EP1155449A1 - Semiconductor component with a chip carrier with openings for contacting - Google Patents
Semiconductor component with a chip carrier with openings for contactingInfo
- Publication number
- EP1155449A1 EP1155449A1 EP00912347A EP00912347A EP1155449A1 EP 1155449 A1 EP1155449 A1 EP 1155449A1 EP 00912347 A EP00912347 A EP 00912347A EP 00912347 A EP00912347 A EP 00912347A EP 1155449 A1 EP1155449 A1 EP 1155449A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- chip
- metal foil
- chip carrier
- semiconductor
- openings
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
Classifications
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- H01L23/3107—Encapsulations, e.g. encapsulating layers, coatings, e.g. for protection characterised by the arrangement or shape the device being completely enclosed
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- H05K3/4084—Through-connections; Vertical interconnect access [VIA] connections by deforming at least one of the conductive layers
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P70/00—Climate change mitigation technologies in the production process for final industrial or consumer products
- Y02P70/50—Manufacturing or production processes characterised by the final manufactured product
Definitions
- the present invention relates to a semiconductor component with at least one semiconductor chip, and with a chip carrier for mounting the semiconductor chip on one of the surfaces of the chip carrier, the semiconductor chip being electrically connected to solder connection points.
- the solder connection points form a conductive connection through openings in the chip carrier which extend from the first surface of the chip carrier through the chip carrier to a second surface of the chip carrier.
- At least the semiconductor chip is surrounded by a housing which was produced, for example, by pressing with a molding compound, a globe-top technique or from an underfill of a flip-chip arrangement.
- Such semiconductor components are known from the prior art, for example from US 4,700,276.
- the present invention can be used, for example, in logic or high-frequency semiconductor components. However, it is readily applicable to other types of semiconductor devices, such as memory devices.
- the semiconductor chips are usually mounted on metal leadframes or laminate substrates as chip carriers.
- the chip is then contacted using either wire bonding technology or flip-chip technology.
- the encapsulation of the chip is usually carried out by pressing using transfer molding.
- the contact connections or contact pads of the component are located on the underside of the semiconductor component. Since these components do not have the usual pin connections, one speaks of “leadless components” and of “leadless chip carriers” (LCC).
- Sol- before me- components of the prior art with a Leadfra- or laminate -Chip are situated in Figures 1 and 2 Darge ⁇ .
- the designs of such semiconductor components known to date from the prior art have significant disadvantages.
- the semiconductor components shown in Figure 1 with a leadframe chip carrier have a high reliability and stability of the chip carrier during manufacture and during operation of the component.
- the leadframe has many openings, there are great problems in sealing the chip carrier in the injection mold, especially in the case of one-sided encapsulation, in such a way that passage of the molding compound from the side on which the chip is arranged to the opposite side on which the Connections to the circuit board are arranged to prevent.
- laminate chip carriers have major disadvantages with regard to their reliability and stability, in particular due to their significantly increased sensitivity to moisture and the risk of soldering shocks occurring (popcorn effect).
- the object of the present invention is therefore to provide a semiconductor component with at least one semiconductor chip and a chip carrier, which offers simple manufacture and high reliability, in particular with regard to the disadvantages mentioned.
- the chip carrier of the semiconductor component has openings which extend from a first surface of the chip carrier through the chip carrier to a second surface.
- the chip carrier is ideally selected from a material that guarantees high reliability and stability.
- the openings of the chip carrier are tall foil lined, which also forms the solder connection points of the semiconductor device.
- the metal foil extends from the first surface of the chip carrier through the openings in the direction of the second surface of the chip carrier. The metal foil thus covers the entire area of the openings in the chip carrier and thus effectively seals the openings against possible penetration of the molding compound.
- the metal foil can also simultaneously form the contact points, which serve to establish a conductive connection to the semiconductor chip.
- solder connection points can be contacted directly from the second surface of the chip carrier.
- a further metal foil is arranged between the semiconductor chip and the chip carrier which lines this at least one opening and extends from the first surface of the chip carrier through the opening to the second surface of the chip carrier. This metal foil enables a rear electrical connection of the semiconductor chip, so that the semiconductor component is well suited, for example, for single semiconductors.
- the connection of the underside of the chip to the metal foil results in better heat dissipation or shielding or grounding of the semiconductor chip
- Circuit board Depending on the size of the opening in the chip carrier below the semiconductor chip, a partial or even entire connection of the underside of the chip to the printed circuit board can follow by soldering the metal foil onto the printed circuit board.
- the metal foil can cover a part of the first surface that is adjacent to the edge of the openings. However, it can also be provided that the metal foil is only in the openings and does not extend over the edge of the openings onto the surface of the chip carrier. If the metal foil is also used as a contact point, in this case, contact can be made with the metal foil to produce a conductive connection to the semiconductor chip in the interior of the opening. However, if the metal foil extends over the edge of the opening to the first surface of the chip carrier, contact can also be made with the metal foil in the region of the first surface of the chip carrier. As a rule, a separate piece of metal foil is provided for each of the openings, since these should usually have no electrical connection with one another. If necessary, however, several openings can also be lined with a continuous metal foil, where such an electrical connection is just desirable.
- the metal foil In the area of the second surface of the chip carrier, provision can be made for the metal foil to be flush with the second surface or for the metal foil to protrude from the opening beyond the second surface. In the latter case, the metal foil forms a contact which projects beyond the chip carrier and can be used to ensure a certain distance between the chip carrier and the printed circuit board. However, it can also be provided that the metal foil in the opening does not extend all the way to the edge of the opening and thus not all the way to the second surface of the chip carrier.
- the conductive connection to the circuit board to be attached underneath can be established by providing corresponding solder connections with solder material on the circuit board, which fill the remaining area of the openings with solder material during soldering.
- the chip carrier should consist of the most stable and reliable material possible.
- ceramic or metal can be used.
- the chip carrier preferably consists of a plastic tape, for example of epoxy glass, polyimide or polyester.
- Suitable metals are used for the metal foil, such as copper, copper alloys or iron-nickel alloys
- the metal foil can be introduced into the openings of the chip carrier, for example, by first laminating a structured metal layer onto the chip carrier, which is then drawn into the openings of the chip carrier by a deep-drawing process or an embossing process. It can also be provided that the metal foil is completely structured before the lamination, so that the metal foil already lines the openings in the desired manner after the lamination, and a further stamping or deep-drawing process is therefore unnecessary.
- the shaped metal foil on the underside of the chip carrier thus creates a defined solder connection point for the solder connection. In the area of the top of the chip carrier, the metal foil can be used as a defined contact point for the electrical connection from the semiconductor chip to the chip carrier.
- FIG. 1 shows a semiconductor component with leadframe chip carrier according to the prior art.
- Figure 2 shows a semiconductor device with laminate chip carrier according to the prior art.
- FIG. 3a shows a semiconductor component with a chip carrier with openings which are later lined with a metal foil.
- Figure 3b shows a semiconductor device according to Figure 3a, the
- Openings are already lined with a metal foil.
- FIG. 4 shows a semiconductor component according to FIG. 3b, with an additional opening in the chip carrier below the semiconductor chip and a metal foil between the semiconductor chip and the chip carrier or printed circuit board.
- Figure 5 examples of the arrangement of the openings or solder connection points.
- Figure 6 shows a semiconductor device according to Figure 3b, but with flip chip assembly technology.
- FIG. 7 top view of a chip carrier with solder connection points in a matrix arrangement with conductor paths to the openings
- Figure 8 top view of a chip carrier with a multichip arrangement
- FIG. 9 arrangement according to FIG. 3b, but as a ball grid array and with wedge contacting of the metal foil
- FIG. 10 top view of a matrix array with a plurality of chip carriers with solder connection points on the edge of the chip carrier
- FIG 11 Schematic cross section through an opening in the chip carrier, lined with a metal foil
- FIG. 3a shows a semiconductor component according to the invention, which has a plastic tape 1 as a chip carrier on which a semiconductor chip 2 is mounted.
- the semiconductor chip 2 and the Chip carriers 1 are connected to one another by an adhesive layer 12.
- the chip carrier has openings 20 which extend from the first surface 8 of the chip carrier 1 to the second surface 9 of the chip carrier 1.
- the later position of a metal foil 7, which is to line the openings 20, is indicated by the dotted areas.
- FIG. 3 b shows that these openings 20 are lined with a metal foil 7 which extends over the edge of the openings 20 to the first surface 8.
