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Description  |
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FIELD OF THE INVENTION
This invention relates to an apparatus for inspecting surface mounted
components, and more particularly, to an apparatus for inspecting the
solder joints of components mounted on the surface of a ceramic substrate.
BACKGROUND OF THE INVENTION
In the course of manufacture of certain electrical devices, such as hybrid
integrated circuits, it is often necessary to mount a plurality of
components or chip carriers on one surface of a thin film ceramic
substrate. These chip carriers may be attached to the substrate by as many
as 32 solder joints. The solder joints, which support the respective chip
carriers above the surface of the substrate, establish an air gap between
the carriers and the surface of the substrate. The air gap permits the
flow of cleaning fluids to remove solder flux that may be present under
the chip carriers which would cause leakage currents when high voltages
are applied to the substrate. Moreover, the air gap facilitates the
encapsulation of the solder joints. The presence of the air gap makes the
alignment of the chip carriers with appropriate ceramic substrate pads a
difficult task. Thus, each solder joint must be visually inspected for
misalignment, shorts between adjacent joints and missing solder joints in
order to reduce subsequent costly test diagnostic time of defective
circuits.
One method of inspecting the solder joints involves a free-hand rotation of
the hybrid integrated circuit beneath a microscope. This method is very
cumbersome because each chip carrier must be rotated four times and the
location of the defective component or chip carrier must be noted for
subsequent repair. This process is difficult to perform without mistakes
because the orientation of the circuit is attained by manual manipulation
in space. Moreover, it is further complicated by (1) closely spaced
adjacent components which block the view of the solder joints or (2) the
necessary and repeated steps of looking back and forth between the
microscope and documentation which identifies the defective component or
chip carrier's location. The process is very time consuming and causes eye
fatigue because of the varying focal lengths due to an unsteady hand.
Consequently, an apparatus is needed which can be rapidly operated to
accurately fix the orientation of the circuit at a constant focal length
from the microscope and allows the inspection of solder joints at varying
distances beneath the component or chip carrier.
SUMMARY OF THE INVENTION
The present invention contemplates, among other things, an inspection
apparatus having a workholder that is moved to individually precisely
position and lock a succession of components mounted on a substrate at an
inspection site whereat a viewer is moved to encompass the sides of the
component to permit microscopic inspection of the sides and the top
surface of the components.
More particularly, the substrate having a pattern of components mounted
thereon is loaded onto the workholder. The workholder is then moved so
that one of the components is presented at an inspection site. A template,
which is secured to the workholder, includes a field of depressions
arrayed in a pattern corresponding to the pattern of components and a
second field of locator holes arrayed in a pattern corresponding to the
patterns of depressions and components. A moveable pin, which is mounted
below the template, senses the presence of one of the field of depressions
and moves therein upon movement of a component into the exact inspection
site. Thereafter, a locator pin moves into one of the field of locator
holes in response to the movement of the moveable pin to lock the
workholder in a fixed position when one of a pair of switches is activated
by an operator. A viewer having mirrors arrayed about an opening of
sufficient size to receive the component at the inspection site is moved
about the component in order to enable the inspection thereof.
BRIEF DESCRIPTION OF DRAWINGS
Other advantages and features of the invention will be apparent upon
consideration of the following detailed description in conjunction with
the drawings wherein:
FIG. 1 is a side view showing a hybrid integrated circuit having a
plurality of chip carriers and applique circuits mounted thereon;
FIG. 2 is a top view showing a layout of chip carriers and an applique
circuit mounted on one major surface of the hybrid integrated circuit of
FIG. 1;
FIG. 3 is a side view of an apparatus for inspecting surface mounted
components embodying certain principles of the invention;
FIG. 4 is a top view of the apparatus of FIG. 3 having certain parts
removed for clarity;
FIG. 5 is a side view showing a viewing assembly having portions cut away
to show a viewing adaptor;
FIG. 6 is a top view showing an apparatus for raising the viewing assembly
of FIG. 5;
FIGS. 7 and 8 are top and side views, respectively, showing the viewing
adaptor of FIG. 5;
FIGS. 9 and 10 are top and side views, respectively, showing an applique
viewing adaptor; and
FIG. 11 is a schematic view of the pneumatic control system of the
apparatus of FIG. 3.
