Cast core fabrication of helically wound antenna
First Claim
1. A method of manufacturing a helical antenna comprising the steps of:
- (a) providing a grooved mandrel that conforms with the intended contour of a dielectric support core having a helical groove upon which an antenna conductor is to be wound;
(b) forming a mold around said grooved mandrel, so that said mold conforms with the shape of the surface of said grooved mandrel;
(c) extracting said grooved mandrel from said mold so as to leave said mold with a cavity that has an embossed helical ridge and replicates the shape of said grooved mandrel;
(d) injecting dielectric material into said mold cavity, and curing said dielectric material to produce said dielectric support core;
(e) removing said mold from said dielectric support core produced in step (d); and
(f) winding said antenna conductor in said helical groove of said dielectric support core, so as to provide a helical antenna winding that is stably retained by said dielectric support core.
2 Assignments
0 Petitions
Accused Products
Abstract
A cast core process is used to fabricate a very small, precision wound helical antenna having readily repeatable configuration parameters for use in a high GHz multi-element (e.g., phased array) antenna. A dielectric core member is formed by shaping a solid mandrel having a precision helical groove. After a mold is formed around the mandrel and cured, the mandrel is extracted, so that it may be used to make additional identical molds. A dielectric mixture is injected into the mold'"'"'s cavity, and cured. The mold is then removed, and antenna wire is tightly wound and bonded into the dielectric core'"'"'s helical groove. The antenna wire-wrapped core is then mechanically and electrically attached to a baseplate laminate structure, that includes a tuning circuit, so that the antenna may be physically mounted to a support member and connected to an associated transmit—receive module.
27 Citations
14 Claims
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1. A method of manufacturing a helical antenna comprising the steps of:
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(a) providing a grooved mandrel that conforms with the intended contour of a dielectric support core having a helical groove upon which an antenna conductor is to be wound;
(b) forming a mold around said grooved mandrel, so that said mold conforms with the shape of the surface of said grooved mandrel;
(c) extracting said grooved mandrel from said mold so as to leave said mold with a cavity that has an embossed helical ridge and replicates the shape of said grooved mandrel;
(d) injecting dielectric material into said mold cavity, and curing said dielectric material to produce said dielectric support core;
(e) removing said mold from said dielectric support core produced in step (d); and
(f) winding said antenna conductor in said helical groove of said dielectric support core, so as to provide a helical antenna winding that is stably retained by said dielectric support core. - View Dependent Claims (2, 3, 4, 5)
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6. A method of manufacturing a multi-element antenna architecture comprising the steps of:
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(a) providing a grooved mandrel that conforms with the intended contour of a dielectric support core having a helical groove upon which an antenna conductor is to be wound;
(b) forming a mold around said grooved mandrel, so that said mold conforms with the shape of the surface of said grooved mandrel;
(c) extracting said grooved mandrel from said mold so as to leave said mold with a cavity that has an embossed helical ridge and replicates the shape of said grooved mandrel;
(d) injecting dielectric material into said mold cavity, and curing said dielectric material to produce said dielectric support core;
(e) removing said mold from said dielectric support core produced in step (d);
(f) winding said antenna conductor in said helical groove of said dielectric support core, so as to provide a helical antenna winding that is stably retained by said dielectric support core;
(g) electrically and mechanically coupling said helical antenna winding as retained by said dielectric support core to a support structure for mounting said helical antenna winding to a multi-element antenna support member;
(h) mounting said support structure for said helical antenna winding as retained by said dielectric support core to said multi-element antenna support structure;
(i) repeating steps (a)-(h) a plurality of times, using the grooved mandrel extracted in step (c) as the mandrel provided in repeated step (a). - View Dependent Claims (7, 8, 9)
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- 10. A helical antenna configured by forming a mold around a helically grooved mandrel that conforms with the intended contour of a dielectric support core having a helical groove upon which an antenna conductor is to be wound, so that said mold conforms with the shape of the surface of said helically grooved mandrel, extracting said helically grooved mandrel from said mold so as to leave said mold with a mold cavity that has an embossed helical ridge and replicates the shape of said helically grooved mandrel, injecting dielectric material into said mold cavity, and curing said dielectric material to Produce said dielectric support core, removing said mold from said dielectric support core, and winding said antenna conductor in said helical groove of said dielectric support core, so as to provide a helical antenna winding that is stably retained by said dielectric support core.
Specification