Information
-
Patent Grant
-
6217983
-
Patent Number
6,217,983
-
Date Filed
Wednesday, March 25, 199826 years ago
-
Date Issued
Tuesday, April 17, 200123 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
- Stout, Uxa, Buyan & Mullins, LLP
- Stout; Donald E.
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CPC
-
US Classifications
Field of Search
US
- 428 195
- 428 200
- 428 201
- 428 365
- 428 158
- 156 235
- 156 210
- 156 277
- 156 324
- 156 267
- 156 269
- 156 289
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International Classifications
-
Abstract
An R-foam having a surface with an electrically resistive ink layer that is continuous and an electrically conductive ink layer that is in a predetermined pattern. The resulting surface is thereby electrically modified to have a predetermined resistive taper across it according to a predetermined resistivity curve. The method of manufacturing the R-foam involves printing the ink layers to the surface in a predetermined pattern that results in the predetermined resistivity curve. The ink layers may be applied using silk screening, stamping, and ink jet printing techniques.
Description
BACKGROUND OF THE INVENTION
The present invention relates to a foam structure having a surface with altered electrical attributes and a method of manufacturing same.
In applications where complex electronic circuits are used, the electronic noise generated by such circuits, i.e., the radio frequency/electromagnetic interference, may be of such level as to be hazardous or detrimental to nearby personnel or other electronic circuits. If such electronic noise reaches a high level, a unit may be in violation of federal regulations or the manufacturer's design specifications, requiring the unit to be recalled by the manufacturer. Applications where this is important include low observable or low radar bounce back uses that require radar absorbing materials or structures. Some of these applications include frequency selective services, anechoic chambers, antenna termination, electric and magnetic shielding, and thermal-electric shielding.
One solution to the above problem involves redesigning the circuit components to reduce the radio frequency/electromagnetic interference to acceptable levels. However, this is a costly remedy. It has also been proposed that a foil shield be placed around the electronic circuitry and connected to ground as another viable approach to reducing environmental radiation from electronic circuitry. Toward this end, an aluminum or copper foil has been adhesively coated on both sides of a substrate, and an outer wrapping layer of polyester or plastics material has been applied thereto. However, these metal foil shielding arrangements are relatively costly and are not especially durable.
Electromagnetic interference has been reduced within a microwave module by producing a sheet of absorber material, such as an elastomer material filled with iron powder, cutting out a pattern from the sheet of absorber material to fit around the components within the module (this pattern generally being relatively complex in shape), and then bonding the absorber to the module lid with an adhesive. Foam has been used as the module lid, and for other structures requiring absorber material. However, the precision shaping and positioning required of the sheet of absorber material significantly increases cost.
Another solution involves R-cards (i.e., resistive or conductive ink cards), examples of which are disclosed in U.S. Pat. Nos. 5,494,180 and 5,364,705, both of which are entitled “Hybrid Resistance Cards and Methods of Manufacturing Same,” and are incorporated herein in their entireties. R-cards have been fabricated by screen printing an ink having electric altering properties imparted by resistive or conductive ingredients onto a major surface of a carrier. The ink printed carrier is then bonded to a part, such as a foam structure. By using silk screening to apply the inks onto a card, the resolution of the patterns as fine as 1 mil permits the R-card to have an accurate and precise resistivity curve.
However, the R-card carriers have been flat, and may be relatively stiff, cards of various materials. For example, one approach has been to print the ink on a cured epoxy-glass laminate and then subsequently use separate film adhesive material to bond such an R-card to a part. Such an approach increased costs and labor, e.g., due to the adhesive coat operation. Also, R-card rigidness has the drawback of not readily conforming to non-flat surfaces, such as double curved surfaces.
