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Claims  |
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What is claimed is:
1. A manufacturing method for a supermicro-connector, comprising:
a step of fixing a plurality of conductor wires, arranged substantially
parallel to one another, by means of an elastic insulator interposed
between the conductor wires, thereby making a composite structure formed
of the conductor wires and the insulator;
a step of cutting the composite structure along a plane extending at right
angles to the conductor wires, thereby making a plurality of composite
chips;
a step of removing the insulator from at least one cut surface of each of
the composite chips by dissolution by means of an agent, thereby exposing
respective end portions of the conductor wires for a predetermined length;
and
a step of forming solder bumps individually on the respective exposed end
portions of the conductor wires.
2. A manufacturing method for a supermicro-connector according to claim 1,
further comprising a step of further removing the insulator on the side
for the formation of the solder bumps by dissolution by means of the
agent, thereby exposing the conductor wires for a predetermined length
between the solder bumps and the insulator, after the step of forming the
solder bumps on the exposed end portions of the conductor wires.
3. A manufacturing method for a supermicro-connector according to claim 1,
wherein said elastic insulator is an expanded silicone rubber.
4. A manufacturing method for a supermicro-connector according to claim 2,
wherein said elastic insulator is an expanded silicone rubber.
5. A manufacturing method for a supermicro-connector according to claim 1,
wherein each said conductor wire is formed, on the surface thereof, with a
number of linear or spiral channels each having an opening with a width
smaller than that of the inner part thereof.
6. A manufacturing method for a supermicro-connector according to claim 2,
wherein each said conductor wire is formed, on the surface thereof, with a
necessary number of linear or spiral channels each having an opening with
a width smaller than that of the inner part thereof.
7. A manufacturing method for a supermicro-connector according to claim 1,
wherein each said conductor wire is a stranded wire or a composite wire
formed by joining and bonding a plurality of wires together so that the
surface of the conductor wire is rugged.
8. A manufacturing method for a supermicro-connector according to claim 2,
wherein each said conductor wire is a stranded wire or a composite wire
formed by joining and bonding a plurality of wires together so that the
surface of the conductor wire is rugged.
9. A manufacturing method for a supermicro-connector according to claim 1,
wherein each said conductor wire is a composite wire formed of a core
member erodible by a specific corrosive agent and a covering member not
erodible by the corrosive agent.
10. A manufacturing method for a supermicro-connector according to claim 2,
wherein each said conductor wire is a composite wire formed of a core
member erodible by a specific corrosive agent and a covering member not
erodible by the corrosive agent.
11. A manufacturing method for a supermicro-connector according to claim 1,
wherein said conductor wires are bonded to the elastic insulator by means
of an adhesive agent.
12. A manufacturing method for a supermicro-connector according to claim 2,
wherein said conductor wires are bonded to the elastic insulator by means
of an adhesive agent.
13. A manufacturing method for a supermicro-connector according to claim 1,
wherein said plurality of conductor wires are laminated into a plurality
of parallel conductor wire rows arranged at predetermined intervals under
a tension applied by means of a plurality of members having different
heights and formed with a plurality of V-grooves arranged at regular
pitches, in said step of fixing the plurality of conductor wires, arranged
substantially parallel to one another, by means of the elastic insulator
interposed between the conductor wires, thereby making the composite
structure formed of the conductor wires and the insulator.
14. A manufacturing method for a supermicro-connector according to claim 2,
wherein said plurality of conductor wires are laminated into a plurality
of parallel conductor wire rows arranged at predetermined intervals under
a tension applied by means of a plurality of members having different
heights and formed with a plurality of V-grooves arranged at regular
pitches, in said step of fixing the plurality of conductor wires, arranged
substantially parallel to one another, by means of the elastic insulator
interposed between the conductor wires, thereby making the composite
structure formed of the conductor wires and the insulator.
15. A manufacturing method for a supermicro-connector according to claim
13, wherein each said conductor wire is subjected to a tension by means of
a weight attached to an end portion thereof.
16. A manufacturing method for a supermicro-connector according to claim
14, wherein each said conductor wire is subjected to a tension by means of
a weight attached to an end portion thereof.
17. A manufacturing method for a supermicro-connector according to claim
13, wherein said lamination intervals between the parallel conductor wire
rows are adjusted by means of spacers interposed between the wire rows.
18. A manufacturing method for a supermicro-connector according to claim
14, wherein said lamination intervals between the parallel conductor wire
rows are adjusted by means of spacers interposed between the wire rows.