- the metal foil 7 extends to the second surface 9 of the chip carrier. The metal foil 7 completely fills the opening 20 of the chip carrier and thus seals it.
- Bonding wires 3 are provided for establishing a conductive connection between the semiconductor chip 2 and the metal foil 7, which simultaneously forms a solder connection point 5 and a contacting point 6.
- Conventional technologies such as nailhead and / or wedge contacts can be provided for contacting.
- an elevation 16 is preferably formed on the metal foil 7 in the interior of the opening 20, e.g. a so-called gold bump, which facilitates contacting.
- contact can then be made with the usual methods. For example, in the case of FIG. 3b, contact is made on the side of the metal foil 7 by wedge contacting on the elevation 16 previously inserted.
- the right part of the figure shows a top view of the underside 9 of the chip carrier 1, the position of the semiconductor chip 2 on the opposite side 8 of the chip carrier being indicated by the dashed line 19.
- a part of the openings 20, in which the solder connection points 5 are formed towards the printed circuit board, would therefore be covered on the opposite side by the semiconductor chip 2.
- the conductor paths 17 are arranged on the top 8 of the chip carrier 1 and with the metal foils 7 in the
- These conductor paths 17 can likewise be produced from the metal foil 7 which is used to line the openings 20, or they can be produced in the usual way, for example by means of a second metal foil.
- the semiconductor component is encapsulated on one side for encapsulation with a molding compound 4, which forms the housing of the semiconductor component.
- the housing 4 has vertical side flanks in FIG. 3b, since in this case the component is pressed in a matrix array and subsequently e.g. was removed from the composite by sawing the matrix array.
- FIG. 4 shows an alternative embodiment of the semiconductor component according to FIG. 3b.
- a further opening 10 is provided in the chip carrier 1 under the semiconductor chip 2.
- this opening 10 has a larger extension than the semiconductor chip 2.
- one or more openings of smaller extension than the semiconductor chip 2 are provided under the semiconductor chip 2. This is shown as an example in the top view of FIG. 5 on a chip carrier.
- the opening 10 enables electrical contact to a connection located on the underside of the semiconductor chip, as is customary above all in the case of single semiconductors, for example diodes, transistors, MOSFETS etc.
- FIG. 5 a) shows a plan view of the opening 10, which is larger than the extent of the semiconductor chip 2.
- FIG. 5 b) shows a plan view of the opening 10, which is larger than the extent of the semiconductor chip 2.
- All openings 10 can be lined with a continuous metal foil 11 or a separate piece of metal foil 11 can be provided for each of the openings 10. For a low electrical resistance, the greatest possible coverage of the semiconductor chip and the metal foil is desirable.
- FIG. 6 shows a semiconductor component according to FIG. 3b, but no bond wires are provided for establishing a conductive connection from the semiconductor chip 2 to the contacting points 6, but instead the semiconductor chip 2 is assembled using flip-chip technology, in which the conductive connection is made by the Bottom of the semiconductor chip 2 is produced starting.
- Contact balls 13 are provided there, which are embedded in an underfill 15. Starting from these contact balls, conductor tracks 14 are drawn to the metal foils 7. These conductor tracks 14 can likewise be produced from the metal foil 7 which is used for lining the openings 20, or they can be produced, for example, by a second metal foil.
- FIG. 8 shows an alternative embodiment of the invention, in which a plurality of semiconductor chips 2a, 2b are mounted on a common chip carrier in the form of a multichip component.
- bond wires 3a are provided, which connect the semiconductor chips 2a, 2b to one another, and further bond wires 3b for contacting the metal foils 7 in the openings 20.
- FIG. 9 shows a further alternative of the invention, solder balls 18 being applied to the metal foils 7 on the underside of the chip carrier 1, so that a ball grid array arrangement (BGA) is produced.
- BGA ball grid array arrangement
- the metal foil 7 is flush with the second surface 9 or that the metal foil 7 protrudes from the opening 20 beyond the second surface 9.
- the metal foil 7 m of the opening 20 does not extend completely to the edge of the opening 20 and thus not completely to the second surface 9 of the chip carrier 1.
- FIG. 11 shows a cross section through an opening 20 m in schematic form, some examples from alternatives a) to d) showing how the metal foil 7 can be arranged in a different way in the opening 20.
- it can extend along the side walls of the opening 20 and form a largely horizontal or slightly curved termination in the region of the lower surface 9 of the chip carrier 1.
- Variant b) shows a metal foil 7 which is wedged slightly curved in the opening 20.
- the expansion of the metal foil 7 corresponds exactly to the size of the opening 20.
- Variant d) indicates a metal foil 7 which was structured before the lamination onto the chip carrier 1 in such a way that it lines the opening 20 exactly and thus only m the opening 20 is inserted as a kind of plug as part of the lamination process.
- FIG. 10 shows a particularly advantageous arrangement of the openings 20 and thus the solder connection points 5.
- the not yet separated chip carriers la to le are arranged in a matrix array, the lines 22 representing the future edges of the chip carriers la to le.
- the matrix array can be cut along the lines 22, as already described above, by punching, sawing, etc.
- the openings 20 and thus the solder connection points 5 are each arranged at the edges of the chip carriers la to le in such a way that a solder connection point of a chip carrier, for example of chip carrier la, is opposite and a solder connection point of an adjacent chip carrier, for example of chip carrier 1b directly adjacent to this.
- the openings 20 for these two solder connection points 5 can thus be created in a common process as a single opening, approximately twice as long, which extends over the edge of the chip carriers 1 a, 1 b. Just- so these two openings 20, which initially still form a single opening, can be lined in a common step through the metal foil 7 to form the solder connection points 5.
- the special arrangement according to FIG. 10 means that, for example, a single stamping and embossing process can be used to produce two solder connection points 5 which are initially still connected, but separated after separation, whereby the manufacture of the components is considerably simplified and accelerated.
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Abstract
Disclosed is a semiconductor component comprising at least one semiconductor chip (2), a chip carrier (1) for mounting the semiconductor chip (2) onto a first surface (8) of the chip carrier (2) and contact points (6) which are electrically connected to the semiconductor chip (2) and which are provided with a conductive connection via openings (20) of the chip carrier (1) to solder terminals (5) in the area of a second surface (9) of the chip carrier (1). The solder terminals (5) are formed from a metal film (7) which lines the openings (20), extends from the first surface (8) through the openings (20) to the second surface (9) and can be directly contacted. The semiconductor component also comprises an opening (10) in the chip carrier below the semiconductor chip (2). A metal film (11) which lines said opening (10) is situated between the chip carrier (1) and the semiconductor chip (2) so as to form a solder terminal.
Description
Beschreibungdescription
Halbleiterbauelement mit einem Chipträger mit Öffnungen zur KontaktlerungSemiconductor component with a chip carrier with openings for contacting
Die vorliegende Erfindung betrifft ein Halbleiterbauelement mit mindestens einem Halbleiterchip, sowie mit einem Chipträger zur Montage des Halbleiterchips auf einer der Oberflächen des Chipträgers, wobei der Halbleiterchip mit Lötanschluß- stellen elektrisch verbunden ist. Die Lötanschlußstellen bilden dabei eine leitende Verbindung durch Öffnungen des Chip- tragers hindurch, die sich von der ersten Oberfläche des Chiptragers durch den Chipträger hindurch bis zu einer zweiten Oberfläche des Chipträgers erstrecken. Zumindest der Halbleiterchip ist dabei von einem Gehäuse umgeben, das beispielsweise durch Umpressen mit einer Preßmasse, m einer Globe-Top-Technik oder aus einer Unterfüllung einer Flipchip- Anordnung hergestellt wurde. Solche Halbleiterbauelemente sind aus dem Stand der Technik beispielsweise aus US 4,700,276 bekannt.The present invention relates to a semiconductor component with at least one semiconductor chip, and with a chip carrier for mounting the semiconductor chip on one of the surfaces of the chip carrier, the semiconductor chip being electrically connected to solder connection points. The solder connection points form a conductive connection through openings in the chip carrier which extend from the first surface of the chip carrier through the chip carrier to a second surface of the chip carrier. At least the semiconductor chip is surrounded by a housing which was produced, for example, by pressing with a molding compound, a globe-top technique or from an underfill of a flip-chip arrangement. Such semiconductor components are known from the prior art, for example from US 4,700,276.
