US2705256A

US2705256A - High voltage insulator

Info

Publication number: US2705256A
Application number: US761898A
Authority: US
Inventors: John W Mcgee
Original assignee: FREDERIC FLADER Inc
Current assignee: FREDERIC FLADER Inc
Priority date: 1947-07-18
Filing date: 1947-07-18
Publication date: 1955-03-29
Anticipated expiration: 1972-03-29

Description

March 29, 1955 J. w. MGGEE HIGH VOLTAGE INsULAToR Filed July 18, 1947 grwa/wtov MC GEE JOHN W.

Guo-Mug United States Patent O HIGH VOLTAGE INSULATOR John W. McGee, Minneapolis, Minn., assiguor to Frederic Flader, Inc., North Tonawanda, N. Y., a corporation of New York Application July 18, 1947, Serial No. 761,898

7 Claims. (Cl. 174-179) (Granted under Title 35,- U. S. Code (1952), sec. 266) This invention relates to electrical insulators and in particular to electrical insulators offering both high dielectric and structural strengths.

In the operation of radio equipment a most frequently encountered and troublesome problem is that .of static interference. This phenomenon is especially noticeable in aircraft installations, and in particular during flights through areas of precipitation. Under this circumstance the aircraft will become highly electrified, or charged to a potential where corona discharges will occur at various points on the aircraft. When these discharges occur at such points on the aircraft as to be coupled to the antenna the attendant noise pulses are generally so severe as to render the associated radio equipment useless.

In general, most aircraft antenna structure' and espe cially wire type antennae and associated hardware (strain insulators, tension insulators, antenna masts, etc.) are by necessity streamlined or formed with surfaces having small radiuses of curvature. Components having these general physical characteristics frequently go into a corona discharge before any other point on the aircraft. Consequently, the antenna itself and associated hardware are often the most prolific sources of static disturbance.

One effective solution to the suppression of corona from the antenna and associated parts has been to cover the antenna and associated parts with a suitable dielectric sheath. It is to be noted, however, that in order for this solution to be effective, the dielectric sheath covering the antenna and the associated components must have high dielectric strength and must completely cover the antenna and components. The proposition of insulating these components, to repeat, must be' 100% and nothing less.

It is an object of this invention to provide an insulator suitable for use with insulated aircraft antennae.

It is another object of this invention to construct a high voltage insulator having both high dielectric strength and high tensile strength.

It is another object of this invention to provide an insulator of the foregoing character which is both inexpensively and easily manufactured.

It is another object of this invention to provide a high voltage insulator having smoothly faired contours suitable for use on aircraft antenna.

It is another object of this invention to provide a novel high voltage strain insulator.

It is another object of this invention to provide a novel high voltage tension insulator.

Other objects and features of the present invention will become apparent upon a careful consideration of the following detailed description when taken with the accompanying drawings, in which: h

Fig. l is a longitudinal sectional view of one embodiment of the invention, and

Figs. 2 and 3 are longitudinal sectional views of two different types of tension insulators constructed according to the teachings of the present invention.

Referring to Fig. 1, the insulator exemplified in this figure is one which is suitable for use as a strain insulator. Included in the assembly is an elongated inner dielectric member 10 which may be (for example) cylindrical in shape and which, as will hereinafter be apparent, is selected to provide high tensile strength as well as high dielectric strength. A dielectric material known as steatite has been found to be admirably suited to this purpose. Attached to cach end of the inner dielecp ICC tric member 10 is a terminal clamp, or connector, indicated in general at 11 and 12 respectively. In this embodiment, terminal clamps 11 and 12 are attached, such as by the threaded engagements indicated at 13 and 14 to opposite ends of the inner member 10, and extend in opposite directions from and co-linearly with said inner member. Both terminal clamps 11 and 12 are identical in construction. Accordingly, the constructional details of only one of the clamps, 12, which is herein shown in section, will be given.

