Patent Abstract:
The present invention describes two systems ( 100, 300 ) for encapsulation of semiconductor dies. Both systems ( 100, 300 ) involve attaching an encapsulation spacer ( 102, 302, 302   a,    302   b ) having one or more apertures ( 104, 304 ) on an associated substrate ( 150 ) so that a group of chips is located within the aperture ( 104, 304 ). The first system ( 100 ) involves dispensing encapsulant ( 103 ) directly into an aperture. The second system ( 300 ) involves attaching an encapsulant delivery layer ( 350, 351 ) onto the encapsulation spacer and discharging encapsulant into an aperture via a recessed gate ( 308 ).

Full Description:
RELATED APPLICATIONS 
     A corresponding PCT patent application is filed on the same day as this case but it relates to the methods of encapsulating semiconductor dies. 
     FIELD OF INVENTION 
     The present invention relates to system for encapsulation of semiconductor dies that does away with cavity moulds associated with injection or transfer molding. In particular, this invention relates to a system of discharging encapsulant into a cavity defined by an encapsulation spacer disposed on an associated substrate or carrier. 
     BACKGROUND 
     Conventional methods used in semiconductor die packaging involve the process of die bonding, wire bonding, encapsulation moulding, deflashing and singulation. Transfer moulding is typically used to encapsulate a group of semiconductor dies and the respective bonded wire interconnections with a conductive substrate to form a semiconductor package. In the process, the conductive substrate, with wire bonded dies, is placed in a lower mould plate of split-cavity. By clamping the upper mould plate onto the lower mould plate with a periphery of the substrate in between the split mould plates, injecting a liquefied encapsulant into the mold cavity, and allowing the encapsulant to cure, the dies are physically sealed and protected from the external environment. By singulating the semiconductor package, individual semiconductor chips are obtained. 
     Due to the use of high pressure in delivering the encapsulant, some of the bond wires may be dislodged or moved into contact with an adjacent bond wire. The other problem area is to design reservoirs, runners, gates and air vents to give encapsulant flow characteristics that are sufficient to meet void-free encapsulation. These moulds are expensive and require constant cleaning to remove the encapsulant from channels inside the moulds. 
     It can thus be seen that there exists a need for new systems and methods of encapsulating semiconductor dies by overcoming disadvantages of the existing prior art. 
     SUMMARY 
     The following presents a simplified summary to provide a basic understanding of the present invention. This summary is not an extensive overview of the invention, and is not intended to identify key features of the invention. Rather, it is to present some of the inventive concepts of this invention in a generalised form as a prelude to the detailed description that is to follow. 
     The present invention seeks a simple and cost effective system for encapsulating semiconductor dies by doing away with conventional cavity moulds associated with injection or transfer moulding; in effect, the costs of making the toolings for the encapsulation spacer are lower than that for making the conventional cavity moulds. With the present invention, a small and simple press, such as a 4-pole press, with simple platen and pressure plate, is sufficient for use with this invention. These tooling are generally simple and flat metal parts and obviate the need for constant cleaning, as in the case of cavity moulds, and this translate to higher productivity in the use of this invention. 
     In another embodiment, the present invention provides a system for semiconductor packaging. The system comprises: an encapsulation spacer ( 102 ,  302 ), which is shaped and dimensioned to match a substrate/carrier ( 150 ); wherein the encapsulation spacer ( 102 ,  302 ) has one or more apertures ( 104 ,  304 ) such that semiconductor dies ( 160 ) on the substrate/carrier ( 150 ) are disposed inside an associated aperture when the encapsulation spacer ( 102 ,  302 ) is attached to the substrate/carrier ( 150 ), and a volume defined by each of the one or more apertures ( 104 ,  304 ) and the substrate/carrier is operable to be filled with an encapsulant ( 103 ). 
     In one embodiment, the encapsulation spacer having a plurality of apertures is in the form of a panel; in another, the encapsulation spacer having a single aperture is in the form of a ring. In another embodiment, the encapsulation spacer is of a unitary layer; in another, the encapsulation spacer comprises two or more layers. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       This invention will be described by way of non-limiting embodiments of the present invention, with reference to the accompanying drawings, in which: 
         FIG. 1A  illustrates an encapsulation system according to an embodiment of the present invention; 
         FIG. 1B  illustrates an encapsulation spacer according to an embodiment of the encapsulation system shown in  FIG. 1A ; 
         FIGS. 2A-2G  illustrate the various steps involved in using the encapsulation system shown in  FIG. 1A ; 
         FIG. 3A  illustrates an encapsulation system according to another embodiment of the present invention; 
         FIG. 3B  illustrates an encapsulation spacer according to an embodiment of the encapsulation system shown in  FIG. 3A , whilst 
         FIG. 3C  illustrates an encapsulant delivery layer for use with the encapsulation spacer shown in  FIG. 3B ; 
         FIG. 3D  illustrates an encapsulation spacer according to another embodiment of the encapsulation system shown in  FIG. 3A , whilst  FIG. 3E  illustrates an encapsulant delivery layer for use with the encapsulation spacer shown in  FIG. 3D ; 
         FIGS. 4A-4F  illustrate the various steps in using the encapsulation system shown in  FIG. 3A . 
