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BACKGROUND OF THE INVENTION
The present invention relates to a method of protecting an object subjected
to insert, injection molding by encasing the object in an encapsulating
shell prior to subjecting the object to insert, injection molding. More
particularly, it relates to encapsulating an object with a heat-shrinkable
material prior to subjecting the object to insert, injection molding.
Insert, injection molding involves the insertion of an object into an
injection mold and injecting a flowable polymer at high temperature and
pressure into the mold to form a molded product of which the inserted
object has become an integral part. Certain objects can be damaged when
contacted by the high temperature, high pressure polymer as it is injected
into the mold. For example, electrical or electronic devices, or
combinations thereof in the form of a printed circuit board, are
particularly susceptible to damage when subjected to insert, injection
molding. Such devices may become instantly inoperative upon contact by
molten polymer. Alternatively, thermal shock from direct exposure to
molten polymer may produce latent damage, resulting in the premature
failure of such parts. In addition, when the injected polymer is above the
melt temperature of solder, any solder coming into contact with the
polymer will melt. As a consequence, the electrical connection made by the
melted solder can become disabled. Moreover, if the solder is only
partially melted, the melted portion may flow with the molten polymer and
make contact with an adjoining electrical or electronic component, thereby
forming a conductive "bridge" between two components which should not be
electrically joined.
Although electrical and electronic devices, as well as printed circuit
boards, are susceptible to damage when subjected to insert, injection
molding, in many instances it is highly desirable to do so nevertheless
Insert, injection molding is done in order to provide a protective
enclosure around such devices when used in operating environments which
may subject the devices to physical abuses, such as jarring or frequent
exposure to dirt and moisture. In an automotive vehicle, for instance,
electrical devices, electronic devices, and printed circuit boards are
often provided with a protective molded enclosure, particularly those
which are exposed to automotive fluids, excess vibrations and jarring, or
physical contact. Examples include temperature sensors, which are exposed
to engine vibrations, continuous contact with oil, and high temperatures,
and speed sensors, which are subjected to transmission vibrations, high
temperatures, and exposure to transmission fluid.
An additional problem with insert, injection molded products is that the
injection molded enclosure can allow liquids or other foreign materials to
penetrate the molded enclosure and come into contact with the enclosed
object. This can result from cracks in the enclosure as well as through
openings intentionally left in the enclosure in order to access the
enclosed object. In the case of electrical or electronic components, such
liquid contact can result in damage or shorting.
As can be appreciated, means for protecting objects from damage when
subjected to insert, injection molding, as well as for preventing contact
by liquids which penetrate the molded enclosure, would be highly
advantageous. U.S. Pat. No. 3,226,463 to Wallace discloses a dielectric
sleeve which is placed around a circuit element as well as the bare wire
connections of the circuit element with conductor leads. The circuit
element with the sleeve therearound is placed in an injection mold and
subjected to heated liquid plastic which is injected into the mold under
pressure. However, the dielectric sleeve permits the heated liquid plastic
to flow inside of the sleeve such that the heated liquid plastic directly
contacts the circuit element and bare wire connections Thus, the circuit
element, as well as the connections, is susceptible to thermal damage In
addition, any solder used to make the connections is vulnerable to
melting. Further, in use, any liquids which penetrate the solidified
plastic will directly contact the circuit element and/or the connections.
Accordingly, it is seen that a need exists in the art for a method of
protecting an object subjected to insert, injection molding from damage
due to contact with the injected polymer, and for protecting the enclosed
object from contact from foreign liquids or other materials which
penetrate the molded enclosure.
SUMMARY OF THE INVENTION
That need is met by the present invention which provides a method of
encapsulating an object with a heat-shrinkable material prior to
subjecting the encapsulated object to insert, injection molding, and the
product produced thereby. The encapsulation protects the object from
thermal damage by minimizing direct contact of the object by the injected
polymer. In addition, the encapsulation protects the object from being
contacted by any liquids which may penetrate the molded enclosure.