Die vorliegende Erfindung kann beispielsweise bei Logic- oder Hochfrequenz-Halbleiterbauelementen Anwendung finden. Sie ist ηedoch ohne weiteres auch bei anderen Arten von Halbleiter- baue1erneuten anwendbar, wie beispielsweise bei Speicher- Bauelementen .The present invention can be used, for example, in logic or high-frequency semiconductor components. However, it is readily applicable to other types of semiconductor devices, such as memory devices.
Üblicherweise werden bei solchen Halbleiterbauelementen die Halbleiterchips meistens auf Metall -Leadframes oder Laminat - Substrate als Chipträger montiert. Der Chip wird anschließend entweder m Drahtbondtechnik oder Flipchip-Technik kontaktiert. Die Verkapselung des Chips erfolgt m der Regel durch Umpressen mittels Transfermolding. An der Unterseite des Halbleiterbauelementes befinden sich die Kontaktanschlüsse oder Kontaktpads des Bauelements. Da diese Bauelemente keine üblichen Pinanschlüsse aufweisen, spricht man von „Leadless- Bauelementen" sowie von „Leadless-Chip-Carπern" (LCC) . Sol-
ehe Bauelemente aus dem Stand der Technik mit einem Leadfra- me- oder Laminat -Chipträger sind in Abbildung 1 und 2 darge¬ stellt .In the case of such semiconductor components, the semiconductor chips are usually mounted on metal leadframes or laminate substrates as chip carriers. The chip is then contacted using either wire bonding technology or flip-chip technology. The encapsulation of the chip is usually carried out by pressing using transfer molding. The contact connections or contact pads of the component are located on the underside of the semiconductor component. Since these components do not have the usual pin connections, one speaks of “leadless components” and of “leadless chip carriers” (LCC). Sol- before me- components of the prior art with a Leadfra- or laminate -Chipträger are situated in Figures 1 and 2 Darge ¬.
Mit „Leadless-Chip-Bauelementen" kann im Vergleich zu herkömmlichen Bauelementen bei gleicher Fläche auf der Leiterplatte eine deutlich höhere Zahl von Anschlüssen realisiert werden, oder bei gleicher Anzahl von Anschlüssen eine deutlich kleinere Fläche, wobei gleichzeitig eine geringere Bau- höhe der Bauelemente erzielt wird. Speziell bei Hochfrequenz - Anwendungen ergeben sich Vorteile durch die kurzen Signalwege und die kompakte Bauweise der Bauelemente. Die gute Anbindung des Bauelements zur Leiterplatte und die kleinen Bauteilabmessungen wirken sich günstig auf die mechanische Belastbar- keit des Bauelements sowie seiner Befestigung auf der Leiterplatte aus.With "leadless chip components", in comparison to conventional components, a significantly higher number of connections can be realized with the same area on the printed circuit board, or a significantly smaller area with the same number of connections, while at the same time achieving a lower overall height of the components The advantages of the short signal paths and the compact design of the components result in particular advantages in high-frequency applications. The good connection of the component to the circuit board and the small component dimensions have a favorable effect on the mechanical strength of the component and its attachment to the circuit board .
Die bislang aus dem Stand der Technik bekannten Bauweisen solcher Halbleiterbauelemente weisen jedoch deutliche Nach- teile auf. So weisen die in Abbildung 1 dargestellten Halbleiterbauelemente mit einem Leadframe-Chipträger zwar eine hohe Zuverlässigkeit und Stabilität des Chipträgers während der Herstellung sowie während des Betriebes des Bauelementes auf. Jedoch ergeben sich große Probleme beim Umhüllen des Halbleiterbauelementes mit einer Pressmasse. Da das Leadframe viele Öffnungen aufweist, ergeben sich große Probleme, den Chipträger im Spritzwerkzeug gerade bei einer einseitigen Um- pressung so abzudichten, daß ein Durchtreten der Pressmasse von derjenigen Seite, auf der der Chip angeordnet ist, zu der gegenüberliegenden Seite, auf der die Anschlüsse zur Leiterplatte angeordnet sind, zu verhindern. Somit ist entweder ein aufwendiges Anbringen von Dichtungen wie beispielsweise Dichtfolien an der Unterseite des Chipträgers notwendig, oder es wird der Chipträger zunächst nur von einer Seite aus strukturiert und nach dem Umpressen der nichtstrukturierte Teil auf der Unterseite des Chipträgers in einem Ätzschritt entfernt. In beiden Fällen ist somit eine relativ aufwendige
Bearbeitung des Halbleiterbauelementes notwendig, um ein optimales Umpressen zu gewährleisten. Dies ist insbesondere notwendig, wenn die einzelnen Halbleiterchips m Form eines Matrix-Arrays zusammengefaßt werden sollen. Eine Alternative hierzu ist zwar, jeden einzelnen Chip zu umpressen. Folge hiervon ist jedoch ein größerer Platzbedarf für jeden einzelnen Chip und damit eine geringere Anzahl von Halbleiterchips pro Fläche. Die damit erzielbare Gesamtkapazität der Produk- tionsanlagen nimmt somit drastisch ab.However, the designs of such semiconductor components known to date from the prior art have significant disadvantages. Thus, the semiconductor components shown in Figure 1 with a leadframe chip carrier have a high reliability and stability of the chip carrier during manufacture and during operation of the component. However, there are great problems in enveloping the semiconductor component with a molding compound. Since the leadframe has many openings, there are great problems in sealing the chip carrier in the injection mold, especially in the case of one-sided encapsulation, in such a way that passage of the molding compound from the side on which the chip is arranged to the opposite side on which the Connections to the circuit board are arranged to prevent. Thus, either a complicated application of seals such as sealing foils to the underside of the chip carrier is necessary, or the chip carrier is first structured only from one side and, after the extrusion, the non-structured part on the underside of the chip carrier is removed in an etching step. In both cases, this is a relatively complex process Machining of the semiconductor component necessary to ensure optimal pressing. This is particularly necessary if the individual semiconductor chips are to be combined in the form of a matrix array. An alternative to this is to press around each individual chip. However, the consequence of this is a larger space requirement for each individual chip and thus a smaller number of semiconductor chips per area. The total capacity of the production plants that can be achieved thereby drastically decreases.
Die obengenannten Probleme beim Umpressen der Halbleiterbau- elemente können vermieden werden, wenn statt einem Leadframe- Chipträger ein Laminat -Chipträger verwendet wird. Dieser weist keine Öffnungen auf, durch die die Pressmasse auf die Unterseite des Halbleiterbauelementes gelangen könnte. Lami- nat-Chipträger weisen jedoch große Nachteile bezüglich ihrer Zuverlässigkeit und Stabilität auf, insbesondere aufgrund ihrer wesentlich erhöhten Feuchtigkeitsempfmdlichkeit und der Gefahr des Auftretens von Lötschocks (Popcorn-Effekt ) .The above-mentioned problems when pressing the semiconductor components around can be avoided if a laminate chip carrier is used instead of a leadframe chip carrier. This has no openings through which the molding compound could reach the underside of the semiconductor component. However, laminate chip carriers have major disadvantages with regard to their reliability and stability, in particular due to their significantly increased sensitivity to moisture and the risk of soldering shocks occurring (popcorn effect).
Aufgabe der vorliegenden Erfindung ist es daher, ein Halbleiterbauelement mit mindestens einem Halbleiterchip und einem Chipträger bereitzustellen, das eine einfache Herstellung und hohe Zuverlässigkeit insbesondere im Hinblick auf die genann- ten Nachteile bietet.The object of the present invention is therefore to provide a semiconductor component with at least one semiconductor chip and a chip carrier, which offers simple manufacture and high reliability, in particular with regard to the disadvantages mentioned.
Diese Aufgabe wird gelöst durch die Merkmale des vorliegenden Patentanspruchs 1.This object is achieved by the features of the present patent claim 1.