The terminal clamps comprise a chuck assembly having a generally tubular outer metallic housing 16, formed with an internal diameter of a suitable dimension at its base 15 and tapering to a smaller diameter at its throat 27. The mouth, or entrance, of the outer housing 16 is internallyrecessed to a larger diameter as illustrated at 28 to accommodate the insulating sheath 17a of the conductor 17 to be held by the terminal clamp. Inserted within the outer housing 16 are a pair of elongated semicylindrical metallic jaws 18 and 18a which have an external surface tapered to conform to the internal taper of the outer housing 16. The opposing faces of the jaws 18 and 18a are concaved and formed with a series of teeth 19 arranged to grip the bare conductor wire 20 of the conductor 17 as the same is inserted into the clamp. To insure positive gripping of the conductor wire by the metallic jaws 18 and 18a the latter are urged toward one another into a biting contact with the conductor wire 20 by means of the joint action of the internally tapered surface of the outer housing 16 and a compression spring 24 inserted between the base of the jaws 18 and 18a and the base of the outer housing 16.

It will be noted that with such construction, the terminal clamps provide easy entrance into the chuck assembly. Once the conductor is inserted therein, however, the same is locked into engagement. Tension on the conductor merely operates to increase the biting engagement of the jaws with the conductor.

In order to render the above described assembly suit-, able for use as an ultra high voltage insulator having the requirements hereinabove set forth, the inner dielectric member 10 and the metallic terminal clamps 11 and 12 are covered (preferably by moulding) with a dielectric sheath 25 having high dielectric strength. A dielectric `material found suitable for this purpose is known as polyethylene The end extremities of the outer dielectric insulating sheath 25 are reduced in diameter and externally threaded to engage a pair of bullet shaped

end caps

21 and 22.

Caps

21 and 22 are preferably made from a suitable plastic material, such as lucite, and are internally threaded to engage the threaded ends of the outer dielectric insulation sheath 25, and are provided with axial openings formed in their tips to permit the passage of conductors 17 therethrough. In addition,

end caps

21 and 22 are shaped, tapered to a small diameter at their tips, to provide maximum smoothness and streamlining of the exterior surface of the insulator assembly.

The adjacent ends of the outer dielectric insulating sheath 25 and the

end caps

21 and 22 are internally recessed, as indicated at 30, along a portion of their respective lengths to accommodate respective elongated cylindrical packing glands, 23 and 26. These glands are made of rubber-like material such as polyisobutylene having good dielectric strength, and are so dimensioned in thickness and length, with respect to the internally recessed portions 30 into which they fit as to compress into a snug fit with the insulating sheath 17a of the associated conductor 17 when the end caps are threaded down tightly onto the outer insulating sheath 2S.

In the assembling of the

end caps

21 and 22 it is irnportant to eliminate all air pockets in the channel, or internally recessed portions 30, of the end caps and outer sheath 25. To this end a semi-solid, or jelly-like, dielectric may be injected or applied to the internally recessed portions of the outer dielectric sheath 25 and the

end caps

21 and 22 before assembling.

An alternate embodiment of the invention is illustrated in Fig. 2. In this figure the insulator unit is designed to maintain conductor 17 connected thereto under which are similarto those employed in'V the -construction of the insulator of Fig. 1 and further description thereof is believed unnecessary. lnt'this embodiment one of the terminal clamps 12 has been replaced by a solenoid spring assembly 31 enclosed within a suitable metallic tubular housing 32 which is threadably attached at one end by means of end plug 33 to the inner dielectric member 10. Coaxially disposed within the solenoid spring 31 is a suitable metallic plunger rod 34 which carries at its end adjacent the inner insulator a suitable washer and nut assembly 35 for engagement with the spring 31. The opposite extremity of the rod 32 is provided with an eyelet 36 formed therein to provide a suitable external connection for the insulator. Positioned at the end of the assembly within the tubular spring housing 32 is a second end plug 37 arranged with a central bore serving as a guide for the plunger rod 34. ln this construction tension applied to either the conductor 17 or the plunger 34 serves to compress the spring 31 between the end plug 37 and the washer 35 to thereby maintain conductor 17 taut.

As in Fig. l the inner dielectric member 10, the chuck assembly 11, and the spring tension unit are all covered with a dielectric sheath which is adapted to provide high dielectric strength.

A variant embodiment of the tension insulator described above is illustrated in Fig. 3. This insulator assembly is useful in instances Where the conductor 17 is to be grounded. To this end the inner elongated d ielectric member 10 is replaced by a tapered metallic collar 40. Collar 40 is internally threaded to provide a screw threaded engagement with the chuck assembly 11 and the end plug 33 of the spring tension assembly. With this arrangement there is provided a direct conductive connection between the conductor wire 20 of yconductor 17 and the plunger rod 34.