19. A manufacturing method for a supermicro-connector according to claim
15, wherein said lamination intervals between the parallel conductor wire
rows are adjusted by means of spacers interposed between the wire rows.
20. A manufacturing method for a supermicro-connector according to claim
16, wherein said lamination intervals between the parallel conductor wire
rows are adjusted by means of spacers interposed between the wire rows.
21. A manufacturing method for a supermicro-connector according to claim 1,
wherein said elastic insulator is a condensed-type silicone rubber.
22. A manufacturing method for a supermicro-connector according to claim 2,
wherein said elastic insulator is a condensed-type silicone rubber.
23. A manufacturing method for a supermicro-connector according to claim 1,
wherein the respective end portions of the conductor wires are exposed
from both cut surfaces of each of the composite chips, those end portions
of the conductor wires which are exposed from one of the cut surfaces are
connected electrically to a metallic electrode plate, and the solder bumps
are formed individually, by electroplating, on those end portions of the
conductor wires which are exposed from the other cut surface, in the step
of removing the insulator from at least one cut surface of each of the
composite chips by dissolution by means of the agent, thereby exposing the
respective end portions of the conductor wires for the predetermined
length, and the step of forming the solder bumps individually on the
respective exposed end portions of the conductor wires.
24. A manufacturing method for a supermicro-connector according to claim 2,
wherein the respective end portions of the conductor wires are exposed
from both cut surfaces of each of the composite chips, those end portions
of the conductor wires which are exposed from one of the cut surfaces are
connected electrically to a metallic electrode plate, and the solder bumps
are formed individually, by electroplating, on those end portions of the
conductor wires which are exposed from the other cut surface, in the step
of removing the insulator from at least one cut surface of each of the
composite chips by dissolution by means of the agent, thereby exposing the
respective end portions of the conductor wires for the predetermined
length, and the step of forming the solder bumps individually on the
respective exposed end portions of the conductor wires.
25. A manufacturing method for a supermicro-connector according to claim
23, wherein electrically conductive paste is applied to the one cut
surface of each of the composite chip along with the exposed conductor
wires, the surface of the paste is coated for insulation, and the
conductor wires exposed from the one cut surface and the conductive paste
are brought into contact with a conductor connected to a power source, to
be supplied with electric power, whereby the solder bumps are formed by
electroplating on the conductor wires exposed from the other cut surface.
26. A manufacturing method for a supermicro-connector according to claim
24, wherein electrically conductive paste is applied to the one cut
surface of each of the composite chip along with the exposed conductor
wires, the surface of the paste is coated for insulation, and the
conductor wires exposed from the one cut surface and the conductive paste
are brought into contact with a conductor connected to a power source, to
be supplied with electric power, whereby the solder bumps are formed by
electroplating on the conductor wires exposed from the other cut surface.
27. A manufacturing method for a supermicro-connector according to claim 1,
wherein said plurality of conductor wires are gold wires or gilt conductor
wires.
28. A manufacturing method for a supermicro-connector according to claim 2,
wherein said plurality of conductor wires are gold wires or gilt conductor
wires.
29. A manufacturing method for a supermicro-connector according to claim 1,
wherein the surface of each said conductor wire is roughened by an
electrolytic treatment or chemical etching.
30. A manufacturing method for a supermicro-connector according to claim 2,
wherein the surface of each said conductor wire is roughened by an
electrolytic treatment or chemical etching. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a manufacturing method for
supermicro-connectors capable of connecting electrodes of semiconductor
chips and circuit boards electrically to one another with high
reliability.
2. Description of the Related Art
Semiconductor chips are formed each with a large number of electrodes
arranged at fine pitches. With the progress of high-integration versions
of circuits, the number of electrodes used in each chip is increasing
steadily. Dual in-line packages (DIPs) which use lead frames had been
prevalent means for electrical connection between the electrodes of the
semiconductor chips and external equipment. As the electrodes of each chip
increased in number and came to require latticed or multilayer
arrangement, however, the conventional DIPs of the lead-frame type ceased
to be effective connecting means.
In the case where a large number of electrodes are used in each
semiconductor chip, therefore, the bare chip packaging method (also
referred to as chip-on-board method or flip chip method) is employed.
According to this method, the electrodes of each semiconductor chip and
electrodes of a circuit board, which are as many as those of the chip and
are arranged at pitches equal to the arrangement pitches of the chip
electrodes, are connected by reflow soldering using solder balls, whereby
the semiconductor chip is mounted directly on the circuit board.