     
    
    
     DETAILED DESCRIPTION 
     One or more specific and alternative embodiments of the present invention will now be described with reference to the attached drawings. It shall be apparent to one skilled in the art, however, that this invention may be practised without such specific details. Some of the details may not be described at length so as not to obscure the invention. For ease of reference, common reference numerals or series of numerals will be used throughout the figures when referring to the same or similar features common to the figures. 
       FIG. 1A  shows an encapsulation system  100  according to an embodiment of the present invention. As shown in  FIG. 1A , the encapsulation system  100  is made up of an encapsulation spacer  102  being attached to a semiconductor substrate or carrier  150 . One semiconductor die or chip  160  or more is/are attached to the substrate/carrier  150  according to a conductive pattern on the substrate/carrier. The die/chip  160  may be a wire-bonded device and the substrate  150  is an associated wiring board, such as a QFN leadframe, a flexible substrate, a ball grid substrate, etc. The encapsulation spacer  102  has a plurality of through apertures  104 .  FIG. 1A  shows a simple encapsulation spacer  102  having one row of apertures  104  for ease of description, where a group of dies/chips  160  are located inside each aperture  104  when the encapsulation spacer  102  is attached to a substrate/carrier  150 . Along one or more sides of each aperture  104 , there is/are overflow reservoir(s)  110 . Thickness of the aperture  104  is predetermined according to height of the die/chip  160  to be encapsulated and the amount of overfill on top of the die/chip. Each overflow reservoir  110  is connected to the respective aperture  104  by air vents  114 . By filling the apertures  104  with an encapsulant  103 , applying heat and pressure on the encapsulant so as to minimise any void space therein, allowing the encapsulant to cure and then singulating the encapsulated dies/chips into individual packages, the encapsulation system  100  provides a simple and cost effective method to form semiconductor packages. 
     The encapsulation spacer  102  need not be in the form of a panel as shown in  FIG. 1A . In another embodiment, an encapsulation spacer is formed as an individual encapsulation ring  102 .  FIG. 1B  shows the encapsulation ring  102  is formed in a quadrilateral shape, but it is not so limited in shape. As in the previous embodiment, the overflow reservoir  110  is connected to the inside of the encapsulation ring  102  by air vents  114 . 
     In another embodiment of the encapsulation ring  102 , there is an additional overflow reservoir  110   a . In one embodiment, the additional overflow reservoir  110   a  is located opposite the overflow reservoir  110 . In another embodiment, the additional overflow reservoir  110   a  is round in shape and is located at a corner of the encapsulation ring that is opposite the overflow reservoir  110 . In yet another embodiment, the encapsulation ring  102  has both types of such additional overflow reservoirs  110   a  and associated air vents  114   a.    
     In one embodiment, the encapsulation spacer  102  is made of metal. In another embodiment, the encapsulation spacer is made of thermoplastic. The encapsulation spacer may be formed by conventional machining, moulding, etching, laser cutting or shaping methods. For example, the encapsulation spacer  102  may be made by etching on a metal piece, preferably from copper. In another example, the encapsulation spacer  102  may be made by masking a metal piece and building the exposed metal piece by plating it with a metal, such as copper. The material of the encapsulation spacer is not so limited; any other material that is low cost and easily formed by conventional machining or shaping may be used. 
     In  FIGS. 1A and 1B , the encapsulation spacer/ring  102  is shown to consist of a single layer. In another embodiment, the encapsulation spacer/ring  102   a  is made up of two or more layers, where adjacent layers may be joined by means of adhesive. The depths of the air vents  114 ,  114   a  and overflow reservoirs  110 ,  110   a  may be defined by the thickness of the relevant layer that make up the encapsulation spacer/ring  102   a . An advantage of this embodiment is that the layers to build the encapsulation spacer  102  are either plain solid or have the aperture  104 ; in this way, the height of the encapsulation spacer  102  is configurable according to the dies  160  to be encapsulated. 
