Plug-in ceramic hybrid module

A hybrid circuit module for the modular system constructions of electronic equipment. The module includes a socket that is soldered to a printed wire board and includes a grounding strip and electrical contact terminals. A hybrid circuit fabricated on a ceramic substrate fits within a plastic guide which in turn is fitted to the socket. A plurality of contact pads on the hybrid circuit make electrical contact with the terminals of the socket. A shield can is fitted over the plastic guide and hybrid circuit.

BACKGROUND OF THE INVENTION 
This invention relates in general to hybrid circuits used in the 
construction of radio equipment and the like. More specifically, this 
invention relates to packaging and interconnect systems used in the 
fabrication of hybrid circuits. 
The use of ceramic substrate thick and thin film hybrid circuits is 
becoming more and more widespread in the radio communications industry. 
Such circuits generally are used in the construction of subsystems that 
are electrically connected with other such systems and/or conventional 
components placed on printed wire boards (PWB). 
Hybrid circuits are formed on a ceramic substrate. Various components, such 
as capacitive and resistive elements are "painted" onto this substrate 
using silver poladium or some other "ink" forming a conductive or 
semiconductive layer. For capacitive elements a dielectric layer is 
"painted" between two conductive layers. The size of the layers, spacing 
and dielectric properties determine the capacitance of the element. In 
addition, lumped parameter conventional components such as resistors, chip 
capacitors, and inductors may form part of the circuit, hence the term 
"hybrid". 
As the radio spectrum becomes more crowded and frequency tolerances become 
more severe; and as radio equipment becomes more sophisticated, there is 
an increasing need for a packaging system that can protect their delicate 
ceramic substrate and the electrical components mounted and painted 
thereon while providing a high degree of radio frequency (RF) interference 
shielding to meet the performance requirements of radio communication 
equipment. In addition, it is highly desirable to provide a circuit 
interconnection system allowing the quick and easy substitution of one 
ceramic hybrid circuit for another. 
A known hybrid circuit packaging arrangement is shown in U.S. Pat. No. 
4,001,711--Knutson et al, incorporated herein by reference. This is a high 
power level circuit and includes pins that are soldered directly to a 
printed wire board when the hybrid circuit is installed. Although such 
solder interconnection may be required for high power circuits requiring 
heat dissipation through the pins, this known packaging arrangement is 
inappropriate for most small signal applications. The use of solder in 
terminals is unnecessarily restrictive, both in initial assembly of a 
piece of radio equipment and in servicing it. 
SUMMARY OF THE INVENTION 
Therefore, the present invention provides a packaging arrangement 
particularly suitable for small signal ceramic hybrid circuits requiring a 
high degree of RF shielding. 
The packaging arrangement provides not only physical protection and RF 
shielding for the hybrid circuit, but also provides a "plug-in" module 
construction. One or more plug-in modules can be mounted on a PWB. If a 
module must be tested or replaced, it can be easily unplugged and a new 
one substituted therefore, as necessary. 
The hybrid module according to the present invention includes four main 
elements: a socket, permanently soldered to a printed wire board; a 
plastic guide interconnecting with the socket and having a pair of grooves 
to accommodate the edges of a ceramic substrate; the ceramic substrate 
hybrid circuit itself which slides into the grooves of the plastic guide 
(the edges of the substrate slide into the grooves); and a shield can 
surrounding the hybrid circuit and the plastic guide and interconnecting 
with terminals provided on the socket, the shield can completely enclosing 
hybrid circuit. The hybrid circuit includes a plurality of contact pads 
which interconnect with terminals provided in the socket. 
To substitute one hybrid circuit for another, it is only necessary to 
remove the shield can and lift the plastic guide and hybrid circuit from 
the socket. The hybrid circuit can then be slipped out of the grooves of 
the plastic guide and another hybrid circuit substituted therefore into 
the plastic guide. The plastic guide and the new hybrid circuit can then 
be reinserted into the socket and the shield can replaced.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to FIG. 1 there is shown an exploded perspective view of the 
plug-in ceramic hybrid module according to the present invention. The 
module includes four main elements: a socket 10 which, upon installation, 
is soldered into a printed wire board 12; a plastic guide 14; a hybrid 
circuit 16, and a shield can 18. 