In this bare chip packaging method, however, the electrodes of the
semiconductor chip and the circuit board are connected directly to one
another by means of the solder balls. As the temperature rises during use,
therefore, the circuit board, having the semiconductor chip mounted
directly thereon by this method, is subjected to thermal strain which is
attributable to the difference in thermal expansion between the chip and
the board. This thermal strain would be concentrated on soldered regions
to damage them, thereby causing connection failure.
SUMMARY OF THE INVENTION
The object of the present invention is to provide a manufacturing method
for supermicro-connectors (hereinafter referred to as "SMCs") with
excellent connecting performance and high reliability, capable of
satisfactorily connecting electrodes of semiconductor chips and circuit
boards without involving any substantial connection failure.
In order to achieve the above object, a manufacturing method for an SMC
according to claim 1 comprises: a step of fixing a plurality of conductor
wires, arranged substantially parallel to one another, by means of an
elastic insulator interposed between the conductor wires, thereby making a
composite structure formed of the conductor wires and the insulator; a
step of cutting the composite structure along a plane extending at right
angles to the conductor wires, thereby making a plurality of composite
chips; a step of removing the insulator from at least one cut surface of
each of the composite chips by dissolution by means of an agent, thereby
exposing the respective end portions of the conductor wires for a
predetermined length; and a step of forming solder bumps individually on
the respective exposed end portions of the conductor wires.
According to the method of the present invention, high-reliability SMCs can
be manufactured such that the solder bumps formed individually on the
conductor wires are uniform in shape, the bonding strength between the
electrodes and the conductor wires is high, thermal strain can be absorbed
during use, and hence, the connection between the electrodes of the
semiconductor chips and the circuit boards is highly reliable. Thus, the
method of the invention can produce outstanding industrial effects.
The above and other objects, features, and advantages of the invention will
be more apparent from the ensuing detailed description taken in connection
with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1A, 1B, 1C, 1D, 1E and 1F are process diagrams for roughly
illustrating a manufacturing method for a supermicro-connector according
to the present invention;
FIGS. 2A, 2B 2C and 2D are perspective views showing the shapes of
conductor wires used in the method of the invention;
FIGS. 3A and 3B are perspectives views showing a conductor wire used in the
method of the invention, an end portion of the wire being eroded by means
of a corrosive agent;
FIG. 4 is a longitudinal sectional view of a supermicro-connector using the
conductor wire of FIG. 3B, showing a state after soldering;
FIGS. 5A, 5B, 5C, 5D, 5E and 5F are process diagrams for illustrating the
way a semiconductor chip and a circuit board are connected by means of the
supermicro-connector manufactured by the method of the invention;
FIG. 6 is a front view showing another embodiment of the
supermicro-connector manufactured by the method of the invention;
FIGS. 7A and 7B are views illustrating the way a plurality of conductor
wires are stretched by means of V-grooved bridges; and
FIG. 8 is a sectional view illustrating the way solder bumps are formed on
a plurality of conductor wires of a composite chip by electroplating.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring now to FIGS. 1A to 1F, a manufacturing method for an SMC
according to the present invention will be described in detail.
First, a large number of conductor wires 2 are stretched in a predetermined
pattern in a square metallic pipe 1 with high-accuracy dimensions so as to
extend substantially parallel to the axis of the pipe 1. A liquid
insulator 3 is injected into the square pipe 1 and solidified therein.
Thereupon, a composite structure 4 is formed including a number of
substantially parallel conductor wires 2 which are fixed by means of the
insulator 3 (FIG. 1A).
Then, the composite structure 4 is drawn out of the square pipe 1 (FIG.
1B), and is cut along a plane F which extends at right angles to the
conductor wires 2, whereupon a thin composite chip 5 with a predetermined
thickness is obtained (FIG. 1C).
Subsequently, the insulator 3 is dissolvingly removed from the composite
chip 5 through cut surfaces 5a and 5b thereof by means of an agent,
whereby the respective end portions of the conductor wires 2 are exposed
for a predetermined length each (FIG. 1D).
An SMC 10 is manufactured by collectively forming substantially spherical
solder bumps 6 individually on the respective one-side end portions of the
exposed conductor wires 2 (FIG. 1E).
