US3813639A

US3813639A - Electrical connection for high voltage electrical systems

Info

Publication number: US3813639A
Application number: US00238562A
Authority: US
Inventors: G Schurter; Luca C De
Original assignee: Deutsche ITT Industries GmbH
Current assignee: Thomas and Betts Holdings Inc; ITT Inc
Priority date: 1972-03-27
Filing date: 1972-03-27
Publication date: 1974-05-28
Anticipated expiration: 1991-05-28
Also published as: CA992175A

Abstract

Disclosed is a non-vented electrical connector designed to mate with a connection to a transformer or the like in a primary power distribution system. The connector will mate with and make electrical connection with a load break terminator as used in such systems, so that an electrical circuit carrying high currents at elevated voltage levels may be broken in the field without harm to the service personnel making and breaking the connection. The connector has internal members for suppressing the arc generated by high current, high voltage circuit openings and closures. In addition, the connector has internal structure for rapidly condensing and diffusing gases formed within the connector by an arc. In this way, the gas pressure developed in the connector is relieved to prevent pressure blowouts of the terminator. The gas condensing structure shown includes further, a multiple thickness tubular screen, which may be comprised of a length of fine mesh screen coiled into a tubular form. In addition, the connector has an internal scraping member which contacts the arc follower and removes surface contaminants to prevent such contaminants from adding to an arc and to prevent secondary arcing due to the presence of such contaminants in the path of an arc.

Description

United States Patent 1 1 Schurter et al.

[111 3,813,639 1451 May 28, 1974 1 1 ELECTRICAL- CONNECTION FOR HIGH VOLTAGE'ELECTRICAL SYSTEMS [75] inventors: Gary LeeSchurter, Kirkwood; Carlo Bruno DeLuca, Chesterfield, both of 73] Assignee: International Telephone-and Telegraph Corporation, New York,

221 1 Filed: Mar. 27, 1972 21 Appl. No.: 238,562

[521' US. Cl. 339/111, 174/73 [51] Int. Cl H01! 13/52 [58] Field of Search 339/111, 143 R, 143 L,

339/143 5, 143 T, 95 R, 59 R, 59 L, 59 M, 5012, 60 13 60 M, 6l R, 1 c, 61L, 61 M;

Primary,ExaminerBobby R. Gay

Assistant ExaminerRobert A. Hafer Attorney, Agent, or FirmJames B. Raden; Marvin M. Chaban [5 7] ABSTRACT Disclosed is a non-vented electrical connector de signed to mate with a connection to a transformer or the like in a primary power distribution system. The connector will mate with and make electrical connection with a load break terminator as used in such systems, so that an electrical circuit carrying high currents at elevated voltage levels may be broken in the field without harm to the service personnel making and breaking the connection. The connector has internal members for suppressing the arc generated by high current, high voltage circuit openings and closures. In addition, the connector has internal structure for rapidly condensing and diffusing gases formed within the connector by an arc. 1n this way, the gas pressure developed in the connector is relieved to prevent pressure blowouts of the terminator. The gas condensing 7 structure shown includes further, a multiple thickness tubular screen, which may be comprised of a length of fine mesh screen coiled into a tubular form. In addition, the connector has an internal scraping member which contacts the arc follower and removes surface contaminants to prevent such contaminants from adding to an arc and to prevent secondary arcing due to the presence of such contaminants in the path of an arc. 1

16 Claims, 6 Drawing Figures PATENTEB MAY 28 1974 A Z x I Q PAIENTEDIM 28 um sum 2 or 2 FIG. 6

ELECTRICAL CONNECTION FOR HIGH v VOLTAGE ELECTRICAL SYSTEMS BACKGROUND OF THE INVENTION The present invention is designed to receive a load break terminator of the type disclosed in co-pending application Ser. No. 85,651, filed on'Oct. 30, 1970, by R. A. Strain, for Waterproof High Voltage Connection Apparatus" andassigned to the assignee hereof. In the application noted, there is shown an elbow terminator which, in oneform, may be rated at standard 200 amp, 8.3 kv for connecting a shielded cable detachably in conjunction with a suitable plug to a power transformer or the like. For effecting the electrical contact with the connector the terminator has a central conductive electrode with an arc follower pilot rod at its exposed tip. The are follower, as mentioned, has an elongated tip or rod of arcsuppressing dielectric material.

