JPH0258793B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to semiconductor devices, and more particularly to improvements in the structure and method for bonding an assembly in which a semiconductor device storage container is bonded to a wiring substrate by interconnection pads.

A well-known type of package or assembly for highly integrated semiconductor ICs is called a chip carrier, which is a container that encloses an IC element, usually made of ceramic, and interconnection pads formed by a metallized pattern. This is of a type that is soldered to a wiring base (motherboard), usually made of ceramic, which has connection pins for mounting on a printed circuit board. The chip carrier and the wiring base are bonded by applying solder to at least one of the interconnection pads provided on each pad by a method such as soldering or printing, thereby forming a so-called solder bulge in advance. This is then done by superimposing the two and subjecting them to heat treatment.
This conventional technique has the disadvantage that the amount of solder attached to the pads is not constant, and insufficient or excessive solder often results in incomplete interconnections or short spots between adjacent pads. Ta. In particular, the chip carrier format is often used for the purpose of high-density mounting of highly integrated ICs.
It has become necessary to have a large number of minute pads of several hundred square micrometers densely packed on the interconnection surface, and the number of defects due to the above-mentioned causes tends to increase more and more.

Therefore, the present invention eliminates the above-mentioned problems caused by incomplete connections or shorts when joining the semiconductor storage container and the wiring board by soldering the interconnection pads, and also simplifies the manufacturing process. The aim is to provide a structure and manufacturing method that can be used to

The main features of the present invention are that an insulating plate is interposed between the container and the wiring substrate, and this insulating plate is provided with holes through which solder passes through the interconnections between the corresponding pads, and the manufacturing method thereof The above feature is to prepare a connection insulating plate that has through holes at positions corresponding to each interconnection part and insert solder into the through holes, and to sandwich this between the container and the wiring base. The process involves heat-treating the stacked layers and joining them together.

The present invention will be explained in detail below using examples.

FIG. 1 is a diagram showing an example of a method for manufacturing a connection insulating plate used in the present invention. As the insulating plate 1, a heat-resistant resin sheet (for example, 100 μm in thickness) such as polyimide is used, and through holes 2 are formed in the sheet 1 at positions corresponding to the pattern of interconnection pads between the container and the wiring board. is formed by punching. On the other hand, solder balls 3 with a diameter of about 500 μm are formed in advance, placed over the through holes 2 as shown in FIG. Press fit. Reference numeral 4 denotes a press-fitting aid, which is formed with a recess 5 for receiving the solder ball 3, so that the solder ball 3 is press-fitted into the through hole as shown in FIG. 1b without being crushed.

The solder ball 3 is sized to accommodate an appropriate amount of solder for one interconnection portion.

Once the heat-resistant sheet 1 for interconnection as shown in FIG. 1b is prepared, it is attached to the container 10 as shown in FIG.
and the wiring base 20 and overlap each other. In FIG. 2, reference numeral 11 denotes an interconnection pad on the side of the container 10, which is printed with, for example, gold paste. Ceramic container 10
In this example, is a typical chip carrier type, 12 is an encapsulated IC element, 13 is a lead wire, and 14 is a sealing cap plate made of Kovar. Since the present invention is not concerned with the internal structure of this chip carrier, details are omitted. 2
Reference numeral 1 denotes an interconnection pad provided on the wiring base (motherboard) 20 side. The detailed structure of the wiring base 20 is also omitted, but this is a base made of ceramic, for example, and has a single or multilayer metallized wiring layer formed by screen printing. It is equipped with a connecting pin.

When the insulating sheet 1, the container 10, and the wiring base 20 are heat-treated in a stacked state as shown in FIG. 2a, the solder balls 3 are melted and alloyed with the respective pads 11 and 21, so that they mutually interact as shown in FIG. 2b. A connection is made. Here, it is easier to make a fixed amount of each solder ball 3 compared to the conventional method of creating a solder ball by soldering or printing, and an appropriate amount of solder is always applied to each interconnection pad. Therefore, good solder connections can be made with good reproducibility on all pads. Moreover, insulation sheet 1
Because it has poor wettability with solder, it suppresses the spread of molten solder to the surrounding area, and also prevents the container 10 and the wiring board 20 from spreading.
It can also be expected to act as a spacer to keep the distance between pads constant, and thereby prevent shortening between adjacent pads due to the spread of excess solder.

As described above, according to the present invention, since the appropriate amount of solder can always be applied to each interconnection pad, it is possible to reduce shorts and poor connection accidents caused by excess or shortage of solder, which have been experienced in the past. Furthermore, by interposing the insulating plate, the distance between the opposing pads of the interconnection portion is always kept constant, making it possible to realize bonding with good reproducibility. In the manufacturing process as well, in the present invention, if the insulating plates for interconnection are prepared separately in advance, the bonding process itself can be shortened compared to the conventional method, and the time required for the assembly process can be shortened.

In addition to the solder sheet shown in FIG. 1 explained in the above embodiment, the solder sheet for connection may be one in which rivet-type solder is inserted and fixed into a through hole provided in a heat-resistant insulating sheet, or An eyelet or rivet made of a highly conductive metal such as copper may be fixed in the through hole of an insulating sheet, and solder may be applied in a hemispherical shape to the front and back sides of the eyelet or rivet.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a manufacturing process of an interconnection insulating plate used in an embodiment of the present invention, and FIG. 2 is a diagram showing a semiconductor device and its manufacturing process in an embodiment of the present invention. DESCRIPTION OF SYMBOLS 1... Insulating plate, 3... Solder ball, 10... Semiconductor element storage container, 11, 21... Interconnection pad, 20... Wiring base.

Claims (1)

[Scope of Claims] 1. In an apparatus in which connection pads are provided corresponding to a container for housing a semiconductor element and a wiring base on which the container is mounted, and the corresponding pads are interconnected by solder, An insulating plate is interposed between the pad and the wiring substrate, and the insulating plate has holes formed at each interconnection portion through which solder for interconnecting each of the corresponding pads passes. . 2. Connecting pads corresponding to the container housing the semiconductor element and the wiring base on which the container is mounted are provided, respectively, and the corresponding pads are interconnected by solder to join the container to the wiring base. In this case, a connection insulating plate having through holes at positions corresponding to each interconnection part and solder inserted into the through holes is interposed between the container and the wiring base, and heat treatment is performed. 1. A method for manufacturing a semiconductor device, which comprises bonding the two together.