In FIGS. 1C, 1D, 1E and 1F, the illustrated conductor wires 2 are limited
to four in number for simplicity. Also in FIGS. 5, 6, 7 and 8 which will
be mentioned later, illustration of most of the conductor wires 2 is
omitted for the same reason.
In a method according to claim 1, the insulator used should preferably have
a coefficient of thermal expansion which is intermediate between those of
a semiconductor chip and a circuit board. The insulator of this type can
prevent the solder bumps from being subjected to thermal strain which is
attributable to the difference in the coefficient of thermal expansion
from the semiconductor chip or the circuit board, and hence, from lowering
the electrical connection performance.
A method according to claim 2 is a manufacturing method for an SMC, which
comprises a step of further dissolvingly removing the insulator on the
side for the formation of the solder bumps by means of the agent, thereby
exposing the conductor wires for a predetermined length between the solder
bumps and the insulator, after the step of forming the solder bumps on the
exposed end portions of the conductor wires.
In the method according to claim 2, the insulator 3 on the side for the
formation of the solder bumps 6 is further removed from the SMC 10 shown
in FIG. 1E by means of the agent, whereby an SMC 11 with its conductor
wires 2 exposed is manufactured (FIG. 1F).
In the SMC 11 manufactured by the method according to claim 2, the
conductor wires 2 are exposed for the predetermined length between the
solder bumps 6 and the insulator 3. When electrodes of the semiconductor
chip or the circuit board are connected by soldering, thermal strain may
be caused by the difference in the coefficient of thermal expansion
between the insulator and the semiconductor chip or the circuit board.
Even in such a case, according to this SMC 11, the thermal strain is
absorbed by deformation of the exposed portions of the conductor wires,
and the exposedness of the wires ensures improved heat radiation property.
The reason why an elastic insulator is used as the insulator to be
interposed between the conductor wires according to the method of the
present invention is that a thermal stress produced by soldering between
the SMC and the electrodes of the semiconductor chip or the circuit board
is absorbed by deformation of the insulator, so that the deformation of
the conductor wires attributable to change of the distance between the
electrodes or thermal expansion is not likely to be inhibited, and hence,
high connectibility between the electrodes can be maintained.
Silicone rubber or polymeric elastomer may be suitably used as the elastic
insulator. In particular, expanded silicone rubber is liable to less
deformation by thermal expansion. A connector is interposed between the
semiconductor chip and the circuit board, the respective electrodes of the
semiconductor chip and the circuit board and conductor wires of the
connector are aligned with another and are then soldered together by
heating. In doing this, the electrodes and the conductor wires cannot be
dislocated.
The size of the solder bumps depends on the length of those portions of the
conductor wires which are exposed from at least one cut surface of the
composite chip. The bumps are formed on the exposed end portions of the
conductor wires by a conventional method, e.g., by dipping the end
portions in a solder bath or applying solder paste to the end portions by
means of a brush. The length of those portions of the wires which are
further exposed between the solder bumps and the insulator, after the
bumps are formed in this manner, is a length such that the connection
between the exposed conductor wires and the semiconductor chip or between
the wires and the circuit board by soldering or the like is easy, and is
changed variously depending on the material used.
Preferably, the length of the exposed portions of the conductor wires
before the formation of the solder bumps range from 0.02 to 0.1 mm. If
this length is shorter than 0.02 mm, solder bumps of an adequate size
cannot be formed. If the length of exposure of the wires is longer than
0.1 mm, on the other hand, solder bumps of a proper shape, substantially
spherical, cannot be formed.
In the case where the conductor wires are further exposed after the
formation of the solder bumps, in contrast with this, their length of
exposure should preferably be not shorter than 0.2 mm. If this length is
shorter than 0.2 mm, it is impossible to secure a space in which a
positioning jig is used to solder the wires to the semiconductor chip and
the circuit board. Thus, the soldering operation is difficult, and the
accuracy of positioning on the semiconductor chip and the circuit board is
lowered.
The solder used for the formation of the bumps may be selected among ones
for low-temperature use, such as Bi--In, In, Bi--Sn solders, as well as
Sn--Pb solder, pure Sn, etc. which are employed usually. In the case where
silicone rubber is used as the insulator, however, solders with the
melting point of 320.degree. C. or more cannot be used in consideration of
the heat resistance of silicone rubber.
A commercially available agent is used as the agent for dissolvingly
removing the insulator. If the insulator is silicone rubber, for example,
a substantially linear relationship is established between the amount of
dissolution and lapse of time, and a 2-methoxyethanol solvent is used
whereby the removal of the insulator can be easily controlled with time.