Der Chipträger des Halbleiterbauelements weist dabei Öffnungen auf, die sich von einer ersten Oberfläche des Chipträgers durch den Chipträger hindurch bis zu einer zweiten Oberfläche erstrecken. Der Chipträger wird dabei idealerweise aus einem Material gewählt, das eine hohe Zuverlässigkeit und Stabili- tat gewährleistet. Um gleichzeitig eine Dichtigkeit des Halbleiterbauelements beim Umpressen mit einer Preßmasse zu erzielen, werden die Öffnungen des Chipträgers mit einer Me-
tallfolie ausgekleidet, die gleichzeitig die Lötanschlußstellen des Halbleiterbauelementes bildet. Dabei erstreckt sich die Metallfolie von der ersten Oberfläche des Chipträgers durch die Öffnungen in Richtung der zweiten Oberfläche des Chipträgers. Die Metallfolie bedeckt somit die gesamte Fläche der Öffnungen im Chipträger und dichtet damit die Öffnungen effektiv gegen ein mögliches Durchtreten der Preßmasse ab. Die Metallfolie kann auch gleichzeitig die Kontaktierungs- stellen bilden, die dazu dienen, eine leitende Verbindung zu dem Halbleiterchip herzustellen. Es können aber auch separate Kontaktierungsstellen vorgesehen sein, die dann eine leitende Verbindung zu der Metallfolie aufweisen. Die Lötanschlußstellen sind jedoch von der zweiten Oberfläche des Chipträgers her direkt kontaktierbar . Unter dem Halbleiterchip ist minde- stens eine weitere Öffnung im Chipträger vorhanden. Es ist dabei zwischen dem Halbleiterchip und dem Chipträger eine weitere Metallfolie angeordnet, die diese mindestens eine Öffnung auskleidet und sich von der ersten Oberfläche des Chipträgers durch die Öffnung zur zweiten Oberfläche des Chipträgers hin erstreckt. Diese Metallfolie ermöglicht einen rückseitigen elektrischen Anschluß des Halbleiterchips, so daß das Halbleiterbauelement z.B. für Einzelhalbleiter gut geeignet ist. Ferner ergibt sich durch die Verbindung der Chipunterseite mit der Metallfolie eine bessere ärmeablei- tung oder Abschirmung bzw. Erdung des Halbleiterchips zurThe chip carrier of the semiconductor component has openings which extend from a first surface of the chip carrier through the chip carrier to a second surface. The chip carrier is ideally selected from a material that guarantees high reliability and stability. In order to achieve a tightness of the semiconductor component during the encapsulation with a molding compound, the openings of the chip carrier are tall foil lined, which also forms the solder connection points of the semiconductor device. The metal foil extends from the first surface of the chip carrier through the openings in the direction of the second surface of the chip carrier. The metal foil thus covers the entire area of the openings in the chip carrier and thus effectively seals the openings against possible penetration of the molding compound. The metal foil can also simultaneously form the contact points, which serve to establish a conductive connection to the semiconductor chip. However, separate contacting points can also be provided, which then have a conductive connection to the metal foil. However, the solder connection points can be contacted directly from the second surface of the chip carrier. There is at least one further opening in the chip carrier under the semiconductor chip. A further metal foil is arranged between the semiconductor chip and the chip carrier which lines this at least one opening and extends from the first surface of the chip carrier through the opening to the second surface of the chip carrier. This metal foil enables a rear electrical connection of the semiconductor chip, so that the semiconductor component is well suited, for example, for single semiconductors. Furthermore, the connection of the underside of the chip to the metal foil results in better heat dissipation or shielding or grounding of the semiconductor chip
Leiterplatte hin. Je nach Größe der Öffnung im Chipträger unterhalb des Halbleiterchips kann dabei eine partielle oder sogar ganzflächige Verbindung der Chipunterseite zur Leiterplatte durch Anlöten der Metallfolie auf der Leiterplatte folgen.Circuit board. Depending on the size of the opening in the chip carrier below the semiconductor chip, a partial or even entire connection of the underside of the chip to the printed circuit board can follow by soldering the metal foil onto the printed circuit board.
Die Metallfolie kann dabei einen Teil der ersten Oberfläche bedecken, die an den Rand der Öffnungen angrenzt. Es kann jedoch auch vorgesehen sein, daß die Metallfolie sich lediglich in den Öffnungen befindet und sich nicht bis über den Rand der Öffnungen auf die Oberfläche des Chipträgers erstreckt. Wird die Metallfolie auch als Kontaktierungsstelle genutzt,
so kann in diesem Fall eine Kontaktierung der Metallfolie zur Herstellung einer leitenden Verbindung zum Halbleiterchip im Innenraum der Öffnung erfolgen. Erstreckt sich jedoch die Metallfolie über den Rand der Öffnung bis auf die erste Ober- fläche des Chipträgers, so kann auch eine Kontaktierung der Metallfolie im Bereich der ersten Oberfläche des Chipträgers erfolgen. In der Regel wird ein separates Stück Metallfolie für jede der Öffnungen vorgesehen, da diese untereinander meist keine elektrische Verbindung aufweisen sollen. Es kön- nen jedoch gegebenenfalls auch mehrere Öffnungen durch eine durchgehende Metallfolie ausgekleidet werden, wo eine solche elektrische Verbindung gerade wünschenswert ist .The metal foil can cover a part of the first surface that is adjacent to the edge of the openings. However, it can also be provided that the metal foil is only in the openings and does not extend over the edge of the openings onto the surface of the chip carrier. If the metal foil is also used as a contact point, in this case, contact can be made with the metal foil to produce a conductive connection to the semiconductor chip in the interior of the opening. However, if the metal foil extends over the edge of the opening to the first surface of the chip carrier, contact can also be made with the metal foil in the region of the first surface of the chip carrier. As a rule, a separate piece of metal foil is provided for each of the openings, since these should usually have no electrical connection with one another. If necessary, however, several openings can also be lined with a continuous metal foil, where such an electrical connection is just desirable.
Im Bereich der zweiten Oberfläche des Chipträgers kann vorge- sehen sein, daß die Metallfolie bündig mit der zweiten Oberfläche abschließt oder daß die Metallfolie aus der Öffnung über die zweite Oberfläche hinausragt. Im letzten Fall bildet die Metallfolie einen Kontakt, der über den Chipträger hinausragt und dazu genutzt werden kann, einen gewissen Abstand zwischen dem Chipträger und der Leiterplatte zu gewährleisten. Es kann jedoch auch vorgesehen sein, daß sich die Metallfolie in der Öffnung nicht ganz bis zum Rand der Öffnung und damit nicht ganz bis zur zweiten Oberfläche des Chipträgers erstreckt. Die leitende Verbindung zu der darunter anzu- bringenden Leiterplatte kann dadurch hergestellt werden, daß auf der Leiterplatte entsprechende Lötanschlüsse mit Lötmaterial vorgesehen werden, die beim Verlöten den verbleibenden Bereich der Öffnungen mit Lötmaterial ausfüllen.In the area of the second surface of the chip carrier, provision can be made for the metal foil to be flush with the second surface or for the metal foil to protrude from the opening beyond the second surface. In the latter case, the metal foil forms a contact which projects beyond the chip carrier and can be used to ensure a certain distance between the chip carrier and the printed circuit board. However, it can also be provided that the metal foil in the opening does not extend all the way to the edge of the opening and thus not all the way to the second surface of the chip carrier. The conductive connection to the circuit board to be attached underneath can be established by providing corresponding solder connections with solder material on the circuit board, which fill the remaining area of the openings with solder material during soldering.
Wie bereits erwähnt sollte der Chipträger aus einem möglichst stabilen und zuverlässigen Material bestehen. Prinzipiell kann dabei beispielsweise Keramik oder Metall Anwendung finden. Bevorzugt besteht der Chipträger jedoch aus einem Kunst - stofftape, beispielsweise aus Epoxyglas, Polyimid oder Poly- ester.
Für die Metallfolie werden entsprechend geeignete Metalle verwendet, wie beispielsweise Kupfer, Kupferlegierungen oder Eisen-Nickel -LegierungenAs already mentioned, the chip carrier should consist of the most stable and reliable material possible. In principle, for example, ceramic or metal can be used. However, the chip carrier preferably consists of a plastic tape, for example of epoxy glass, polyimide or polyester. Suitable metals are used for the metal foil, such as copper, copper alloys or iron-nickel alloys
Die Metallfolie kann beispielsweise dadurch in die Öffnungen des Chipträgers eingebracht werden, daß zunächst eine strukturierte Metallschicht auf den Chipträger auflamminiert wird, die anschließend durch einen Tiefziehprozeß oder einen Prägeprozeß in die Öffnungen des Chipträgers gezogen wird. Es kann auch vorgesehen sein, daß die Metallfolie bereits vor dem Auflaminieren vollständig strukturiert wird, so daß die Metallfolie nach dem Auflaminieren die Öffnungen bereits in der gewünschten Weise auskleidet und damit ein weiterer Prägeoder Tiefziehprozeß entbehrlich wird. Somit entsteht durch die geformte Metallfolie auf der Chipträger-Unterseite eine definierte Lötanschlußstelle für die Lötverbindung. Im Bereich der Chipträger-Oberseite kann die Metallfolie als definierte Kontaktierungsstelle für die elektrische Verbindung vom Halbleiterchip zum Chipträger genutzt werden.The metal foil can be introduced into the openings of the chip carrier, for example, by first laminating a structured metal layer onto the chip carrier, which is then drawn into the openings of the chip carrier by a deep-drawing process or an embossing process. It can also be provided that the metal foil is completely structured before the lamination, so that the metal foil already lines the openings in the desired manner after the lamination, and a further stamping or deep-drawing process is therefore unnecessary. The shaped metal foil on the underside of the chip carrier thus creates a defined solder connection point for the solder connection. In the area of the top of the chip carrier, the metal foil can be used as a defined contact point for the electrical connection from the semiconductor chip to the chip carrier.