DETAILED DESCRIPTION
Referring to FIGS. 1 and 2, there is shown a hybrid integrated circuit,
designated generally by the numeral 10, which includes a plurality of
closely-spaced elements, such as components or chip carriers 12 and
applique circuits 14 mounted thereon. Additional components (not shown)
may be mounted on surface 15 of the applique circuit 14. The hybrid
integrated circuit 10 also includes a printed circuit (not shown) formed
on major surfaces 16 and 18 of a ceramic substrate, designated generally
by the numeral 20. Moreover, a plurality of mounting pads 21 are formed on
major surfaces 16 and 18 in order to facilitate the mounting of chip
carriers 12 and applique circuits 14 thereon by a plurality of solder
joints 22. Sets of leads 24 are mounted along edges 26 and 28 of the
ceramic substrate 20 in order to facilitate the mounting of the hybrid
integrated circuit 10 into a printed wiring board (not shown). Leads 24
are shown in FIG. 1 as being perpendicular to surfaces 16 and 18. During
the inspection of the hybrid integrated circuit 10, leads 24 are parallel
to surfaces 16 and 18 and include a carrier (not shown) which is
releasably attached to ends of each set of leads positioned along edges 26
and 28.
Referring to FIG. 3, there is shown an apparatus, designated generally by
the numeral 30, for inspecting (1) major surfaces 16 and 18 (FIG. 1), (2)
solder joints 22 positioned beneath chip carriers 12 of applique circuits
14, (3) lead frames 24 and (4) surface 15 of the applique circuit.
Apparatus 30 includes a stage assembly, designated generally by the
numeral 32, a positioning or selectively locking assembly, designated
generally by the numeral 34, a carrier viewing assembly, designated
generally by the numeral 36, and a microscope 38 mounted on a support 40
above the stage and viewing assemblies.
Referring to FIGS. 3 and 4, the stage assembly 32 includes a template 42
mounted for movement on a table 43 mounted for X-Y movement by a
commercial X-Y slide arrangement (not shown). The template 42 includes a
set of coded representations, such as an array of cone-shaped depressions
44, formed in one surface 45 thereof and which are arranged in a first
field such that the positions therein correspond to the positions of the
plurality of chip carriers 12 mounted on the substrate 20 (FIGS. 1 and 2).
The template 42 also includes an array of apertures or locator holes 46
arranged in a second field so that the positions of the apertures also
correspond to the positions of chip carriers 12 mounted on the substrate
20. A platform 47 is positioned above and attached to template 42. A
shield 48, which is attached to the platform 47, is positioned between the
platform and the template 46. The stage assembly 32 also includes a nest
or work holder, designated generally by the numeral 50, which is mounted
on platform 47 and supports the hybrid integrated circuit 10 (FIGS. 1 and
2) during an inspection process. The nest 50, which is mounted on platform
47, is moveable in planar fashion during the inspection process. The nest
50 includes four locating posts 52 (three shown) which facilitate the
positioning of circuit 10 on the nest. Moreover, the nest 50 also includes
position pins 54 which precisely align the leads 24 of circuit 10 on the
nest so that the position of the chip carriers 12 correspond to the
positions of the array of cone-shaped depressions 44. Handle portions 56,
which are also mounted on platform 47, enable an operator to manually
shift the stage assembly 32 in X-Y paths beneath the microscope 38. A pair
of pneumatic switches, designated generally by the numeral 58, which are
mounted on platform 47, enable and control the activation of the
positioning assembly 34. Each one of the pneumatic switches 58 includes a
nozzle 59 which normally emits a stream of air and which is overlayed by a
thin flexible sheet of metal or switch actuator 60, which when flexed acts
to close the appropriate one of the nozzles to effectuate operation of the
appropriate switch.
Referring again to FIG. 3, the positioning assembly 34 includes a
spring-biased sensor plunger 62. The sensor plunger 62, is biased in the
direction of the template 42 and is prevented from moving in an upward
direction, as viewed in FIG. 3, by under surface 45 of the template. A cam
64, which is positioned on a lower portion of plunger 62, facilitates the
operation of a pneumatic switch 66. Depressions 44 allow an upward
movement of plunger 62 when positioned thereabove which permit the
movement of cam 64 and the closing of switch 66. A cylinder rod or locator
pin 68 is activated by air cylinder 69 to move into one of the array of
apertures 46 when (1) cam 64 allows switch 66 to close and (2) one of the
switch actuators 60 is depressed by an operator. The movement of cylinder
rod 68 into one of the array of apertures 46 (1) shifts the template 42
and the stage assembly 32 to precisely center the corresponding one of the
chip carriers 12 beneath the carrier viewing assembly 36 when the circuit
10 is mounted in nest 50 and (2) lowers the viewing assembly about the
chip carrier.