Any electrically conductive material may be applied to the conductor wires
which are used according to the method of the present invention. More
specifically, phosphor bronze, Cu--Be alloy, nickel silver, Corson alloy,
or other copper alloy material is available. Each conductor wire may be a
round wire (FIG. 2A), square wire, stranded wire combining these wires, or
shaped wire.
While the coefficient of thermal expansion of a metal material which
constitutes the conductor wires is 10.degree. to
20.degree..times.10.sup.-6 /.degree. C., that of silicone rubber is as
high as 200.degree. to 300.degree..times.10.sup.-6 /.degree. C. In the
case where silicone rubber is used as the insulator, therefore, the
insulator is expanded by a temperature rise during the formation of the
solder bumps, and is liable to be separated from the conductor wires. As a
result, the force of the insulator (silicone rubber) to hold the wires is
reduced, so that the wires can be easily disengaged from the insulator
during the manufacture of the SMC. To avoid this, it is advisable to give
the conductor wires a shape such that they cannot be easily separated from
the insulator.
FIG. 2B shows a shaped conductor wire 2 as an example of a wire which is
shaped so as not to be easily separated from the insulator. This wire is
provided thereon with a necessary number of channels 2a whose opening is
narrower than their inside space. With use of this shaped wire, the
insulator gets into the channels 2a, so that the area of contact with the
wire is wide. As the temperature rises during the use of the SMC,
therefore, the insulator expands so that it is clamped fast to the regions
in- and outside the channels 2a. If the shaped wire is twisted so that the
channels 2a are spiral in shape, the conductor wires can be restrained
from longitudinally shifting its position in the insulator.
Also in the case of a conductor wire 2 formed of a stranded wire shown in
FIG. 2C, its area of contact with the insulator can be made wide, and the
stranded wire is twisted in the longitudinal direction. Thus, the
longitudinal shift of the conductor wire can be restrained. In a conductor
wire 2 shown in FIG. 2D, square wires are joined together so that the
surface of the resulting structure is rugged. In this case, the contact
area is wider than in the case of the conventional stranded wire shown in
FIG. 2C, so that the movement of the conductor wire can be restrained more
positively.
Dislocation of the conductor wires can be restrained more securely if the
insulator and the conductor wires are bonded by means of an adhesive
agent. Preferably, the adhesive agent should be a primer which can bond a
metal material, silicone rubber, etc. In bonding the insulator and the
conductor wires, the primer is applied to the wires in advance.
In order to form the solder bumps steadily into a predetermined shape,
according to the method of the present invention, it is advisable to use a
conductor wire 2 shown in FIGS. 3A and 3B. The wire 2 is a composite wire
(FIG. 3A) which is composed of a core member 2b and a covering member 2c.
The core member 2b is formed of a material which is erodible by a specific
corrosive liquid, while the covering member 2c is formed of a material
which is not erodible. When an end portion of this wire 2 is dipped into
the corrosive liquid, the core member 2b is eroded so that a cup-shaped
depression 2d is formed in its top portion (FIG. 3B). When the top portion
of the member 2b is dipped into a solder bath, solder solidifies in the
depression 2d. The shape of the depression 2d can be freely changed
depending on the conditions of corrosion.
A method according to claim 13 or 14 is a manufacturing method for an SMC,
in which a plurality of conductor wires are laminated into a plurality of
parallel conductor wire rows arranged at predetermined intervals under a
tension applied by means of a plurality of members having different
heights and formed with a plurality of V-grooves arranged at regular
pitches, in the step of fixing the plurality of conductor wires, arranged
substantially parallel to one another, by means of the elastic insulator
interposed between the conductor wires, thereby making the composite
structure formed of the conductor wires and the insulator.
In the manufacturing method according to claim 13 or 14, the conductor
wires are positioned by utilizing the V-grooves, so that the operation is
easy. The conductor wires can be accurately positioned with respect to the
direction of their arrangement by using V-grooved bridges, which are
obtained by rectangularly cutting an iron block having V-grooves arranged
at regular pitches thereon.
The tension can be easily applied to each conductor wire by pulling it by
means of a weight which is attached to an end portion thereof. The
lamination intervals between the parallel conductor wire rows can be
accurately adjusted by means of spacers interposed between the wire rows.