     In use, the encapsulation spacer  102 ,  102   a  may be mounted on the substrate  150  by means of adhesive.  FIGS. 2A-2G  illustrate the process  200  of encapsulating semiconductor dies/chip using the above encapsulation spacer/ring  102 ,  102   a . As shown in  FIG. 2A , groups of dies/chips  160  are mounted  210  on the substrate  150  according to the conductive patterns on the substrate. In  FIG. 2B , the encapsulation spacer/ring  102 ,  102   a  is mounted  220  on the substrate  150  by means of adhesive  118 . The encapsulant  103  is then dispensed  230  into each aperture  104  of the encapsulation spacer  102 ,  102   a  or inside the encapsulation ring  102 ,  102   a  until the encapsulant  103  reaches the top of the encapsulation spacer/ring  102 ,  102   a  and is about to overflow into the overflow reservoir(s)  110 ,  110   a  via the respective air vents  114 ,  114   a . Dispensing of the encapsulant may be carried out manually or automatically via a metering system. As shown in  FIG. 2D , pressure may be applied  240  on the surface of the encapsulant after an aperture is filled. An overlay sheet  130  is then applied  250  over the top of the encapsulation spacer/ring  102 ,  102   a  to cover the encapsulant  103 . The entire assembly is then disposed  260  inside a press where a platen, shaped and dimensioned according to the aperture  104  or inside of the encapsulation ring  102 ,  102   a , applies  265  heat and pressure to the encapsulant  103 . The heat and pressure may be maintained for a predetermined period of time to allow the encapsulant  103  to cure, at least partially.  FIG. 2G  shows the dies  160  on the substrate  150  being encapsulated inside the aperture  104  of the encapsulation spacer  102 ,  102   a  at the end of the process  100 . The entire assembly may then be disposed inside an oven to complete curing the encapsulant  103 . After the encapsulant  103  is fully cured, the encapsulated dies/chips are singulated to form individual semiconductor packages. 
       FIG. 3A  shows an encapsulation system  300  according to another embodiment of the present invention. The encapsulation system  300  is made up of the substrate/carrier  150 , an encapsulation spacer  302  and an encapsulant delivery layer  350 . As shown in  FIG. 3A , the encapsulation spacer  302  is attached to the substrate/carrier  150  and the encapsulant delivery layer  350  is in turn attached to the encapsulation spacer  302 ; such attachments may be by means of adhesive  118 . The present invention is clearer when individual parts of the encapsulation system  300  are described. 
       FIG. 3B  shows the encapsulation spacer  302  according to an embodiment of the present invention. The encapsulation spacer  302  is exemplified as an elongate strip, which has a plurality of apertures  304 . In  FIG. 3B , the apertures  304  are aligned in a row along a longer dimension of the elongate strip for simpler description but they are not so limited. As in the previous embodiment, a group of semiconductor dies/chips  160  are attached to the substrate/carrier  150  such that the dies/chips are seen within an aperture  304  and a thickness of the encapsulation spacer  302  at the aperture defines a thickness of the encapsulant around the die/chip  160 . 
     On the shorter dimension of the elongate strip, as shown in  FIG. 3B , there are four reliefs  320 . The reliefs  320  are dimensioned so that they provide finger and thumb gripping spaces, for example when the encapsulation spacer  302  is to be peeled off from the substrate/carrier  150  or when the encapsulant delivery layer  350  is to be peeled off from the encapsulation spacer  302  after the encapsulant has cured. 
     The right side of the encapsulation spacer  302  has a larger margin than the left hand side, as seen in  FIG. 3B . In the right hand margin, the closed phantom line  306  shows the location of the encapsulant  103  stored in the encapsulant delivery layer  350  when the encapsulant delivery layer  350  is attached to the encapsulation spacer  302 . A recessed gate  308 , on the rear side of the encapsulation spacer  302  as seen in  FIG. 3B , extends from inside the closed phantom line  306  to the associated aperture  304 . A plane  309  defined by another phantom line cuts through the recessed gate  308 . The area of the encapsulation spacer  302  on the right hand side of the plane  309  may be broken or sheared off after encapsulant is delivered into the apertures  304  and has at least partially cured. On the left and rear side of each aperture  304 , as seen in  FIG. 3B , is an overflow reservoir  310 . An air vent  314  connects each overflow reservoir  310  to the respective aperture  304 . 
     In one embodiment, the encapsulation spacer  302  is made of a unitary layer. For example, when the encapsulation spacer  302  is metallic, the built-up layer may be deposited by plating a metal on a substrate whilst depressions or apertures may be formed by masking and etching away the exposed metal surface. In another embodiment, the encapsulation spacer  302   a  is made up of two or more layers; the adjacent layers may be joined by means of adhesive; in another example, the adjacent layers may be laminated together; the depths of the recessed gates  308 , air vents  314  and overflow reservoirs  310  may be defined by the thicknesses of the relevant layers that make up the encapsulation spacer  302   a.    