Arc followers are designed to enter the axial cavity of a connector. The connector, as mentioned, may be electrically connected at its other end to a distribution transformer and thus must carry heavy current at elevated voltages from thetransformer to the terminator. During entry of the terminator electrode into the connector cavity, first the suppressor and then the conductive body of the electrode will pass through a tube of arc suppressant or are snuffing material until the conductive body of the electrode electrically contacts a female body; member'of conductive material.

The connection between the terminator and the connector is designed to be closed and opened under nominal power distribution voltages and currents, with the power on. With voltages and amperages of the magnitudes, as is known in mean, arcs are generated during the passage of the terminator electrode into and out of the connector. The are suppressant materials are used to cut down the arc but they do not completely suppress the arc and, as a result, there may be a rapid internal pressure buildup in the connector cavity.

It is, of course, well known in the art that arcgenerated pressure within a closed connector cavity, if unrelieved, can shove the elbow or terminator back out of the connector with a snap-action speed, opening the circuit, and possibly harming the person opening or closing the circuit.

" To relieve such pressure within the connector cavity, some systems have used venting to the outside of the connector. in some cases, two compartments are formed within the connector cavity. The compartments are connected to one-way valves designed to blow out under heavy pressure and thus vent the pressure from the first compartment to the second compartment after dissipating some of the pressure.

Other systems have employed a flexible cable connected to a slidable femaleconductive structure. On the occurrence of arcing and its resultant internal pressure within the connector, the pressure tends to generate piston action forcing the female structure to advance rapidly toward the arc follower conductor. Rapid advance of the female structure will cause the followerto-connector circuit to close rapidly, thus terminating the arc. The flexible cable maintains the closed circuit condition between the female structure to the trans former.

These solutions require moving parts such as valves and pistons and generate internal movements resulting from arc-induced pressure. Naturally, any system which tends to subject pistons and valves to elevated temperatures and pressures will tend to have a short life and may readily fail in service. Any system which does not rely on moving parts will be more capable of providing more foolproof action capable of continuous positive service, at reasonable cost.

SUMMARY OF THE INVENTION The present invention provides a non-vented, loadbreak connector for connection to a power distribution member such as a transformer by means of a stud connection or the like. The connector is capable of detachably receiving at its other end a load break terminator for connection to a primary line comprisinga grounded shield cable.

The connector is designed to permit the terminator to be safely connected and disconnected from the bushing with nominal power distribution voltages and currents energized. Also, with nominal distribution fault current ready to flow through the connection at the start of connect, the connector may bedamaged but the operator performing the connecting should not be harmed, provided the circuit is protected by adequate circuit protection devices.

The are suppression features used herein include the use of an arc snuffer tube within the connector entry area for receiving the arc follower of the terminator electrode to aid in suppressing a generated are. In addition, at the rear of the connector cavity, there is provided a coaxially disposed configured connector plug end opposing an arc-generated pressure wave. Within the plug end is fitted one 'end of a mesh screen multiple I thickness tube. The tube opening is in communication with the cavity of the connector in which an arc would be formed so that produced gases enter the tube core. The mesh screen of the tube rapidly condenses the gases to relieve the pressure in the bushing cavity. The large surface area of the screen within the tube enables the screen to condense a large volume of gas in a short span of time and thereby dissipate the internal pressures within theconnector.

In addition, there is provided intermediately within the connector, a scraper ring of arc suppressant dielectric material positioned to engage the wall of the arc follower and scrape contaminants from the follower during making or breaking of the circuit. By removing contaminants, the problems of secondary arcing and continuation of the main are due to the pressure of contaminants is reduced to a minimum.

It is, therefore, an object of the invention to provide a new and improved connector for use with a load break terminator.

It is a further object of the invention to provide a connector within which a heavy power carrying circuit can be made and broken safely.

It is a further object of the invention to provide a load break connector with improved internal pressure relieving structure.

It is another object of the invention to provide a load break connector in whose internal cavity is mounted a gas condensing and cooling structure.

These and other objects, features and advantages of the invention will become apparent from the following specification viewed in conjunction with the accompanying drawings.