R-film has been developed to overcome some of the difficulties in using R-cards with structures of complex geometries while maintaining the highly accurate and precise resistivity curve. R-film is disclosed in co-pending U.S. Patent Application entitled “Screen Ink Printed Film Carrier and Methods of Making and Using Same from Electrical Field Modulation” filed Dec. 10, 1997, now U.S. Pat. No. 5,890,429 which is incorporated herein in its entirety. R-film is a silk screen printed, electrical altering image on thin adhesive film carrier that is flexible to conform to surfaces that are flat and non-flat. However, the process for using R-film requires multiple steps for printing the film and adhering the film to the structure.
It is known to directly coat surfaces of foam structures using techniques that do not provide high resolution. Some of these techniques are spraying, dipping, and loading the foam with resistive and/or conductive filters. The problem with not having high resolution printing is that the accuracy and precision of predetermined resistivity tapers are compromised.
What is needed, therefore, is a foam structure, and manufacturing method thereof, with a surface having a predetermined resistivity taper of relatively high accuracy and precision that is relatively simple to manufacture.
SUMMARY OF THE INVENTION
Accordingly, it is an object of this invention to provide a foam structure with a surface that has a predetermined resistive taper that is made by a relatively simple process compared to that required by conventional processes.
In order to achieve the above and other objects of the invention, an R-foam is provided with a surface having a combined ink layer printed thereon of an electrically resistive ink layer that is continuous and an electrically conductive ink layer that is in a predetermined pattern. The resulting surface is electrically modified to have predetermined resistive taper from the top portion to the bottom portion according to a predetermined resistivity curve.
In another aspect of the invention, the method of manufacturing the R-foam comprises printing a resistive ink layer and a patterned conductive ink layer to the surface of a piece of foam. The patterned conductive ink layer electrically shorts out portions of the surface in a predictable fashion to achieve a predetermined resistive taper from the top portion of the surface to the bottom portion of the surface according to a predetermined resistivity curve. Other and further objects and advantages will appear hereinafter.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a perspective view of an R-foam according to the invention.
FIG. 2
is a sectional end view of the electrically modified surface of the R-foam according to the invention.
FIG. 3
is an alternative pattern of the electrically modified surface of the R-foam according to the invention.
FIG. 4
is the detail A of
FIG. 1
of the electrically modified surface of the R-foam according to the invention.
FIG. 5
is a flow chart of the method for manufacturing the R-foam according to the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring now to the drawings, wherein like reference numerals designate corresponding structures throughout the views, and referring in particular to
FIGS. 1 and 2
, an R-foam
10
according to an embodiment of the invention is shown. R-foam
10
is a foam structure
12
with a surface
14
on which is printed combined ink layer
16
that electrically modifies the surface
14
. The surface
14
has a top portion
18
and a bottom portion
20
.
The foam structure
12
is comprised of a syntactic or blown foam with open or closed cell forms and may be thermoplastic or thermosetting. In a preferred embodiment of the invention, the foam is thermoplastic syntactic foam, an example of which is disclosed in U.S. Pat. No. 5,532,295 entitled “Thermoplastic Syntactic Foams and Their Preparation,” which is incorporated herein in its entirety. The block shape of the foam structure
12
is only for example and other embodiments of the invention may have foam structures of other shapes.
The R-foam
10
is designed to function in the same manner as a prior art R-foam described in the Background of the Invention, but with greater accuracy and precision over the resistive taper. The accuracy is maintained by using a printing process that applies the two layers of the combined ink layer
16
, an electrically resistive ink layer
22
and an electrically conductive ink layer
24
, in a controllable fashion. In a preferred embodiment of the invention, the printing process results in a resolution of as fine as 1 millimeter for both pattern and ink layer thickness. Preferred printing processes include silk screening, stamping, and ink jet printing, with the silk screening process being highly preferred.
The resistive taper of the R-foam
10
is a function of the resistive and conductive ink layers
22
and
24
. The resistive ink layer
22
, shown in black, is applied directly on the surface
14
in a continuous layer, as shown in FIG.