Spezielle Ausführungsformen der vorliegenden Erfindung werden anhand der Figuren 1 bis 6 sowie der nachfolgenden speziellen Beschreibung erläutert.Special embodiments of the present invention are explained with reference to FIGS. 1 to 6 and the following special description.
Es zeigen:Show it:
Figur 1 ein Halbleiterbauelement mit Leadframe-Chipträger nach dem Stand der Technik.1 shows a semiconductor component with leadframe chip carrier according to the prior art.
Figur 2 ein Halbleiterbauelement mit Laminat -Chipträger nach dem Stand der Technik.Figure 2 shows a semiconductor device with laminate chip carrier according to the prior art.
Figur 3a ein Halbleiterbauelement mit einem Chipträger mit Öffnungen, die später durch eine Metallfolie ausge- kleidet werden.
Figur 3b ein Halbleiterbauelement nach Figur 3a, wobei dieFIG. 3a shows a semiconductor component with a chip carrier with openings which are later lined with a metal foil. Figure 3b shows a semiconductor device according to Figure 3a, the
Öffnungen bereits durch eine Metallfolie ausgekleidet sind.Openings are already lined with a metal foil.
Figur 4 ein Halbleiterbauelement nach Figur 3b, mit einer zusätzlichen Öffnung im Chipträger unterhalb des Halbleiterchips und einer Metallfolie zwischen Halbleiterchip und Chipträger bzw. Leiterplatte.FIG. 4 shows a semiconductor component according to FIG. 3b, with an additional opening in the chip carrier below the semiconductor chip and a metal foil between the semiconductor chip and the chip carrier or printed circuit board.
Figur 5 Beispiele für die Anordnung der Öffnungen bzw. Lötanschlußstellen .Figure 5 examples of the arrangement of the openings or solder connection points.
Figur 6 ein Halbleiterbauelement nach Figur 3b, jedoch mit Flipchip-Montagetechnik.Figure 6 shows a semiconductor device according to Figure 3b, but with flip chip assembly technology.
Figur 7 Draufsicht auf einen Chipträger mit Lötanschlußstel- len in Matrixanordnung mit Leiterwegen zu den ÖffnungenFIG. 7 top view of a chip carrier with solder connection points in a matrix arrangement with conductor paths to the openings
Figur 8 Draufsicht auf einen Chipträger mit einer Multichip- AnordnungFigure 8 top view of a chip carrier with a multichip arrangement
Figur 9 Anordnung nach Figur 3b, jedoch als Ball Grid Array und mit Wedge-Kontaktierung der MetallfolieFIG. 9 arrangement according to FIG. 3b, but as a ball grid array and with wedge contacting of the metal foil
Figur 10 Draufsicht auf ein Matrix Array mit mehreren Chipträgern mit Lötanschlußstellen am ChipträgerrandFIG. 10 top view of a matrix array with a plurality of chip carriers with solder connection points on the edge of the chip carrier
Figur 11 Schematischer Querschnitt durch eine Öffnung im Chipträger, ausgekleidet durch eine MetallfolieFigure 11 Schematic cross section through an opening in the chip carrier, lined with a metal foil
Der Stand der Technik, wie er in Figur 1 und 2 dargestellt ist, wurde bereits eingangs erläutert.The prior art, as shown in Figures 1 and 2, has already been explained at the beginning.
Figur 3a zeigt ein erfindungsgemäßes Halbleiterbauelement, das ein Kunststofftape 1 als Chipträger aufweist, auf dem ein Halbleiterchip 2 montiert ist. Der Halbleiterchip 2 und der
Chipträger 1 sind durch eine Klebeschicht 12 miteinander verbunden. Der Chipträger weist Öffnungen 20 auf, die sich von der ersten Oberfläche 8 des Chipträgers 1 bis zur zweiten Oberfläche 9 des Chipträgers 1 erstrecken. Die spätere Lage einer Metallfolie 7, die die Öffnungen 20 auskleiden soll, ist durch die punktierten Bereiche angedeutet.FIG. 3a shows a semiconductor component according to the invention, which has a plastic tape 1 as a chip carrier on which a semiconductor chip 2 is mounted. The semiconductor chip 2 and the Chip carriers 1 are connected to one another by an adhesive layer 12. The chip carrier has openings 20 which extend from the first surface 8 of the chip carrier 1 to the second surface 9 of the chip carrier 1. The later position of a metal foil 7, which is to line the openings 20, is indicated by the dotted areas.
In Figur 3b ist dargestellt, daß diese Öffnungen 20 mit einer Metallfolie 7 ausgekleidet sind, die sich über den Rand der Öffnungen 20 bis auf die erste Oberfläche 8 erstreckt. Auf der anderen Seite des Chipträgers 1 erstreckt sich die Metallfolie 7 bis zur zweiten Oberfläche 9 des Chipträgers. Die Metallfolie 7 füllt die Öffnung 20 des Chipträgers vollständig aus und dichtet diese somit ab.FIG. 3 b shows that these openings 20 are lined with a metal foil 7 which extends over the edge of the openings 20 to the first surface 8. On the other side of the chip carrier 1, the metal foil 7 extends to the second surface 9 of the chip carrier. The metal foil 7 completely fills the opening 20 of the chip carrier and thus seals it.
Zur Herstellung einer leitenden Verbindung zwischen dem Halbleiterchip 2 und der Metallfolie 7, die gleichzeitig eine Lötanschlußstelle 5 und eine Kontaktierungsstelle 6 bildet, sind Bonddrähte 3 vorgesehen. Zur Kontaktierung können dabei übliche Technologien wie Nailhead- und/oder Wedgekontaktie- rungen vorgesehen werden. Erfolgt dabei eine Kontaktierung der Metallfolie 7 im Innenraum der Öffnung 20, wie in Figur 3b dargestellt, so wird bevorzugt eine Erhöhung 16 im Innenraum der Öffnung 20 auf der Metallfolie 7 ausgebildet, z.B. ein sogenannter Gold-Bump, die eine Kontaktierung erleichtert. Auf dieser Erhöhung kann dann eine Kontaktierung mit den üblichen Verfahren erfolgen. So erfolgt beispielsweise im Fall der Figur 3b die Kontaktierung auf Seiten der Metallfolie 7 durch eine Wedge-Kontaktierung auf der zuvor eingefüg- ten Erhöhung 16.Bonding wires 3 are provided for establishing a conductive connection between the semiconductor chip 2 and the metal foil 7, which simultaneously forms a solder connection point 5 and a contacting point 6. Conventional technologies such as nailhead and / or wedge contacts can be provided for contacting. If the metal foil 7 is contacted in the interior of the opening 20, as shown in FIG. 3b, an elevation 16 is preferably formed on the metal foil 7 in the interior of the opening 20, e.g. a so-called gold bump, which facilitates contacting. On this increase, contact can then be made with the usual methods. For example, in the case of FIG. 3b, contact is made on the side of the metal foil 7 by wedge contacting on the elevation 16 previously inserted.