BRIEF'DESCRIPTION OF THE DRAWINGS of the connector of FIG. 1;

FIG. 4 is a sectional view through the arc snuffing member of FIG. 1;

FIG. 5 is a sectional view taken along lines 5-5 of FIG. 3; and

FIG. 6 is a side elevational view of a load break connector partially broken away to show the interior of a second embodiment of the invention.

DETAILED DESCRIPTION OF THE DRAWINGS Turning to the drawings, in FIG. 1, we show a load break elbow terminator 10 of the type shown in copending U.S. Patrapplication Ser. No. 85,651, filed Oct. 30, 1970 by R. A. Strain, and assigned to the assignee hereof. The load breakterminator is of the type which is connected at one end to the conductor of a grounded sheathed cable 16. The cable is connected to a conductive member-or splice within the terminator dielectric and semiconductive housing (as described in the cited reference). The conductive member is, in turn, rigidly connected to a central conductive electrode 14 in rod form coaxially disposed within a hollow tubular open end of the housing 12. The electrode 14 is recessed from the open end 18 of the housing and has connected to its outer end a dowel rod 20 of suitable arc suppressant dielectric material. The follower acts as a pilot or guide for the electrode and serves an arc suppressing function, as is well known in the art.

The'connector 30, one form of which is shown in FIGS. 1-3, is designed to matewith the terminator 10. The connector has an outer dielectric housing 32 which may be molded rubber. The housing incorporates a molded-on" ground shield which will establish a ground plane about the exposed portion of the connector upon installation, and decreases the electrical stress field level in that'area. The insulation of the housing may be pressure molded rubber and the ground shield may be of a semi-conductive elastomer. This housing has an entry end sized to mate with and fit snugly into the open end of terminator housing 12. Fitted tightly within the connector housing 32 is an open-ended copper tube or body shell 34. The open mouth end 36 of shell 34 is recessed from the entry opening of the housing to eliminate the risk of any inadvertant contact. The tube or shell extends in a plurality of progressively stepped or tapered

sections

38, 40 and 42 of greater diameter to its open remote end 44, as will be described later.

The entrance to the tube adjacent mouth end 36 is internally threaded at section 50 to receive a complementarily threaded tube-like arc snuffer 52, shown in detail in FIG. 4. The arc snuffer 52 may be fabricated of arc suppressant material like that of the arc follower rod of the terminator and is designed to remain in the connector until replaced. A suitable material for use in the arc snuffer is a material composed of polyoxymethylene with glass fiber or borosilicate filler. The are snuffer is suitably externally threaded along its outer surface 54 to mate with the threaded copper tube at section 50. The snuffer has central bore 56 sized to receive the terminator arc follower rod 20 and also the terminator electrode 14. The outer end 58 of the snuffer bore is internally chamfered to receive and guide the follower rod 20, and its periphery is flared at flange 59 to rest against the opening of the connector housing 32.

Within copper tube 34, as seen best in FIG. 2, there is fitted a tubular female contacting member or receiving electrode 60 fabricated of copper or the like, which has a rear body portion 62 fitted tightly and suitably crimped within the adjacent body section 38 of tube 34. The receiving electrode 60 has as its forward end an inwardly tapered terminator electrode receiving section 64 spaced from the innermost edge 66 of arc snuffer 52. The receiving section is slitted with two diametrically spaced slits 70 extending from the receiving mouth end 72 to a line near its body portion 62. The slits produce a resilient mouth end, the mouth end terminating in an out-turned lip 74 which serves as a retainer for the holding ring or washer 76. Ring 76, which may be fabricated of tin-plated metal, is fitted about the outside of the female contacting member 60 adjacent its mouth end to limit the expansion of this slitted end of the contacting member in response to spreading forces.

.The copper tube or shell 34 tapers outwardly in a rearward direction from body section 38 through the tapered section 40 to the enlarged end section 42. Section 4 is of length slightly longer than its diameter, its inner diameter being approximately twice that of snuffer tube 52. Section 42, in turn, leads to the inturned rearmost end 44 of shell 34. Within end 44 is mounted an end plug of cylindrical shape sized to fit tightly within the shell end. The end plug 80 has a body of some thickness which may be copper or the like and has a threaded bore 82, coaxial with the shell axis. In fabrication of the shell 34, the end plug may be inserted within section 42and the remote end 44 formed over the curved edge 84 of the plug to firmly lock the end plug in place, leaving the bore 82 open for connection to a conductive stud (not shown).