A method according to claim 21 or 22 is a manufacturing method for an SMC,
in which the elastic insulator is formed of a condensed-type silicone
rubber.
Since silicone rubber has high heat resistance and flux resistance, the
insulator can appropriately stand the environment for soldering. Since
silicone rubber can dissolve relatively stably in an agent, moreover, the
length of exposure of the conductor wires can be made uniform. An
additional-type silicone rubber with a high degree of polymerization,
among other types, requires a long time for dissolution, and may swell and
get out of shape during dissolution, in some cases. In contrast with this,
a condensed-type silicone rubber, which has a low degree of polymerization
and contains a relatively large quantity of filler, dissolves uniformly in
a short period of time, so that it can be a suitable material for the
insulator.
A method according to claim 23 or 24 is a manufacturing method for an SMC,
in which the respective end portions of the conductor wires are exposed
from both cut surfaces of each of the composite chips, those end portions
of the conductor wires which are exposed from one of the cut surfaces are
connected electrically to a metallic electrode plate, and the solder bumps
are formed individually, by electroplating, on those end portions of the
conductor wires which are exposed from the other cut surface, in the step
of dissolvingly removing the insulator from at least one cut surface of
each of the composite chips by means of the agent, thereby exposing the
respective end portions of the conductor wires for the predetermined
length, and the step of forming the solder bumps individually on the
respective exposed end portions of the conductor wires.
The solder bumps are formed on the respective end portions of the conductor
wires which are exposed from each composite chip, and the semiconductor
chip or the circuit board is connected to the bumps.
It is difficult to form large solder bumps by the hot dip method. However,
the electroplating method can produce solder bumps of any desired size and
uniform shape.
A method according to claim 25 or 26 is a manufacturing method for an SMC,
in which electrically conductive paste is applied to the one cut surface
of each of the composite chip along with the exposed conductor wires, the
surface of the paste is coated for insulation, and the conductor wires
exposed from the one cut surface and the conductive paste are brought into
contact with a conductor connected to a power source, to be supplied with
electric power, whereby the solder bumps are formed by electroplating on
the conductor wires exposed from the other cut surface.
The conductive paste used may, for example, be resin paste in which copper
or silver powder is dispersed. The efficiency of operation for the
electrical supply can be improved by drying and solidifying the conductive
paste and bringing it into contact with the conductor. Preferably, those
portions which require no solder-plating should be insulated by means of
manicure or the like so that the solder bumps can enjoy a more accurate
shape.
FIG. 8 is a sectional view showing the way the solder bumps 6 are formed on
the conductor wires 2 of the composite chip 5. Electrically conductive
paste 20 is applied to the conductor wires 2 exposed from the one cut
surface of the chip 5, and an electrode plate 22 is connected electrically
to the paste 20. The conductive paste 20 and the electrode plate 22 are
insulated by means of a manicure layer 21 (or insulating film or the
like).
The connection between the conductor wires 2 and the electrode plate 22 can
be made perfect by applying the conductive paste 20 to the supply-side end
portions of the conductor wires 2 and bringing it into contact with the
plate 22 which is connected to the power source. To attain this, the
length of exposure of the conductor wires 2 on the electrical supply side
should be made long enough to ensure the contact between the paste 20 and
the exposed wires 2. If the conductive paste 20 is dry and solid, it can
be easily removed by being dissolved in a solvent or by a chemical method
after the solder-plating.
Thus, in the SMC manufacturing method according claim 25 or 26, the solder
bumps of any desired size can be formed uniformly on the respective end
portions of hundreds or thousands of conductor wires with ease.
A method according to claim 27 or 28 is a manufacturing method for an SMC,
in which the conductor wires are gold wires or gilt conductor wires.
The electrodes of the semiconductor chip or the circuit board are connected
to the conductor wires. Accordingly, the conductor wires are expected to
have satisfactory solderability. The surface of the gold wires or gilt
conductor wires cannot be easily oxidized, and these wires enjoy good
environmental resistance and low contact resistance, so that electricity
can be supplied uniformly to the exposed conductor wires. Thus, solder
bumps of uniform size can be formed individually on a large number of
exposed conductor wires by electroplating.
Since the gold wires or gilt conductor wires do not react to In, moreover,
the electrical supply can be further ensured by depositing a low-melting
In-based solder on the supply-side exposed end portions of the wires and
connecting a metallic electrode plate directly to the In-base solder.