Wie Figur 7 schematisch zeigt, kann auch vorgesehen sein, daß von der Metallfolie 7 aus, die die Öffnungen 20 auskleidet, kurze Leiterwege 17 weggeführt werden, wobei eine Kontaktie- rung dann auf den Leiterwegen 17 erfolgt anstatt direkt auf der Metallfolie 7. Durch diese Maßnahme kann eine Entkopplung der Anforderungen an die Kontaktierung der Bonddrähte 3 für
die Verbindung zum Halbleiterchip 2 von den Anforderungen an die Metallfolie 7 erzielt werden, die somit getrennt voneinander optimiert werden können. Außerdem können durch diese Möglichkeit beispielsweise eine größere Zahl von Kontaktan- Schlüssen 6 für Bonddrähte 3 und Lötanschlußstellen 5 zur Leiterplatte hin auf dem Chipträger 1 untergebracht werden und man erhält mehr Freiheiten bei der Anordnung der Lötanschlußstellen 5 auf dem Chipträger 1. In Figur 7 sind die Öffnungen 20 bzw. die Lötanschlußstellen 5 in einer Matrix- form auf dem Chipträger 1 angebracht. Im rechten Teil der Figur ist eine Draufsicht auf die Unterseite 9 des Chipträgers 1 dargestellt, wobei die Lage des Halbleiterchips 2 auf der gegenüberliegenden Seite 8 des Chipträgers durch die gestrichelte Linie 19 angedeutet ist. Ein Teil der Öffnungen 20, in denen die Lötanschlußstellen 5 zur Leiterplatte hin ausgebildet sind, wäre also auf der gegenüberliegenden Seite durch den Halbleiterchip 2 überdeckt. Um trotzdem eine Kontaktierung zu ermöglichen, werden, wie im linken Teil der Figur 7 dargestellt, auf der Oberseite 8 des Chipträgers 1 die Lei- terwege 17 so angeordnet und mit den Metallfolien 7 in denAs schematically shown in FIG. 7, it can also be provided that short conductor paths 17 are led away from the metal foil 7 which lines the openings 20, contacting then taking place on the conductor paths 17 instead of directly on the metal foil 7 Measure can be a decoupling of the requirements for contacting the bonding wires 3 for the connection to the semiconductor chip 2 can be achieved by the requirements for the metal foil 7, which can thus be optimized separately from one another. In addition, this option allows, for example, a larger number of contact connections 6 for bonding wires 3 and solder connection points 5 to the circuit board to be accommodated on the chip carrier 1 and there is more freedom in the arrangement of the solder connection points 5 on the chip carrier 1. In FIG Openings 20 or the solder connection points 5 are arranged in a matrix form on the chip carrier 1. The right part of the figure shows a top view of the underside 9 of the chip carrier 1, the position of the semiconductor chip 2 on the opposite side 8 of the chip carrier being indicated by the dashed line 19. A part of the openings 20, in which the solder connection points 5 are formed towards the printed circuit board, would therefore be covered on the opposite side by the semiconductor chip 2. In order nevertheless to make contact, as shown in the left part of FIG. 7, the conductor paths 17 are arranged on the top 8 of the chip carrier 1 and with the metal foils 7 in the
Öffnungen 20 verbunden, daß die Leiterwege 17 unter dem Halbleiterchip 2 hervorragen und damit kontaktierbar sind. Diese Leiterwege 17 können dabei ebenfalls aus der Metallfolie 7 hergestellt sein, die zur Auskleidung der Öffnungen 20 ver- wendet wird, oder sie können auf übliche Weise hergestellt werden, beispielsweise durch eine zweite Metallfolie.Openings 20 connected so that the conductor paths 17 protrude below the semiconductor chip 2 and can thus be contacted. These conductor paths 17 can likewise be produced from the metal foil 7 which is used to line the openings 20, or they can be produced in the usual way, for example by means of a second metal foil.
Das Halbleiterbauelement ist zur Verkapselung mit einer Pressmasse 4 einseitig umpresst, die das Gehäuse des Halblei- terbauelementes bildet. Das Gehäuse 4 weist m Figur 3b senkrechte Seitenflanken auf, da in diesem Fall das Bauelement in einem Matrix Array umpreßt und anschließend z.B. durch Zersägen des Matrix Arrays aus dem Verbund herausgelöst wurde.The semiconductor component is encapsulated on one side for encapsulation with a molding compound 4, which forms the housing of the semiconductor component. The housing 4 has vertical side flanks in FIG. 3b, since in this case the component is pressed in a matrix array and subsequently e.g. was removed from the composite by sawing the matrix array.
Figur 4 zeigt eine alternative Ausführungsform des Halbleiterbauelements nach Figur 3b. Hierbei ist unter dem Halbleiterchip 2 eine weitere Öffnung 10 im Chipträger 1 vorgesehen.
Im Beispiel nach Figur 4 hat diese Öffnung 10 eine größere Ausdehnung als der Halbleiterchip 2. Es kann jedoch auch vorgesehen sein, daß unter dem Halbleiterchip 2 eine oder mehrere Öffnungen von kleinerer Ausdehnung als der Halbleiterchip 2 vorgesehen sind. Dies ist in der Draufsicht der Figur 5 auf einen Chipträger beispielhaft dargestellt. Die Öffnung 10 ermöglicht einen elektrischen Kontakt zu einem auf der Unterseite des Halbleiterchips befindlichen Anschluß, wie dies vor allem bei Einzelhalbleitern, z.B. Dioden, Transistoren, MOSFETS usw., üblich ist.FIG. 4 shows an alternative embodiment of the semiconductor component according to FIG. 3b. Here, a further opening 10 is provided in the chip carrier 1 under the semiconductor chip 2. In the example according to FIG. 4, this opening 10 has a larger extension than the semiconductor chip 2. However, it can also be provided that one or more openings of smaller extension than the semiconductor chip 2 are provided under the semiconductor chip 2. This is shown as an example in the top view of FIG. 5 on a chip carrier. The opening 10 enables electrical contact to a connection located on the underside of the semiconductor chip, as is customary above all in the case of single semiconductors, for example diodes, transistors, MOSFETS etc.
Im Beispiel nach Figur 4 wird zudem eine ganzflächige Wärmeableitung von der Unterseite des Halbleiterchips 2 durch die Metallfolie 10 zur Leiterplatte hin gewährleistet. Figur 5 a) zeigt eine Draufsicht auf die Öffnung 10, die größer ist als die Ausdehnung des Halbleiterchips 2. Wo eine solche ganzflächige Wärmeabfuhr jedoch nicht notwendig ist, kann auch eine nur partielle Wärmeabfuhr durch mehrere kleine Öffnungen 10, wie in Figur 5 b) dargestellt, vorgesehen sein. Diese mehreren Öffnungen sind auf dem Chipträger 1 so angeordnet, daß sie sämtlich von dem Halbleiterchip 2 nach dessen Montage bedeckt werden. Es können dabei alle Öffnungen 10 von einer durchgehenden Metallfolie 11 ausgekleidet sein oder es kann jeweils ein separates Stück Metallfolie 11 für jede der Öffnungen 10 vorgesehen werden. Für einen geringen elektrischen Widerstand ist eine möglichst große Überdeckung von dem Halbleiterchip und der Metallfolie wünschenswert.In the example according to FIG. 4, full-surface heat dissipation from the underside of the semiconductor chip 2 through the metal foil 10 to the printed circuit board is also ensured. FIG. 5 a) shows a plan view of the opening 10, which is larger than the extent of the semiconductor chip 2. However, where such full-surface heat dissipation is not necessary, only partial heat dissipation through several small openings 10, as in FIG. 5 b) shown, be provided. These multiple openings are arranged on the chip carrier 1 so that they are all covered by the semiconductor chip 2 after its assembly. All openings 10 can be lined with a continuous metal foil 11 or a separate piece of metal foil 11 can be provided for each of the openings 10. For a low electrical resistance, the greatest possible coverage of the semiconductor chip and the metal foil is desirable.
Weiterhin ist in Figur 4 eine alternative Form des Gehäuses 4 dargestellt, die abgeschrägte Seitenflanken aufweist. Hier wurde eine Einzelumpressung des Bauelementes mittels Einzel - kavitäten vorgenommen und anschließend zur Vereinzelung der Bauelemente eine Zertrennung des Chipträgers 1, z.B. durch Sägen, Stanzen, Fräsen, Laser, Wasserstrahl oder ähnliches vorgenommen.