Although I have shown anddescribed only limited and specific embodiments of the present invention, it is to be` understood that I am fully aware that there are many modications4 possible thereof without departing from the spirit of the invention.

The invention described herein may be manufactured and used by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.

What is claimed is:

1. A high voltage insulator comprising an elongated inner dielectric member of high mechanical strength, connector means attached to each end of said inner member and extending away therefrom, an outer dielectric sheath of high dielectric strength covering said inner member and said connector means, said outer sheath being provided with an opening formed therein adjacent each of said connector means and non-conducting cap members threadably positioned over each of said openings, each of said caps being provided with an opening formed therein through which an insulated wire may pass for engagement with said connector means.

2. A high voltage insulator comprising an elongated inner body member of high mechanical strength, connector means attached to each end of said inner member and extending away therefrom, an outer dielectric sheath of high dielectric strength covering said inner member and said connector means, said outer sheath being provided with an opening formed therein adjacent each of said connector means, and non-conducting cap members threadably positioned over each of said openings, each of said caps being provided with an opening formed therein through which an insulated wire may pass for engagement with said connector means, said cap members and said openings in said outer sheath being provided at their engaging ends with similar internally recessed portions, and a resilient insulating bushing adapted for insertion in said internally recessed portions whereby tightening of said caps will canse said bushings to be compressed into a snug fit with said insulated wire.

3. A high voltage insulator comprising a self-locking connector means, an elongated spring loaded plunger assembly, said plunger formed at one extremity thereo with a suitable anchoring terminal, means mechanically joining said connector means to said plunger assembly whereby movement of said .connector is opposed by the action of said plunger assembly, and an outer dielectric sheath of high dielectric strength covering said connector and plunger assembly, said outer sheath being provided aty `theposition of said connector with a threaded opening', and a non-conducting cap member adapted to threadably engage said threaded opening of said outer sheath, ,said cap being provided with an opening therein through 'an insulating sheathing having'high dielectric strength `covering said body portion and said connector device,

an opening formed in said sheathing at the location of said connector for receipt of the antenna wire, and an insulating cap member surrounding thel opening in said sheathing and having a bore therein through which the insulated antenna wire must pass for engagement with said connector device.

5. A high voltage insulator for an insulated wire antenna comprising, a main body portion, a connector device attached to said body portion, an insulating sheathing' having high dielectric strength formed over said body portion and said connector device, an opening formed in said sheathing at the location of said connector device through which the antenna wire may be threaded for engagement with said connector device, and an insulating cap member attached to the sheathing and surrounding the opening in said sheathing and having a bore therein through which the insulated antenna wire must pass for engagement with said connector device.

6. A high voltage insulator for an insulated wire antenna comprising, a main body portion, a connector device attached to said body portion, an insulating sheathing having high dielectric strength formed over said body portion and said connector device, an opening formed in 'said sheathing at the location of said connector device through which the antenna wire may be threaded for engagement with said connector device, and a dielectric sealing means surrounding the opening in said sheathing, said sealing means having a bore therein through which the insulated antenna wire must pass for engagement with said connector device.

7. An insulator for use in anti-static antenna systems, said insulator comprising an inner dielectric member of high mechanical strength, terminal connector means secured at opposite ends of said inner dielectric member and extending therefrom along the longitudinal axis of said insulator, said connector means including means for attaching the ends of insulated wires, and an outer dielectric sheath of high dielectric strength covering said inner dielectric member and said connector means and having in its opposite ends openings extending along said longitudinal axis and communicating with said connector means for snugly receiving such insulated wires for attachment to said connector means.

References Cited in the le of this patent UNITED STATES PATENTS 388,487 Harris Aug. 28, 1888 743,346 Swain Nov. 3, 1903 833,252 Schwennker Oct. 16, 1906 861,149 Varney July 23, 1907 937,896 Varney et al. Oct. 26, 1909 937,897 Varney Oct. 26, 1909 1,069,051 Woodlock July 29, 1913 1,324,994 Benjamin Dec. 16, 1919 1,751,826 Marshall Mar. 25, 1930 2,223,198 Zittrich et al. Nov. 26, 1940 2,434,658 Katz Jan. 20, 1948 2,441,309 Cook May 11, 1948 FOREIGN PATENTS 254,401 Great Britain July 5, 1926