In accordance with one aspect of the present invention, an encapsulated
product is provided, comprising an object enclosed within a molded plastic
material, and an encapsulating shell positioned around the object and
interposed between the object and the molded plastic material such that
the molded plastic material is substantially prevented from contacting the
object. The encapsulating shell comprises a heat-shrinkable material which
has been heat shrunk to encapsulate the object. Advantageously, the
encapsulating shell substantially minimizes contact with the encapsulated
object by any foreign liquid materials which may penetrate the outer
plastic material
In accordance with another aspect of the present invention, a method is
provided of making an encapsulated product, comprising the steps of
positioning a heat-shrinkable material around an object, applying
sufficient heat to the heat-shrinkable material to activate the
heat-shrinkable material such that the heat-shrinkable material
substantially completely encapsulates the object, placing the encapsulated
object in a mold having a cavity with a predetermined shape, adding a
flowable polymer to the mold such that the encapsulated object is
substantially completely surrounded by the flowable polymer, and
solidifying the flowable polymer. Preferably, the mold is an insert,
injection mold. Advantageously, the heat-shrinkable material substantially
minimizes contact with the encapsulated object by the flowable polymer
while the polymer is added to the mold. In this manner, the
heat-shrinkable material protects the object from damage which may occur
due to direct contact with the flowable polymer, which is injected into
the mold under high pressure and at high temperature.
Accordingly, it is a feature of the present invention to provide an object
encapsulated with an encapsulating shell and contained within an outer
molded plastic enclosure.
It is a further feature to provide a method of encapsulating an object with
a heat-shrinkable material prior to subjecting the encapsulated object to
insert, injection molding.
These and other features and advantages of the present invention will
become apparent from the following detailed description, the accompanying
drawings, and the appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 a perspective view of a tube of a heat-shrinkable material about to
be positioned around a printed circuit board;
FIG. 2 is a perspective view of heat being applied to the tube of
heat-shrinkable material of FIG. 1 in order to encapsulate the printed
circuit board of FIG. I positioned therewithin;
FIG. 3 is a perspective view of the printed circuit board of FIG. 2
encapsulated within the heat-shrinkable material of FIG. 2 after being
heat shrunk;
FIG. 4 is a cross-sectional view taken along lines 4--4 in FIG. 3;
FIG. 5 is a perspective view of the encapsulated printed circuit board of
FIG. 3 placed within an injection mold; and
FIG. 6 is a perspective view, partially in section, of the encapsulated
printed circuit board of FIG. 5 enclosed within a molded plastic material.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The present invention provides a method of making an encapsulated product
which allows an object to be insert, injection molded without sustaining
damage from direct contact with the injected polymer, and the product
produced thereby. Generally, a heat-shrinkable material is first
positioned around an object to be insert, injection molded. The object can
be any object around which it is desired to place a molded plastic
enclosure. The method of the present invention is particularly useful for
objects which are susceptible to damage when subjected to insert,
injection molding, or those which can be damaged upon contact with fluids
or other foreign objects. After the heat-shrinkable material has been
positioned around the object, sufficient heat is applied to the
heat-shrinkable material to activate the heat-shrinkable material such
that it substantially completely encapsulates the object within. The
encapsulated object is then placed in a mold and a flowable polymer is
added thereto such that the encapsulated object is substantially
completely surrounded by the flowable polymer. Finally, the flowable
polymer is solidified to complete the encapsulated product. In this
manner, the heat-shrinkable material substantially prevents the flowable
polymer from contacting the object while the polymer is added to the mold,
thereby protecting the object from any damage which may occur due to
direct contact with the flowable polymer.
By way of example, the method of the present invention will be illustrated
by reference to FIGS. 1-6. It is to be understood, however, that the
following example is set forth for illustration purposes only, and that
the particular application of the present invention which is illustrated
is not intended to be limiting.
With reference to FIG. 1, printed circuit board 10 and heat-shrinkable
material 12 are shown. Heat-shrinkable material 12 is adapted to be
positioned around printed circuit board 10. Preferably, heat-shrinkable
material 12 is tubular or sleeve shaped so that it can be easily slipped
around printed circuit board 10. Printed circuit board 10 includes a pair
of electrical contact leads 14, both of which include a lead wire 15
surrounded by insulation 16. Electrical contact leads 14 provide a means
for electrically communicating with printed circuit board 10.