Since the gold wires or gilt conductor wires are highly resistant to
acids, furthermore, removal of the In-base solder by dissolution and acid
washing after the completion of the solder-plating can be accomplished
with ease, so that the conductor wires cannot be damaged.
A method according to claim 29 or 30 is a manufacturing method for an SMC,
in which the surface of each conductor wire is roughed by an electrolytic
treatment or chemical etching.
The anchoring force between the conductor wires and the insulator of the
composite chip may depend on the elastic force of the insulator or the
force of shape retention of the wires. By roughing the wire surface, the
area of contact between the conductor wires and the insulator is increased
to enhance the anchoring force, so that the reliability for use as a
connector is improved.
In any of the methods according to the present invention, (1) a plurality
of conductor wires, which are arranged substantially parallel to one
another, are fixed by means of an elastic insulator which is interposed
between the wires, whereby a composite structure formed of the conductor
wires and the insulator is made, and the composite structure is cut along
a plane extending at right angles to the conductor wires, to make a
plurality of composite chips. In this manner, high-accuracy composite
chips can be mass-produced. (2) The length of exposure of the conductor
wires can be freely controlled by dissolvingly removing the insulator by
means of an agent to expose the wires from each composite chip. Thus,
solder bumps with a predetermined shape can be formed steadily on the
exposed conductor wires. (3) Since the solder bumps are formed on the
conductor wires exposed from the composite chip, they can be controlled in
shape and size. (4) Since the conductor wires between the solder bumps and
the insulator are exposed for a predetermined length, a positioning jig
can be used to solder the wires to a semiconductor chip, so that the
positioning accuracy is improved. (5) The aforesaid exposure of the
conductor wires facilitates the operation for soldering the wires to a
circuit board or the like, and ensures firm connection. (6) Since the
elastic insulator is interposed between the conductor wire, a thermal
stress produced by soldering is absorbed by deformation of the insulator,
so that dislocation between the electrodes and the conductor wires cannot
be caused.
According to the present invention, moreover, (7) a large number of
superfine conductor wires can be arranged substantially parallel to one
another with ease by using bridges which have V-grooves. (8) The accuracy
of arrangement of the conductor wires in the V-grooves of the bridges can
be easily improved by pulling the wires by means of weights which are
attached individually to the respective end portions of the wires. (9) The
position of the conductor wires in the V-grooves of the bridges with
respect to the direction of arrangement (width) can be accurately settled
by arranging the conductor wires in the V-grooves which are formed at
regular pitches. Also, the lamination intervals between a plurality of
parallel conductor wire rows can be easily adjusted by means of spacers
interposed between the wire rows. (10) If a condensed-type silicone
rubber, which has a low degree of polymerization and contains a relatively
large quantity of filler, is used as a material of the insulator, the
conductor wires can be exposed for a uniform length in a short period of
time. (11) If the solder bumps are formed by electroplating, they can
enjoy a desired size and uniform shape. (12) Electrical supply for
electroplating can be easily effected by applying electrically conductive
paste to one cut surface of each of the composite chip along with the
exposed conductor wires, coating the paste for insulation, and then
connecting the conductor wires and the paste electrically to a conductor
which is connected to a power source. (13) If the conductor wires are
formed of gold wires or gilt conductor wires, whose surface cannot be
easily oxidized and which enjoy good environmental resistance, the solder
bumps with uniform shape can be formed individually on the exposed
conductor wires by electroplating. (14) If the surface of each conductor
wire is roughed by an electrolytic treatment or chemical etching, the area
of contact between the conductor wires and the insulator is increased to
enhance the anchoring force between them.
Embodiment 1
SMCs 10 were manufactured according to processes shown in FIGS. 1A to 1F.
Gilt conductor wires 2 (diameter: 0.08 mm) formed of phosphor bronze (Cu,
8% Sn, 0.13% P, by weight) and 1,600 in number were arranged at pitches of
0.25 mm in a square pipe 1 of low-carbon steel, measuring 500 mm in length
and 15.+-.0.01 mm by 15.+-.0.01 mm in cross-sectional area, so as to
stretch substantially parallel to the axis of the pipe 1. A liquid
silicone rubber for use as an insulator 3 was injected into the pipe 1 and
solidified therein, whereupon a composite structure 4 formed of the
conductor wires 2 and the insulator 3 was obtained (FIG. 1A).
Then, the composite structure 4 was drawn out of the square pipe 1 (FIG.
