portion of the component is located within said at least one hole;
- a first conductive-pattern layer arranged on the first surface of the insulating layer;
- attachment areas between each of said at least one component and said first conductive-pattern layer;
- at least one bonding layer between the at least one core sheet and the first conductive-pattern layer outside the attachment areas, said at least one bonding layer forming part of the insulating layer;
- a hardened adhesive layer substantially within the attachment areas, said hardened adhesive layer forming part of the insulating layer; and
- a plurality of feedthroughs penetrating the hardened adhesive layer and forming electrical contacts between the first conductive-pattern layer and at least a plurality of the contact zones of said at least one component;
- wherein the at least one core sheet has a first coefficient of thermal expansion, the component has a second coefficient of thermal expansion lower than the first coefficient of thermal expansion and the filler material has a third coefficient of thermal expansion higher than the first coefficient of thermal expansion.
The examples and embodiments presented above and in the Figures show some possible processes, with the aid of which our invention can be exploited. Our invention is not, however, restricted to only the processes disclosed above, but instead the invention also encompasses various other processes and their end products, taking into account the full scope of the Claims and the interpretation of their equivalences. The invention is also not restricted to only the constructions and method described by the examples, it being instead obvious to one versed in the art that various applications of our invention can be used to manufacture a wide range of different electronic modules and circuit boards, which differ greatly from the examples described above. Thus, the components and wiring of the figures are shown only with the intention of illustrating the manufacturing process. Thus many alterations to and deviations from the processes of the examples shown above can be made, while nevertheless remaining within the basic idea according to the invention. The alterations can relate, for example, to the manufacturing techniques described in the different stages, or to the mutual sequence of the process stages.
With the aid of the method, it is also possible to manufacture component packages for connection to a circuit board. Such packages can also include several components that are connected electrically to each other.
The method can also be used to manufacture total electrical modules. The module can also be a circuit board, to the outer surface of which components can be attached, in the same way as to a conventional circuit board.
Claims
1. A method for manufacturing an electronic module, the method comprising:
- taking a conductive layer,
- taking a component, which has a contact surface, which has contact zones,
- gluing the component, from the side of the contact surface, to the first surface of the conductive layer,
- making an insulating-material layer, which surrounds the component glued to the conductive layer, on the first surface of the conductive layer,
- making feed-throughs for connecting the contact zones of the component electrically to the conductive layer, and
- making conductive patterns from the conductive layer.
2. A method according to claim 1, in which, when gluing the component:
- an adhesive layer is spread on the surface of the conductive layer, and
- the contact surface of the component is pressed into the adhesive layer.
3. A method according to claim 1, in which, when gluing the component:
- adhesive layers are spread on the contact surface of the component and the first surface of the conductive layer, and
- the adhesive layers are pressed against each other.
4. A method according to claim 2, in which at least one component is glued to the conductive layer and an adhesive layer is spread on areas of the surface of the conductive layer, in such a way that the surface of the conductive layer is essentially free of adhesive outside of the connection zones of the components.
5. A method according to claim 1, in which, when gluing the component:
- an adhesive layer is spread on the contact surface of the component, and
- the adhesive layer on the surface of the component is pressed against the conductive layer.
6. A method according to claim 1, in which
- at least one alignment mark is made on the conductive layer, for the alignment of a component, and
- the component is glued to the conductive layer, aligned relative to the at least one alignment mark.
7. A method according to claim 6, in which at least one alignment mark is a through hole, which penetrates the conductive layer.
8. A method according to claim 1, in which conductive patterns are made from the conductive layer by removing part of the material of the conductive layer, so that the remaining material forms the conductive patterns.
9. A method according to claim 1, in which openings are made in the conductive layer and the adhesive layer at the position of the contact zones of the component, in order to form feed-throughs.
10. A method according to claim 1, in which a support layer is attached to the conductive layer, and is removed after the manufacture of the insulating-material layer, but before the manufacture of the conductive patterns.
11. A method according to claim 1, in which the insulating-material layer surrounding the component is manufactured by attaching an insulating-material layer, in which recesses or cavities for a component or components have been made, to the conductive layer.
12. A method according to claim 11, in which a second insulating-material layer, which is unified and which covers the component, is attached to the surface of the first insulating-material layer attached to the conductive layer.
13. A method according to claim 1, in which a second conductive-pattern layer is manufactured on the opposite surface of the insulating-material layer.
14. A method according to claim 1, in which a separate component, which is not connected to a circuit-board structure, is glued to the conductive layer.
15. A method according to claim 1, in which more than one component is embedded in the electronic module in a corresponding manner.
16. A method according to claim 15, in which the components embedded in the base are connected electrically to each other, in order to form a functional totality.
17. A method according to claim 1, in which a first module is manufactured along with at least one second module and the manufactured modules are attached to each other one on top of the other, so that the modules are aligned relative to each other.
18. A method according to claim 17, in which holes for feed-throughs are made through the modules that are attached on top of each other and conductors are made in the holes thus created, in order to connect the electronic circuits on each of the modules to each other to form a functional totality.
Type: Application
Filed: Mar 31, 2014
Publication Date: Jul 31, 2014
Applicant: GE EMBEDDED ELECTRONICS OY (Helsinki)
Inventors: Risto Tuominen (Helsinki), Petteri Palm (Helsinki), Antti Iihola (Helsinki)
Application Number: 14/230,029
International Classification: H05K 3/38 (20060101);