Referring to FIGS. 3, 4, 5 and 6, the carrier viewing assembly 36 includes
a viewing adaptor, designated generally by the numeral 70, mounted on a
bracket member 72. Bracket member 72 is coupled to a support member 74
which is coupled to a moveable portion 76 of a roller-bearing slide
mechanism 78. A stationary portion 80 of the slide mechanism 78 is fixedly
attached to a sub-assembly mounting plate 82 by a first L-shaped bracket
84. A second L-shaped bracket 86, which is secured to support member 74,
is positioned above a first air-cylinder 88. When the first air cylinder
88 is activated, cylinder rod 90 engages bracket 86 in order to move the
carrier viewing assembly 36 in an upward direction. The carrier viewing
assembly 36 also includes a second or lock-out air cylinder 92 having a
cylinder rod 94 which is spring biased in an outward direction. Whenever
there is a failure in the air supply to air cylinder 92, cylinder rod 94
is forced outward and positions one end thereof beneath bracket 74 in
order to lock the viewing assembly 36 in an upward position which prevents
the lowering of the viewing assembly. This serves as a safety feature to
prevent harm to the integrated circuit 10 should there be a loss of air
supply to cylinder 92 while the viewing assembly 36 is in its upward
position.
Referring to FIGS. 7 and 8, there is shown an enlarged view of the viewing
adaptor 70. The viewing adaptor includes four polished metal mirrors 96
mounted on bracket member 72 at an angle which facilitates the inspection
of solder joints 22 (FIG. 1). A plurality of support members or feet 98,
which are positioned between the mirrors 96, support the viewing adaptor
70 and limit (1) the downward travel of the viewing assembly 36 (FIGS. 3
and 5) and (2) the contact with hybrid integrated circuit 10 (FIGS. 1, 2,
3 and 4) to four small areas. The mirrors 96 of the viewing adaptor 70 are
configured to provide an open center area 100 which (1) provides a target
zone or inspection site within which a chip carrier 12 is positioned and
(2) enables the operator to inspect lead frames 24 (FIGS. 1 and 2),
surfaces 16 and 18 of hybrid integrated circuit 10 and surfaces 15 of the
applique circuit 14. When the mirrors 96 are positioned to surround the
edges of the selected chip carrier 12, light is impinged on the edges of
the carrier and the solder joints 22 under the carrier. A light image of
each edge and the solder joints 22 positioned thereby is reflected back
onto the respective mirror which may be easily viewed from directly above
through the microscope 38.
As noted above, each of the chip carriers 12 has a plurality of solder
joints 22 positioned therebeneath. Spacing between the solder joints 22 is
very small; thus, the viewing adaptor 70 must enable the operator to
inspect each of the solder joints. The angle of the mirrors 96 is set to
enable each of the solder joints 22 to be visible as well as a distance
beneath the selected chip carrier 12 beyond the tangent of each of the
solder joints. Moreover, a portion of the appropriate surface 16 or 18, as
well as an adjacent surface of the chip carrier 12, must be visible in
order for the operator to determine if an effective connection exists
between the substrate 20 and the selected chip carrier.
Referring again to FIGS. 4, 9 and 10, there is shown an auxiliary or
applique viewing adaptor, designated generally by the numeral 102, for
inspecting the solder joints 22 positioned between the applique circuit 14
(FIGS. 1 and 2) and the respective surfaces 16 and 18 of the hybrid
integrated circuit 10. The auxiliary viewing adaptor 102 includes four
polished metal mirrors 104 mounted at an angle and positioned to encompass
an open center area 106. As is best seen in FIG. 2, solder joints 22 are
positioned farther inward from the appropriate edge of the applique
circuit 14. Therefore, the angle of mirrors 104 must be such that the
solder joints 22 as well as portions of the appropriate surface 16 or 18
are visible. The auxilliary viewing adaptor 102 is pivotally mounted on a
support member 108 to permit selective movement of the adaptor about the
applique circuit 14 during the inspection thereof. The support member 108
is fixedly attached to platform 47 (FIGS. 3 and 4) adjacent the nest 50.