Generally, printed circuit board 10 is an object around which it is desired
to form a molded enclosure. Containing various electronic components
electrically and mechanically joined by solder joints, printed circuit
board 10 is an object which is susceptible to damage upon direct contact
with a high-temperature, flowable polymer. Thus, printed circuit board 10
serves as a good example of an object for which the method of the present
invention is useful. As can be readily appreciated however, any other
object, such as an electrical or electronic device, may just as readily be
utilized with the method of the present invention.
Referring collectively to FIGS. 2-4, the encapsulation of printed circuit
board 10 will be discussed. As shown in FIG. 2, heat-shrinkable material
12 is positioned around printed circuit board 10. Heat, sufficient to
activate heat-shrinkable material 12, is then applied to heat-shrinkable
material 12 by heat gun 18, or by any suitable heat source. By "activate,"
we mean that the temperature of the heated air 20 flowing onto
heat-shrinkable material 12 from heat gun 18 is above the minimum
temperature at which heat-shrinkable material 12 shrinks In this manner,
when activated, heat-shrinkable material 12 will shrink around printed
circuit board 10 to form encapsulating shell 26 which, as shown in FIG. 3,
substantially completely encapsulates printed circuit board 10.
Preferably, upper edge 22 and lower edge 24 of heat-shrinkable material 12
are positioned around electrical contact leads 14 through opening 25 in
heat-shrinkable material 12. As shown in FIGS. 3 and 4, when heat is
applied to activate heat-shrinkable material 12, upper and lower edges 22
and 24, as well as opposing upper and lower edges 22, and 24,, converge
such that openings 25 and 25' become substantially smaller in size than
the size of those openings prior to the application of heat to
heat-shrinkable material 12. In this manner, only minimal portions of the
surface of printed circuit board 10 will be exposed to direct contact with
flowable polymer during insert, injection molding. Specifically, only
exposed portions 27 and 27' of printed circuit board 10 will be subjected
to direct contact by flowable polymer entering openings 25 and 25',
respectively.
In addition, encapsulating shell 26 substantially minimizes contact with
the remaining portions of printed circuit board 10 which are not exposed
to direct contact by flowable polymer during insert, injection molding.
Heat-shrinkable material 12 is preferably sized such that, when activated,
the resultant encapsulating shell 26 tightly conforms to the outer contour
of printed circuit board 10. The tightly conforming shape of encapsulating
shell 26 around printed circuit board 10 substantially prevents flowable
polymer from flowing inside of encapsulated shell 26 to contact the
portions of printed circuit board 10 which are not exposed to direct
contact by flowable polymer during insert, injection molding. As shown in
FIG. 4, few, if any, void spaces exist between encapsulating shell 26 and
printed circuit board 10. Thus, flowable polymer which contacts exposed
portions 27 and 27' of printed circuit board 10 is largely prevented from
flowing between encapsulating shell 26 and printed circuit board 10 to
reach the vital, non-exposed portions of printed circuit board 10. In the
event that some flowable polymer does reach the non-exposed portions of
printed circuit board 10, the flowable polymer reaching those non-exposed
portions will have lost enough heat and will be so small in amount as to
pose little or no threat of damage to printed circuit board 10.
Referring now to FIG. 5, printed circuit board 10, encapsulated in
encapsulating shell 26, is placed in cavity 28 of insert, injection mold
30. As shown, encapsulated printed circuit board 10 is placed in cavity 28
such that electrical contact leads 14 extend beyond the outer edges of
mold 30. Although an insert, injection mold is presently illustrated, any
type of mold can be utilized in accordance with the present invention. As
is conventional, insert, injection mold 30 further includes upper mold
half 32 and lower mold half 34. Positioned on upper mold half 32 are
injection tubes 36, through which high temperature, high pressure flowable
polymer is injected.