Figur 6 zeigt ein Halbleiterbauelement nach Figur 3b, wobei jedoch keine Bonddrähte zur Herstellung einer leitenden Verbindung vom Halbleiterchip 2 zu den Kontaktierungsstellen 6 vorgesehen sind, sondern es erfolgt eine Montage des Halblei - terchips 2 in Flipchip-Technik, bei der die leitende Verbindung von der Unterseite des Halbleiterchips 2 ausgehend hergestellt wird. Dort sind Kontaktkugeln 13 vorgesehen, die in eine Unterfüllung 15 eingebettet sind. Von diesen Kontaktkugeln ausgehend werden Leiterzüge 14 zu den Metallfolien 7 ge- zogen. Diese Leiterzüge 14 können dabei ebenfalls aus der Metallfolie 7 hergestellt sein, die zur Auskleidung der Öffnungen 20 verwendet wird, oder sie können beispielsweise durch eine zweite Metallfolie hergestellt werden.Furthermore, an alternative form of the housing 4 is shown in Figure 4, which has beveled side flanks. Here, the component was pressed individually by means of individual cavities, and then, in order to separate the components, the chip carrier 1 was separated, for example by sawing, punching, milling, laser, water jet or the like. FIG. 6 shows a semiconductor component according to FIG. 3b, but no bond wires are provided for establishing a conductive connection from the semiconductor chip 2 to the contacting points 6, but instead the semiconductor chip 2 is assembled using flip-chip technology, in which the conductive connection is made by the Bottom of the semiconductor chip 2 is produced starting. Contact balls 13 are provided there, which are embedded in an underfill 15. Starting from these contact balls, conductor tracks 14 are drawn to the metal foils 7. These conductor tracks 14 can likewise be produced from the metal foil 7 which is used for lining the openings 20, or they can be produced, for example, by a second metal foil.
Figur 8 zeigt eine alternative Ausführungsform der Erfindung, bei der mehrere Halbleiterchips 2a, 2b auf einem gemeinsamem Chipträger in Form eines Multichip-Bauelements montiert sind. Dabei sind Bonddrähte 3a vorgesehen, die die Halbleiterchips 2a, 2b untereinander verbinden, sowie weitere Bonddrähte 3b zur Kontaktierung der Metallfolien 7 in den Öffnungen 20.FIG. 8 shows an alternative embodiment of the invention, in which a plurality of semiconductor chips 2a, 2b are mounted on a common chip carrier in the form of a multichip component. In this case, bond wires 3a are provided, which connect the semiconductor chips 2a, 2b to one another, and further bond wires 3b for contacting the metal foils 7 in the openings 20.
In Figur 9 ist eine weitere Alternative der Erfindung dargestellt, wobei auf der Unterseite des Chipträgers 1 Lötkugeln 18 auf die Metallfolien 7 aufgebracht sind, so daß eine Ball Grid Array-Anordnung (BGA) entsteht. Vorteil hierbei ist, daß dann vereinfachte Leiterplatten benutzt werden können, die keine Lötkontakte mehr aufweisen müssen. Figur 9 zeigt auch gleichzeitig eine bevorzugte Form der Drahtkkontaktierung der Bonddrähte 3 auf der Metallfolile 7, nämlich in Form einer Wedge-Kontaktierung in demjenigen Bereich der Metallfolie, die sich über den Rand der Öffnung 20 auf die obere Oberfläche 8 erstreckt.FIG. 9 shows a further alternative of the invention, solder balls 18 being applied to the metal foils 7 on the underside of the chip carrier 1, so that a ball grid array arrangement (BGA) is produced. The advantage here is that simplified circuit boards can then be used that no longer have to have solder contacts. FIG. 9 also simultaneously shows a preferred form of wire contacting of the bonding wires 3 on the metal foil 7, namely in the form of a wedge contact in the area of the metal foil which extends over the edge of the opening 20 onto the upper surface 8.
Für alle der genannten Ausführungsformen kann vorgesehen sein, daß die Metallfolie 7 bündig mit der zweiten Oberfläche 9 abschließt oder daß die Metallfolie 7 aus der Öffnung 20 über die zweite Oberfläche 9 hinausragt. Es kann jedoch auch
vorgesehen sein, daß sich die Metallfolie 7 m der Öffnung 20 nicht ganz bis zum Rand der Öffnung 20 und damit nicht ganz bis zur zweiten Oberfläche 9 des Chipträgers 1 erstreckt.For all of the above-mentioned embodiments, it can be provided that the metal foil 7 is flush with the second surface 9 or that the metal foil 7 protrudes from the opening 20 beyond the second surface 9. However, it can also it should be provided that the metal foil 7 m of the opening 20 does not extend completely to the edge of the opening 20 and thus not completely to the second surface 9 of the chip carrier 1.
Figur 11 zeigt einen Querschnitt durch eine Öffnung 20 m schematischer Form, wobei aus den Alternativen a) bis d) einige Beispiele deutlich werden, wie die Metallfolie 7 auf unterschiedliche Weise m der Öffnung 20 angeordnet sein kann. So kann sie sich nach Variante a) entlang der Seitenwände der Öffnung 20 erstrecken und im Bereich der unteren Oberfläche 9 des Chipträgers 1 einen weitgehend waagerechten oder auch leicht gekrümmten Abschluß bilden. Variante b) zeigt eine Metallfolie 7, die m der Öffnung 20 leicht gekrümmt verkeilt ist. In Variante c) entspricht die Ausdehnung der Metallfolie 7 gerade der Größe der Öffnung 20. Variante d) deutet eine Metallfolie 7 an, die bereits vor dem Auflaminieren auf den Chipträger 1 so strukturiert wurde, daß sie genau die Öffnung 20 auskleidet und damit lediglich m die Öffnung 20 im Rahmen des Auflaminierens als Art Stöpsel eingefügt wird.FIG. 11 shows a cross section through an opening 20 m in schematic form, some examples from alternatives a) to d) showing how the metal foil 7 can be arranged in a different way in the opening 20. Thus, according to variant a), it can extend along the side walls of the opening 20 and form a largely horizontal or slightly curved termination in the region of the lower surface 9 of the chip carrier 1. Variant b) shows a metal foil 7 which is wedged slightly curved in the opening 20. In variant c) the expansion of the metal foil 7 corresponds exactly to the size of the opening 20. Variant d) indicates a metal foil 7 which was structured before the lamination onto the chip carrier 1 in such a way that it lines the opening 20 exactly and thus only m the opening 20 is inserted as a kind of plug as part of the lamination process.
In Figur 10 ist eine besonders vorteilhafte Anordnung der Öffnungen 20 und damit der Lόtanschlußstellen 5 dargestellt. Die noch nicht vereinzelten Chipträger la bis le sind dabei m einem Matrix Array angeordnet, wobei die Linien 22 die zu- künftigen Ränder der Chipträger la bis le darstellen. Beim Vereinzeln der Chiptrager kann das Matrix Array entlang der Linien 22, wie bereits oben beschrieben, durch Stanzen, Zersägen etc. zerteilt werden. Die Öffnungen 20 und damit die Lötanschlußstellen 5 sind jeweils so an den Rändern der Chip- träger la bis le angeordnet, daß jeweils eine Lötanschluß- stelle eines Chipträgers, beispielsweise von Chiptrager la, einer Lötanschlußstelle eines angrenzenden Chipträgers, beispielsweise von Chipträger lb, gegenüberliegt und direkt an diese angrenzt. Die Öffnungen 20 für diese beiden Lόtan- schlußstellen 5 können damit m einem gemeinsamen Vorgang als eine einzige, etwa doppelt so lange Öffnung erzeugt werden, die sich über den Rand der Chipträger la, lb erstreckt. Eben-
so können diese beiden Öffnungen 20, die damit zunächst noch eine einzige Öffnung bilden, in einem gemeinsamen Schritt durch die Metallfolie 7 zur Bildung der Lötanschlußstellen 5 ausgekleidet werden. Es kann also durch die spezielle Anordnung nach Figur 10 beispielsweise ein einziger Stanz- und Prägevorgang zur Erzeugung von zwei zunächst noch verbundenen, nach dem Vereinzeln jedoch getrennten Lötanschlußstellen 5 genutzt werden, wodurch die Herstellung der Bauelemente wesentlich vereinfacht und beschleunigt wird.
FIG. 10 shows a particularly advantageous arrangement of the openings 20 and thus the solder connection points 5. The not yet separated chip carriers la to le are arranged in a matrix array, the lines 22 representing the future edges of the chip carriers la to le. When the chip carriers are separated, the matrix array can be cut along the lines 22, as already described above, by punching, sawing, etc. The openings 20 and thus the solder connection points 5 are each arranged at the edges of the chip carriers la to le in such a way that a solder connection point of a chip carrier, for example of chip carrier la, is opposite and a solder connection point of an adjacent chip carrier, for example of chip carrier 1b directly adjacent to this. The openings 20 for these two solder connection points 5 can thus be created in a common process as a single opening, approximately twice as long, which extends over the edge of the chip carriers 1 a, 1 b. Just- so these two openings 20, which initially still form a single opening, can be lined in a common step through the metal foil 7 to form the solder connection points 5. The special arrangement according to FIG. 10 means that, for example, a single stamping and embossing process can be used to produce two solder connection points 5 which are initially still connected, but separated after separation, whereby the manufacture of the components is considerably simplified and accelerated.