Socket 10 is fabricated from a plastic material and has two channels 20 and 
22 formed therein. In at least one of the channels there is deposed a 
plurality of U-shaped pressure terminals 24 for receiving corresponding 
contact pads 26 formed on the ceramic substrate of hybrid circuit 16. On 
each end of socket 10 is a plastic pin 28 adapted to mate with a groove 30 
formed in each side of plastic guide 14. Socket 10 includes a bracket 32 
running along the bottom and both elongated sides thereof. This bracket is 
electrically interconnected with a ground printed wire on printed wire 
board 12. The edges of bracket 32 running along the elongated sides of 
socket 10 are cut and contoured so that shield can 18 pressure fits over 
the grounded bracket and makes good electrical contact therewith. Thus, 
when shield can 18 is fitted over socket 10, it makes electrical contact 
with bracket 32 for the entire length of both the front and back edges of 
the socket. This arrangement provides a very low resistance connection 
bringing shield can 18 to ground potential. 
Hybrid circuit 16 includes a ceramic substrate 34 on which are formed 
contact pads 26 force-fit for interconnection with terminals 24. Plastic 
guide 14 is provided with a pair of grooves 36 having a width slightly 
larger than the thickness of substrate 34. This allows hybrid circuit 16 
to be inserted within plastic guide 14 from the top thereof. After hybrid 
circuit 16 is slid into grooves 36, the hybrid circuit and plastic guide 
are applied to socket 10. To insert hybrid circuit 16 and plastic guide 14 
into socket 10, the contact pads 26 of the hybrid circuit are inserted 
into the corresponding terminals 24 within the socket and groove 30 is 
forced around pins 28 of the socket. 
Plastic guide 14 also includes a recessed portion 38 surrounding groove 30. 
Recess portion 38 is adapted to accommodate a cutout 40 positioned on each 
side of shield can 18. After hybrid circuit 16 and plastic guide 14 are 
inserted into socket 10, shield can 18 is lowered over the hybrid circuit 
and plastic guide. Cutout 40 which is bent toward the interior of shield 
can 18 becomes wedged within recessed 38 to secure the shield can to the 
plastic guide. As already stated, the bottom portion of shield can 18 
forms a firm contact with bracket 32 of socket 10. This brings shield can 
18 into good electrical contact with the ground plane of the printed wire 
board. As shown in FIG. 1, shield can 18, in this particular circuit 
module embodiment, is provided with three (3) holes in the top thereof. 
These holes provide access to adjustable components by a tuning tool. The 
holes do not form a part of the invention. 
Referring now to FIG. 2 there is shown a partially cutaway front view of 
the hybrid circuit module according to the present invention. In this 
view, socket 10 is soldered to printed wire board 12 and the hybrid 
circuit is in place. Shield can 18 makes contact with ground terminal 32. 
Cutout 40 is shown secured within recess 38 of plastic guide 14. To remove 
shield can 18, it is only necessary to pull evenly in a vertical direction 
with sufficient force to disengage the force fit with socket 10 and 
bracket 32. To remove hybrid circuit 16 from shield can 18, it is 
necessary to disengage cutout 40 from recess 38 in plastic guide 14 which 
then allows easy withdrawal of the hybrid circuit and plastic guide from 
the shield can 32. 
Referring now to FIG. 3 there is shown a partially cutaway side view of the 
hybrid circuit module according to the present invention. This view 
illustrates an alternate embodiment for socket 10 including three channels 
40, 42 and 44 substituted for the two channels 20 and 22 shown in the FIG. 
1 embodiment. Of course, the invention is not limited to any particular 
number of channels and the FIG. 3 embodiment is shown merely as one 
possible alternative. In this cutaway side view, terminals 24 are more 
clearly shown capturing a contact pad 26 of hybrid circuit 16. Also, the 
electrical contact between shield can 18 and ground terminal 32 is more 
clearly visible. 
A thin layer of insulating material can be provided between bracket 32 and 
the upper surface of printed wire board 12. This insulating layer can 
serve as a solder flux shield when socket 10 is soldered to printed wire 
board 12 and as a preventive for the shorting of electrical runs on the 
printed wire board to the ground strip. Of course, bracket 32 is 
electrically connected with a ground strip of printed wire board 12. 
While the invention has been described in connection with what is presently 
considered to be the most practical and preferred embodiments, it is to be 
understood that the invention is not to be limited to the disclosed 
embodiments but on the contrary is intended to cover various modifications 
and equivalent arrangements included within the spirit and scope of the 
appended claims which scope is to be accorded the broadest interpretation 
so as to encompass all such modifications and equivalent structures.