       FIG. 3C  shows an encapsulant delivery layer  350  according to an embodiment of the present invention for use with the encapsulation spacer  302 , 302   a . As shown in  FIG. 3A , the encapsulant delivery layer  350  is dimensioned to match the encapsulation spacer  302 , 302   a , where the encapsulant is stored in a reservoir  352 . The encapsulant delivery layer  350  is made up of a thin and flexible plastic but is strong and resilient enough to hold the encapsulant in the reservoir  352 . In an example, the encapsulant delivery layer  350  may be made by conventional plastic moulding, such as injection or transfer moulding. Before use, the encapsulant delivery layer  350  may be covered by a peel-off layer; by removing the peel-off layer, an adhesive on the encapsulant delivery layer  350  is exposed and the encapsulant delivery layer  350  can then be attached onto the encapsulation spacer  302 , 302   a . In use, the encapsulation system  300  is placed inside a press and pressure on the reservoir  352  collapses the reservoir to deliver the encapsulant through the recessed gate  308  into the associated aperture  304  to encapsulate the dies/chips  160  disposed on the substrate/carrier  150 . After the encapsulant around the dies/chips has cured, the encapsulant delivery layer  350  may be peeled off; alternatively, the encapsulation spacer  302 ,  302   a  together with the encapsulant delivery layer  350  may be broken or sheared at the plane  309 . 
       FIG. 3D  shows an encapsulation spacer  302   b  according to another embodiment of the present invention. The encapsulation spacer  302   b  is similar to the encapsulation spacer  302 ,  302   a  except that the recessed gate  308  starts with a recess  308   a . Each recess  308   a  corresponds with a discrete encapsulant reservoir  353  on a matching encapsulant delivery layer  351  shown in  FIG. 3E . In another embodiment, the area around the recess  308   a  may be shaped and dimensioned to overlap the associated encapsulant reservoir  353 , and the area around the recessed gate  308  is sufficient to adhere to the encapsulant delivery layer  351  to allow encapsulant to be delivered into the aperture  304 , such that material around the recess  308   a  and recessed gate  308  is redundant; this redundant material when removed forms openings  324 . 
       FIGS. 4A-4F  illustrate the process  400  of encapsulating semiconductor dies using the encapsulating spacer  302 ,  302   a ,  302   b . As shown in  FIG. 4A , groups of dies  160  are mounted  410  on the substrate  150  according to the conductive pattern on the substrate. In  FIG. 4B , the encapsulation spacer  302 ,  302   a ,  302   b  is mounted  420  on the substrate, for example by adhesive. In  FIG. 4C , the reservoir or pot  352 ,  353  of an encapsulant delivery layer  350 ,  351  is filled  430  with encapsulant  103 . In  FIG. 4D , the encapsulant delivery layer  350 ,  351  is then attached to the encapsulation spacer  302 ,  302   a ,  302   b . The entire assembly or system  300  is then disposed inside a press where a platen, shaped and dimensioned according to the aperture  304 , applies  440  heat and pressure to the encapsulant  103 . This is followed by collapsing  450  the reservoir or pot  352 ,  353  of the encapsulant delivery layer  350 ,  351 , for example, by extending a ram on the reservoir/pot, as shown in  FIG. 4E . The heat and pressure may be maintained for a predetermined period of time to allow the encapsulant  103  to cure, at least partially, as shown in FIG.  4 F. After the encapsulant is cured and the assembly is removed from the press, the encapsulation spacer  302 ,  302   a ,  302   b  and encapsulant delivery layer  350 ,  351  are broken or sheared off  460  along plane  309  before the encapsulated dies are singulated to form individual semiconductor packages. Alternatively, the encapsulant delivery layer  350 ,  351  are removed prior to singulation to form individual semiconductor packages. 
     While specific embodiments have been described and illustrated, it is understood that many changes, modifications, variations and combinations thereof could be made to the present invention without departing from the scope of the invention. For example, the encapsulation spacer  102 ,  102   a ,  302 ,  302   a ,  302   b  may have a vacuum channel  111 ,  311  disposed alongside each overflow reservoir  110 ,  110   a ,  310 . Each vacuum channel  111 ,  311  may have a vacuum port  312  for connection to a vacuum system as when necessary; a vacuum opening  362  corresponding to the vacuum port  312  may then be provided on the encapsulant delivery layer  350 ,  351 . A control gate  315  connects an overflow reservoir to the associated vacuum channel  311 . Whilst a panel layout of the encapsulation system  300  has been described, the system  300  is also applicable for use with individual encapsulation rings and the encapsulant delivery layer  351 .

Technology Classification (CPC): 7