Claims
1. Halbleiterbauelement mit1. Semiconductor device with
- mindestens einem Halbleiterchip (2) , - einem Chipträger (1) zur Montage des Halbleiterchips (2) auf einer ersten Oberfläche (8) des Chipträgers (1) ,- at least one semiconductor chip (2), - a chip carrier (1) for mounting the semiconductor chip (2) on a first surface (8) of the chip carrier (1),
- Kontaktierungsstellen (6) , die mit dem Halbleiterchip (2) elektrisch verbunden sind und die eine leitende Verbindung durch Öffnungen (20) des Chipträgers (1) hindurch zu Lötan- schlußstellen (5) im Bereich einer zweiten Oberfläche (9) des Chipträgers (1) herstellen,- Contacting points (6) which are electrically connected to the semiconductor chip (2) and which have a conductive connection through openings (20) of the chip carrier (1) to solder connection points (5) in the region of a second surface (9) of the chip carrier ( 1) manufacture,
- einem Gehäuse (4), das zumindest den Halbleiterchip (2) umgibt, dadurch gekennzeichnet, daß die Lötanschlußstellen (5) durch eine Metallfolie (7) gebildet werden, die die Öffnungen (20) auskleidet und sich von der ersten Oberfläche (8) durch die Öffnungen (20) zur zweiten Oberfläche (9) hin erstreckt, daß die Lötanschlußstellen direkt kontaktierbar sind und daß zwischen Halbleiterchip (2) und Chipträger (1) eine weitere Metallfolie (11) vorgesehen ist, die mindestens eine Öffnung (11) im Chipträger (1) unter dem Halbleiterchip (2) auskleidet und sich von der ersten Oberfläche (8) durch die Öffnung (10) zur zweiten Oberfläche (9) erstreckt und eine Lötanschlußstelle bildet.- A housing (4) which surrounds at least the semiconductor chip (2), characterized in that the solder connection points (5) are formed by a metal foil (7) which lines the openings (20) and extends from the first surface (8) extends through the openings (20) to the second surface (9), that the solder connection points can be contacted directly and that a further metal foil (11) is provided between the semiconductor chip (2) and chip carrier (1), the at least one opening (11) in the Chip carrier (1) is lined under the semiconductor chip (2) and extends from the first surface (8) through the opening (10) to the second surface (9) and forms a solder connection point.
2. Halbleiterbauelement nach Anspruch 1, dadurch gekennzeichnet, daß die Metallfolie (7) einen Teil der ersten Oberfläche (8) bedeckt, der an die Öffnungen (20) angrenzt.2. Semiconductor component according to claim 1, characterized in that the metal foil (7) covers a part of the first surface (8) which is adjacent to the openings (20).
3. Halbleiterbauelement nach einem der Ansprüche 1 oder 2, dadurch gekennzeichnet, daß die Metallfolie (7) bündig mit der zweiten Oberfläche (9) abschließt.3. Semiconductor component according to one of claims 1 or 2, characterized in that the metal foil (7) is flush with the second surface (9).
4. Halbleiterbauelement nach einem der Ansprüche 1 oder 2, dadurch gekennzeichnet, daß die Metallfolie (7) aus der Öffnung (20) über die zweite Oberfläche (9) hinausragt.4. Semiconductor component according to one of claims 1 or 2, characterized in that the metal foil (7) protrudes from the opening (20) over the second surface (9).
5. Halbleiterbauelement nach einem der Ansprüche 1 oder 2 , dadurch gekennzeichnet, daß sich die Metallfolie (7) in der Öffnung (20) im Bereich der zweiten Oberfläche (9) nicht bis zum Rand der Öffnung (20) erstreckt.5. Semiconductor component according to one of claims 1 or 2, characterized in that the metal foil (7) in the opening (20) in the region of the second surface (9) does not extend to the edge of the opening (20).
6. Halbleiterbauelement nach einem der Ansprüche 1 bis5, dadurch gekennzeichnet, daß im Innenraum der Öffnungen (5) eine Erhebung (16) auf der Metallfolie (7) vorgesehen ist, die zur Kontaktierung der Me- tallfolie (7) dient.6. Semiconductor component according to one of claims 1 to 5, characterized in that an elevation (16) is provided on the metal foil (7) in the interior of the openings (5), which serves for contacting the metal foil (7).
7. Halbleiterbauelement nach einem der Ansprüche 1 bis 5, dadurch gekennzeichnet, daß die Metallfolie (7) auf der ersten Oberfläche (8) mit Leiterwegen (17) verbunden ist, die zur Kontaktierung der Metallfolie (7) dienen.7. Semiconductor component according to one of claims 1 to 5, characterized in that the metal foil (7) on the first surface (8) is connected to conductor paths (17) which serve to contact the metal foil (7).
8. Halbleiterbauelement nach einem der Ansprüche 1 bis 7, dadurch gekennzeichnet, daß die Öffnungen (20) am Rand des Chipträgers (1) angeordnet sind.8. Semiconductor component according to one of claims 1 to 7, characterized in that the openings (20) on the edge of the chip carrier (1) are arranged.
9. Halbleiterbauelement nach einem der Ansprüche 1 bis 8, dadurch gekennzeichnet, daß der Chipträger (1) aus einem Kunststofftape besteht.9. Semiconductor component according to one of claims 1 to 8, characterized in that the chip carrier (1) consists of a plastic tape.
10. Halbleiterbauelement nach Anspruch 9, dadurch gekennzeichnet, daß das Kunststofftape aus Epoxyglas, Polyimid oder Polyester besteht.10. A semiconductor device according to claim 9, characterized in that the plastic tape consists of epoxy glass, polyimide or polyester.
11. Halbleiterbauelement nach einem der Ansprüche 1 bis 10, dadurch gekennzeichnet, daß die Metallfolie (7) aus Kupfer, einer Kupferlegierung oder einer Eisen-Nickel-Legierung besteht.11. Semiconductor component according to one of claims 1 to 10, characterized in that the metal foil (7) consists of copper, a copper alloy or an iron-nickel alloy.
12. Halbleiterbauelement nach einem der Ansprüche 1 bis 11, dadurch gekennzeichnet, daß der Halbleiterchip (2) m Flipchip-Montagetechnik auf dem Chipträger (1) montiert ist.12. Semiconductor component according to one of claims 1 to 11, characterized in that the semiconductor chip (2) m flip chip assembly technology is mounted on the chip carrier (1).
13. Halbleiterbauelement nach einem der Ansprüche 1 bis 12, dadurch gekennzeichnet, daß das Gehäuse (4) aus einer Preßmasse besteht, die in einer Emzelumpressung oder m einer Matrix-Array-Umpressung einseitig um den Halbleiterchip 2 gepreßt wurde. 13. Semiconductor component according to one of claims 1 to 12, characterized in that the housing (4) consists of a molding compound which was pressed on one side around the semiconductor chip 2 in an Emzelumpressung or m a matrix array pressing.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE19905055 | 1999-02-08 | ||
DE19905055A DE19905055A1 (en) | 1999-02-08 | 1999-02-08 | Semiconductor component with a chip carrier with openings for contacting |
PCT/DE2000/000328 WO2000048249A1 (en) | 1999-02-08 | 2000-02-03 | Semiconductor component with a chip carrier with openings for contacting |
Publications (1)
Publication Number | Publication Date |
---|---|
EP1155449A1 true EP1155449A1 (en) | 2001-11-21 |
Family
ID=7896773
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP00912347A Withdrawn EP1155449A1 (en) | 1999-02-08 | 2000-02-03 | Semiconductor component with a chip carrier with openings for contacting |
Country Status (4)
Country | Link |
---|---|
US (1) | US6528877B2 (en) |
EP (1) | EP1155449A1 (en) |
DE (1) | DE19905055A1 (en) |
WO (1) | WO2000048249A1 (en) |
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Also Published As
Publication number | Publication date |
---|---|
WO2000048249A1 (en) | 2000-08-17 |
US6528877B2 (en) | 2003-03-04 |
DE19905055A1 (en) | 2000-08-17 |
US20020041014A1 (en) | 2002-04-11 |
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