In operation, and referring to FIGS. 3, 4 and 11, the operator places the
hybrid integrated circuit 10 in the nest 50. Grasping the handle portions
56, the staging assembly 32, including the nest 50, is moved to generally
position a first chip carrier 12 beneath the microscope 38 within the
inspection site. The operator then depresses one or both of the switch
actuators 60 to block normal passage of air from the nozzles 59. Spring
urged sensor plunger 62 moves upward into one of the depressions 44 as the
chip carrier 12 is moved into the inspection site which is indicative of
the desired precise positioning of the carrier under the microscope 38.
Upward movement of the sensor plunger 62 releases the switch 66 so that
air applied to an air valve 112 is blocked from passage through bleed line
110 to the atmosphere. Blockage of one or the other or both of the nozzles
59 causes one or another or both of a pair of associated valves 114 and
116 to shift and in conjunction with the releasing of switch 66 condition
an air circuit to the locking cylinder 69.
More specifically, air from source S is impressed over a supply line 118,
through a valve 120, through (1) the now shifted valve 114 or 116 or both,
(2) the directional valves 122 and 124 to a line 126, and (3) a flow
controller 127 to an operator for a valve 130. Valve 130 shifts against
the force of a spring 132 to complete an air circuit to the lower end of
the air cylinder 69. This air circuit can be traced from supply line 118,
over a line 134, through the now shifted valve 130, over a line 136 to the
lower end of the air cylinder 69 which reacts to drive the cylinder rod 68
into the aligned aperture 46 to lock the stage assembly 32 and position
the chip carrier 12 in a precise inspection location with respect to the
microscope 38.
The movement of the cylinder rod 68 into an aligned aperture 46 blocks
normal passage of air from nozzle 138. Blockage of nozzle 138 causes air
valve 140 to shift to allow the passage of air therethrough. Moreover, air
which is impressed over supply line 118, through valve 114 or 116,
directional valves 122 and 124, to line 126, is fed to an operator for a
valve 142. Valve 142 shifts to permit the flow of air to an operator of an
air valve 144 which shifts to complete an air circuit to the upper end of
air cylinder 88. This circuit can be traced from supply line 118 over a
line 146 through the now shifted valve 144 over a line 148 to the upper
end the air cylinder 88 which reacts to retract cylinder rod 90 and
enables the lowering of the viewing assembly 36 about the first chip
carrier 12.
After the operator has completed the inspection of the solder joints 22
associated with the first chip carrier 12, the switch actuator 60 is
released which opens nozzle 59 and permits the normal flow of air
therethrough. The flow of air through nozzle 59 causes the associated air
valve 114 or 116 to shift due to force of an associated spring 150 or 152,
respectively. The shifting of air valve 114 or 116 blocks the flow of air
from air supply line 118 to line 126. The blockage of the flow of air to
line 126 enables air valve 142 to shift to a closed position due to the
force of spring 154 which blocks the flow of air from air supply line 118
through air valve 140 and 142 to the operator of air valve 144. Air valve
144 shifts due to the force of spring 156 to condition an air circuit to
the lower end of the air cylinder 88. This air circuit can be traced from
supply line 118 over line 146 through now shifted air valve 144 over line
158 through flow controller 160 to the lower end of cylinder 88 which
reacts to raise the viewing assembly 36. Moreover, the blockage of air
flow to line 126 enables air valve 130 to shift due to the force of spring
132 which completes an air circuit to the upper end of air cylinder 69.
This air circuit can be traced from supply line 118, over line 134,
through air valve 130, line 157, through flow controller 162 to the upper
end of air cylinder 69 which reacts to retract cylinder rod 68 from
aperture 46 and unlock the stage assembly 32 for movement to position a
second chip carrier 12 beneath the microscope 38. Flow controller 162 is
adjusted to insure that the viewing assembly 36 is raised prior to the
lowering of the cylinder rod 68 in order to prevent any damage to the
circuit 10 which may result if the stage assembly is moved while the
viewing assembly 36 is about the chip carrier 12. The lowering of cylinder
rod 68 also allows air which flows from supply line 118 over line 164 to
bleed through nozzle 138. This allows air valve 140 to shift in a closed
position due to spring 166.
An additional feature of the fixture 30 enables the operator to speed up
the inspection process by activating one or both of the switches 58 while
searching for the location of one of the chip carriers 12. As noted above,
the cylinder rod 68 is raised into one of the apertures 46 only when
sensor plunger 62 enters into one of the depressions 44. Thus, the
operator may freely and rapidly move the stage assembly 32 with one or
both of the switches 58 activated and the cylinder rod 68 will only be
raised when one of the apertures 46 is positioned above it. Moreover, the
viewing assembly 36 will be lowered only after the cylinder rod 68 has
entered one of the apertures 46 and has blocked the bleeding of air from
nozzle 138.