After placing printed circuit board 10, encapsulated in encapsulating shell
26, into cavity 28 of insert, injection mold 30, upper and lower mold
halves 32 and 34, respectively, are tightly joined. High temperature
flowable polymer is then injected at high pressure into cavity 28 through
injection tubes 36. The polymer fills cavity 28 and substantially
completely surrounds encapsulating shell 26, as well as the portions of
electrical contact leads 14 which are exposed in cavity 28. Any type of
polymer which becomes flowable upon heating can be utilized in accordance
with the method of the present invention, such as, for example,
polypropylene, acrylonitrile butadiene styrene, polyamides, or
polycarbonates.
Advantageously, encapsulating shell 26 substantially prevents printed
circuit board 10 from coming into contact with the injected polymer,
thereby protecting the electronic components and solder joints from damage
due to thermal shock or melting of the solder. Preferably, heat-shrinkable
material 12 is a type which, after being heat shrunk to form encapsulating
shell 26, has sufficient temperature resistance to be able to withstand
contact by high-temperature, high-pressure injected polymer without
decomposing. Specifically, the maximum operating temperature of the
heat-shrinkable material used to encapsulate printed circuit board 10
should be higher than the temperature at which the flowable polymer is
injected into mold 30. A preferred example of such a heat-shrinkable
material is polytetrafluoroethylene. In addition to high temperature
resistance, the heat-shrinkable material is preferably selected to be
impervious to any fluids or other foreign materials which are expected to
be present in the operating environment of the encapsulated product. In
this manner, any such fluids or foreign materials which penetrate the
outer plastic enclosure formed by the injected polymer will be
substantially prevented from coming into contact with the enclosed object.
For example, if the enclosed object is a speed sensor, the heat-shrinkable
material forming the encapsulating shell therearound is preferably
impervious to transmission fluid.
Referring now to FIG. 6, the encapsulated product 38 formed from the
above-described method of the present invention is shown. Specifically,
after polymer has been injected into mold 30 and made to solidify (e.g.,
by curing or cooling the polymer, as is conventional), encapsulated
product 38 is removed from mold 30. As shown, encapsulated product 38
includes printed circuit board 10, which is substantially completely
encapsulated by encapsulating shell 26. Encapsulating shell 26 is
interposed between printed circuit board 10 and molded plastic material 40
such that molded plastic material 40 is substantially prevented from
contacting printed circuit board 10. Molded plastic material 40 encloses
printed circuit board 10 and encapsulating shell 26. Electrical contact
leads 14 extend through encapsulating shell 26 and molded plastic material
40 such that electrical communication with printed circuit board 10 is
possible even though it is encapsulated by encapsulated shell 26 and
enclosed within molded plastic material 40.
Encapsulated product 38 can be positioned in any desired operating
environment. Any object, whether electrical, electronic, or otherwise, can
similarly be encapsulated prior to being insert, injection molded.
As described, encapsulating shell 26 protects printed circuit board 10 from
exposure to flowable polymer during insert, injection molding, and from
exposure to foreign liquid materials which may penetrate molded plastic
material 40. By substantially completely encapsulating printed circuit
board 10, encapsulating shell 26 greatly minimizes and substantially
prevents contact with printed circuit board 10 by flowable polymer or
foreign liquid materials by substantially reducing the surface exposure of
printed circuit board 10. Further, openings 25 and 25' minimize direct
contact with printed circuit board 10 by flowable polymer or foreign
liquid materials due to the relatively small size of those openings. Only
exposed portions 27 and 27' are directly exposed to flowable polymer or
foreign liquid materials. Moreover, the tightly conforming shape of
encapsulating shell 26 allows very little, if any, flowable polymer or
foreign liquid materials to directly contact the remaining, non-exposed
portions of printed circuit board 10.
While representative embodiments and certain details have been shown for
purposes of illustrating the invention, it will be apparent to those
skilled in the art that various changes in the methods and apparatus
disclosed herein may be made without departing from the scope of the
invention, which is defined in the appended claims.
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