2
. In a preferred embodiment, the resistive ink layer
22
has a constant value of N Ohms/Square when the ink layer thickness is kept constant. The thickness of the resistive ink layer
22
may also be tapered to assist in achieving the predetermined resistivity curve. The conductive ink layer
24
, shown in white, is used to short out regions on the surface
14
. The conductive ink layer
24
is printed on the resistivity ink layer
22
in a plurality of predetermined shapes, such as hexagons as shown. Other embodiments of the invention may have predetermined patterns of other polygons or shapes.
FIG. 3
discloses an alternative pattern
28
of the conductive ink layer
24
utilizing progressively elongated hexagons. Other embodiments of the invention may have the discontinuous conductive ink layer
24
printed directly on the surface
14
and the continuous resistive ink layer
22
printed on top of layer
24
.
The arrangement of the polygons of the conductive ink layer
24
and spacing between the polygons is also a factor in controlling the resistive taper and the desired ohmic end values of the surface
14
. For conceptual clarity, the apparent grid of the resistive ink layer
22
shall be referred to as a grid-like pattern of lines which border and separate the polygons of the conductive ink layer
24
. The polygons are laid out in a pattern to control the distance between each one. Where the polygons are larger and the lines between them thinner, the resistivity is lower. Where the polygons are smaller and the lines between them larger, the resistivity is higher. In an embodiment of the invention, the maximum size of any polygon is one-tenth the wavelength of the operating frequency and the minimum size of any polygon is about one-half the size of the largest polygon.
FIG. 4
represents a detailed enlargement of the section of
FIG. 1
designated by the reference letter A. The desired resistance of the ink layer at any point of the surface
14
can be determined by knowing the length of the polygon sides and the spacing between each polygon. The resistance can be calculated by knowing the number of squares
26
along each side that are in parallel.
FIG. 4
shows how the number of squares
26
is determined. To calculate the resistance, the following equation is employed:
R=R
ink
/N (1)
where R is the resistance, R
ink
is the resistive value of the hybrid ink in Ohms/Square and N is the number of squares between conductive hexagons. For instance, if R
ink
=2000 Ohms/Square and N=4.25 squares, as shown in
FIG. 4
, R would be calculated as follows:
R=2000/4.25=470.588 Ohms (2)
Referring now to
FIG. 5
, a preferred method
100
for manufacturing the R-foam
10
starts with a step
102
for predetermining the resistivity curve. This requires determining the ohmic end values of the R-foam surface
14
and the geometry of the surface. The next step
104
involves calculating the lines of the resistivity ink layer
22
and the polygons of the conductivity ink layer
24
needed to achieve the predetermined resistivity curve. The calculating step
104
is disclosed in detail in the previously referenced and incorporated U.S. Pat. Nos. 5,494,180 and 5,364,705 and 5,890,429 using the previously mentioned Equation (1).
In the next step
106
of the method
100
, the resistive and conductive ink layers
22
and
24
are applied to the surface
14
of the foam structure
12
. As previously stated, the method
100
could use silk screening, stamping, and ink jet printing. The generic techniques of each of these processes is well known. By way of example, the silk screening process will be discussed.
A basic silk screening technique for applying the ink layers
22
and
24
to the surface
14
begins with step
106
a
in which the surface
14
is prepared. The surface
14
needs to be appropriate to accept the ink layers and maintain the required resolution of the patterns. This might require smoothing the surface
14
and/or incorporating a thin film carrier (not shown) into or onto the surface
14
. In the next step
106
b
, the resistive ink layer
22
is applied to the surface
14
. Following that in step
106
c
, the resistive ink layer
22
is at least partially, if not fully, cured. This is to insure a relatively high resolution of the ink layers. In the next step
106
d
, the conductive ink layer
24
is applied on the resistive ink layer
22
. Following that step, in step
106
e
, the conductive ink layer is at least partially cured. It should be mentioned again that the conductive ink layer may be applied before the resistive ink layer in some embodiments of the invention.