After the operator has completed the inspection of the solder joints 22 for
all of the chip carriers 12, the switch actuator 60 is again released
which permits air which flows from supply line 118 through air valve 120
to bleed through nozzles 59. As noted above, the viewing assembly 36 is
raised before the cylinder rod 68 is lowered which enables the operator to
freely move the stage assembly 32. The operator then moves the stage
assembly 32 so that the auxiliary viewing adaptor 102 can be moved about
the applique circuit 14. As is best seen in FIG. 2, the size of the
applique circuit 14 is much larger than that of the chip carriers 12.
Moreover, the applique circuit 14 is larger than the field of view of the
microscope 38; thus, the stage assembly 32 must be indexed by the operator
in order to present groups of the solder joints 22 associated with the
applique circuit to the inspection site for inspection until all of the
solder joints have been inspected. During this inspection, the viewing
assembly 36 is held in its upward position, as seen in FIGS. 5 and 6, due
to the absence of any cone-shaped depressions 44 in this area of the
template 42 thus causing cam 64 to exert pressure on switch 66 which
prevents the operator from activating either of the pair of switches 58.
Lock-out cylinder 92 is also coupled to air line 118 through air valve 168
and flow controller 170. As noted above, cylinder 92 is spring-biased in
an outward direction. Thus, air from source S is impressed over supply
line 118 through flow controller 170 to an operator of an air valve 168
which causes the air valve to shift to condition an air circuit to an
upper end of cylinder 92. This air circuit enables the cylinder rod 94 to
be retracted against the force of spring 172 contained within cylinder 92.
When there is a loss of air pressure in line 118 due to a failure of air
from source S, air valve 168 is allowed to change its position due to air
pressure within an opposite operator associated with cylinder 92. As air
valve 168 changes its position, air pressure from cylinder 92 leaks out
through line 174 which permits the plunger to be extended as a result of
spring 172 within cylinder 92 and positions itself under an end of bracket
74 to hold the viewing assembly 36 in its upward position.
Apparatus 30 can be also utilized to inspect lead frames 24 mounted along
edges 26 and 28 of the ceramic substrate 20 by positioning the appropriate
edge 26 or 28 beneath the microscope 38. As noted above, the same safety
feature which prevents the lowering of the viewing assembly 36 is in
effect during the inspection of the lead frames 24.
Apparatus 30 also includes a maintenance switch 176 which enables the
operator to operate the fixture without activating the switch actuator 60
during a maintenance operation. When switch 176 is placed in an automatic
(auto) position, as seen in FIG. 11, the operator must activate switch
actuators 60 which condition an air circuit to line 126. This air circuit
can be traced from air supply line 118 through air valve 114 or 116,
directional flow controllers 122 and 124 and into line 126. When switch
176 is placed in a manual position, an air circuit is conditioned to line
126 which by-passes air valves 114 and 116 and directional flow controller
122. This air circuit can be traced from air supply line 118 through the
now shifted air valve 120 over line 128 and into line 126.
Apparatus 30 also includes a switch, designated generally by the numeral
180, that prevents the operator from lowering the viewing assembly 36 by
activating switches 58 when the stage assembly 32 is moved to a loading
position, wherein the stage is moved to the extreme right of the
microscope 38 for loading the hybrid integrated circuit 10 onto nest 50.
Switch 180 includes a switch actuator 182, which is engaged by the table
43 when the stage assembly 32 is in the loading position and which causes
an air valve 184 to shift against the force of a spring 186 so that air
applied to the valve bleeds through line 188. If the operator activates
switches 58, air valves 114 or 116, or both, are shifted and completes a
circuit from line 118 to line 126. Air from source S is now impressed over
line 118, through the now shifted air valves 114 or 116, through
directional flow controller 122 and 124, over line 126 and bleeds out
through line 188 which prevents the operation of (1) air valve 130 which
enables the operation of air cylinder 69 and (2) air valve 142 which
enables the operation of air cylinder 88. Therefore, even though the
operator has activated switches 58, air cylinder 69 is not operated to
lock and position the stage assembly 32 and the viewing assembly 36 is not
lowered when the stage assembly is in the loading position.
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