1B), and was cut along a plane F which extends at right angles to the
conductor wires 2, whereupon a composite chip 5 with the thickness of 1.5
mm was obtained (FIG. 1C). An additional-type silicone rubber with a high
degree of polymerization was used for the insulator 3.
Subsequently, the composite chip 5 was dipped into 2-methoxyethanol, the
insulator 3 was dissolvingly removed from the chip 5 through cut surfaces
5a and 5b thereof, whereby the respective end portions of the conductor
wires 2 were exposed for a length of 0.02 mm each (FIG. 1D).
Thereafter, each SMC 10 of FIG. 1E, measuring 15 mm by 15 mm by 1.5 mm, was
manufactured by dipping the one end side of the exposed conductor wires 2
into a solder bath and forming solder bumps 6 individually on the
respective one-side ends of the exposed conductor wires 2.
An Sn-Pb high-temperature solder, containing 90% Pb and 10% Sn by weight
and having a melting point of 280.degree. to 300.degree. C., was used for
the solder bath.
In stretching the conductor wires substantially in parallel relation at
pitches of 0.25 mm, two guide plates, each having 1,600 holes (in total)
with the diameter of 0.083 mm arranged at pitches of 0.25 mm in both
vertical and horizontal directions, were located corresponding
individually to the opposite ends of the pipe 1 with a space of 500 mm
between them, and the wires 2 were passed individually through the holes
of the guide plates.
Embodiment 2
Each SMC 10 of FIG. 1E, measuring 15 mm by 15 mm by 1.5 mm, was
manufactured in the same manner as in Embodiment 1 except that expanded
silicone rubber was used for the insulator.
Embodiment 3
That side of each SMC 10 of FIG. 1E obtained in Embodiment 1 on which the
solder bumps 6 are formed was dipped again into the agent
(2-methoxyethanol) to remove the insulator 3 further by dissolution,
whereupon the conductor wires 2 were exposed for 0.25 mm between the
solder bumps 6 and the insulator 3. Thus, each SMC 11 of FIG. 1F,
measuring 15 mm by 15 mm by 1.5 mm, was manufactured.
Embodiment 4
Each SMC 11 of FIG. 1F, measuring 15 mm by 15 mm by 1.5 mm, was
manufactured in the same manner as in Embodiments 1 and 3 except that
expanded silicone rubber was used for the insulator.
Embodiment 5
Each SMC 11 of FIG. 1F, measuring 15 mm by 15 mm by 1.5 mm, was
manufactured in the same manner as in Embodiments 1 and 3 except for the
use of conductor wires 2 of 0.08-mm diameter having the channels 2a, as
shown in FIG. 2B, and guide plates having the hole diameter of 0.083 mm.
Embodiment 6
Each SMC 11 of FIG. 1F, measuring 15 mm by 15 mm by 1.5 mm, was
manufactured in the same manner as in Embodiments 1 and 3 except for the
use of stranded wires such as the one shown in FIG. 2C (7-strand wire of
phosphor bronze with diameter of 0.08 mm) and guide plates having the hole
diameter of 0.083 mm.
A thousand SMCs 10 and 1,000 SMCs 11 manufactured according to Embodiments
1 to 6 were prepared, and were connected to electrodes of semiconductor
chips and circuit boards by means of their corresponding conductor wires.
The connection was made following the steps of procedure shown in FIGS. 5A
to 5F.
FIGS. 5A to 5F show the case in which each SMC 11 is connected to
electrodes of a semiconductor chip and a circuit board by means of their
corresponding conductor wires. Since the steps of procedure shown in FIGS.
5A to 5F can be also applied to the case of SMCs 10, however, only the
case of the SMCs 11 will be described below, that is, a description of the
case of the SMCs 10 will be omitted.
A semiconductor chip 30 and a circuit board 32 shown in FIGS. 5A to 5F are
formed with 1,600 electrodes 30a and 1,600 electrodes 32a, respectively.
These electrodes have the same pattern as the conductor wires 2 of the
SMCs 11.
First, the solder bumps 6 formed individually on the conductor wires 2 of
each SMC 11 were arranged opposite their corresponding electrodes 30a of
the semiconductor chip 30 (FIG. 5A).
Then, the solder bumps 6 of the SMC 11 were connected to their
corresponding electrodes 30a of the semiconductor chip 30 by reflow
soldering (FIG. 5B).
Subsequently, solder bumps 7 having a melting point lower than that of the
solder bumps 6 were formed individually on the opposite | | |