The inks used for both the resistive ink layer
22
and the conductive ink layer
24
may be any ink suitable for the chosen printing process, for carrying electrical property additives, and is compatible with the foam structure
12
. An embodiment of the invention uses a resistive ink that is carbon-loaded while the conductive ink may have silver dispersed therein. Other electrically altering additives include powdered iron and ferrites. Some possible inks used in practicing the invention include thermosetting resins such as phenolic, epoxy, or polyamide, or any combination thereof. The preferred phenolic resin is a novolac-type phenolic resin including acid-catalyzed condensation products of formaldehyde or para-formaldehyde with a phenolic compound such as phenol, cresol, xylenol and the like. Suitable modified novolac resins include phenol novolac resin, cresol novolac resin, and tert-butyl phenol novolac resin, a nonylphenol novolac resin, and butylated novolac-type phenolic.
The above-mentioned phenolic compounds and the like may be used alone or as a combination of two or more kinds according to need. The carbon black may be added to adjust the flow and viscosity characteristics of the resistive ink to inhibit undue flowing or sagging while still being spreadable.
The overall thickness of the screen printed pattern
11
, as dried but not yet cured, generally can be about 0.25 to 1.5 mil, more preferably about 0.5 mil.
The screen printing can be practiced, for example, by using screen-mesh, e.g., about 190-420 mesh, filled with emulsion coating. Sharp pattern edges definition is provided when one or more layers of commercially available direct film photo emulsion are used to fill the screen, the emulsion is image-wise exposed and the desired pattern remains in the screen when the exposed emulsion areas are washed out of the screen with water. Each print with about 190-420 mesh deposits about 0.0003 to 0.001 inches of ink coating material.
The flow characteristics of the thermosetting resins used in any of the screen. prints can be further customized by addition of conventional inorganic fillers and/or thixotropic agents, such as fumed silica (e.g., Cabot Cab-O-Sil products). The shelf life of the inks is about one year from the ink production date at normal room temperature (i.e., about 25° C.).
Although presently preferred embodiments of the present invention have been described in detail hereinabove, it should be clearly understood that many variations and/or modifications of the basic inventive concepts herein taught, which may appear to those skilled in the pertinent art, will still fall within the spirit and scope of the present invention, as defined in the appended claims.
Claims
- 1. A foam structure having a surface with altered electrical attributes, comprising:at least one foam surface having a top portion and a bottom portion; and a combined ink layer printed directly on said foam surface, said combined ink layer comprising an electrically resistive ink layer that is continuous and an electrically conductive ink layer that is in a predetermined pattern, such that said foam surface has a predetermined resistive taper from said top portion to said bottom portion according to a predetermined resistivity curve.
- 2. The foam structure as recited in claim 1, wherein:said resistive ink layer is directly on said foam surface; and said conductive ink layer comprises a plurality of shapes disposed on said resistive ink layer, such that said resistive ink layer appears as a grid-like pattern of lines bordering and separating said shapes.
- 3. The foam structure as recited in claim 2, wherein said shapes comprise polygons.
- 4. The foam structure as recited in claim 3, wherein said shapes comprise hexagons.
- 5. The foam structure as recited in claim 3, wherein the maximum size of said polygons is no larger than one-tenth of the wavelength of the highest frequency for which the foam structure is employed, and the minimum size of said polygons is about one-half of the maximum size of the polygons.
- 6. The foam structure as recited in claim 3, wherein the width of said lines determines the resistivity of said surface, such that said lines are thinner in areas of said surface having lower resistivity and are wider in areas of said surface having higher resistivity.
- 7. The foam structure as recited in claim 1, wherein said foam structure comprises a thermoplastic syntactic foam.
- 8. The foam structure as recited in claim 1, wherein said conductive ink layer comprises a plurality of shapes on said foam surface and said resistive ink layer extends continuously over said foam surface and said conductive ink layer.
- 9. The foam structure as recited in claim 1, wherein the thickness of said resistive ink layer varies in thickness across the surface of said foam structure in a predetermined manner in order to assist in achieving said predetermined resistivity curve.
- 10. The foam structure as recited in claim 1, wherein said foam surface comprises a carrier film.
US Referenced Citations (20)