End plug 80 has a toroidal slot in its inner wall 92, the slot 90 being concentric about the bore 82. By providing slot 90 in the otherwise smooth plug surface, we provide a configured or roughened wall in'the path of a pressure wave to break up the wave and thereby aid in diffusing the generated pressure. To enhance these effects, we further use slot 90 to seat one end of a tubular screen member 94. Screen member 94 may comprise a length of fine mesh screening rolled or coiled into a tight cylindrical tube 96 having a number of thicknesses of screen comprising the wall thickness of the cylindrical tube.

We have found that a screen of 20 square mesh, 0.015 inch diameter wire, preferably copper, with a plurality of thicknesses wound into tubular form performs quite satisfactorily. Further, we have found that even superior pressure relieving characteristics result if we plate the screen with a plating of a metal of the transition metal grouping such as nickel, platinum, or palladium, the plating being up to 0.001 inch thick.

As mentioned in the preferred form, we use a spirally wound tube, and to hold the spiral screen together, one

half inches or more. I

The principle of operation of our invention may be summarized as follows: When a circuit between the electrode 14 of the terminator and the receiving electrode 60 is either being opened or closed, an arc is generated which will be partially suppressed by the arc follower 18 and the snuffer 52. Such an arc will tend to generate a high pressure wave within the connector shell cavity. This wave will pass down the shell and will enter the expanded cavity section 42 and will thereby be somewhat reduced in intensity. The wave will also reach the screen 94. The large available surface area on the screen will buffer the pressure wave. In addition, the niany screen sheet ends confronting the wave will even further buffer and diffuse the pressure wave. The screen will tend to condense and cool the gas on its multiplicity of surfaces. Further, the configured nature of the screen inconjunction with the slotted face of end I plug 82 will soften and break-up the shock wave. While other screen configurations are possible, we find that a single spiral sheet wound into a multiplethickness tube I provides excellent shock wave dissipation and condensation of the gas pressure wave. With the pressure dissipated and the gas cooled, the circuit may be readily closed or opened in the energized condition with no adverse reaction to the intended action.

: As mentioned, previously, we find that by plating the sheet of screen 94 with either nickel, platinum or palladium prior to assembly, the plating material acts as a catalyst to speed the condensation and cooling of the gas on the screen mesh.

In FIG. 6, we show an added feature of our invention. In this figure, we show a connector similar to that of the prior FIGS. l-5, with its outer dielectric housing 32, a copper shell 34, a screen tube 96 and a modified receiving electrode 160 corresponding to receiving electrode 60 of the first embodiment.

The receiving electrode 160 adjacent its inward end has a section internally threadedas indicated by the reference character 161. Mated with the threading 161 is an externally threaded scraping member 163. Member 163 is threaded into the connector and presents its bore 165 to the arc follower rod 18 of the terminator. The bore 165 is tapered from its minimum diameter 167 at the end adapted to receive the follower rod 18 and the bore tapers outwardly therefrom. The minimum diameter 167 is sized to provide an interference lit with the follower of approximately 0.002 inch to 0.004 inch at diameter 167. The maximum diameter at the rear end of the scraperbore may be in the range of 0.010 inch clearance fit. Thus, the scraper receives the rod tightly and scrapes from the rod all contaminants.

If contaminants or adhering bits of conductive material or dielectriematerial are picked up by the rod inwardly of the minimum diameter edge of the scraper 6" scraping action further tends to minimize the arc and thereby reduce the pressure in the connector cavity. Preferably, the scraping member is fabricated of arc suppressant dielectric material similar to that of arc follower 18 and snuffer 52.

While there has been described what is at present thought to be the preferred embodiments of the invention, it is understood that modification may be made therein, and it is intended to cover in the appended claims all such modifications which fall within the true spirit and scope of the following claims.

We claim:

1. A connector for receiving a load break terminator having a central conductive electrode, said connector comprising an electrode for receiving said terminator electrodethrough an open face at one end of said connector and for engaging said terminator electrode to complete a current transmitting path therebetween,

a conductive body in said connector for completing a heavy power transmitting path from said receiving electrode to a connecting member at the remote end of said connector,

a housing surrounding said conductive body to enclose said conductive body and produce an otherwise closed cavity therein,

an arc suppressant member adjacent the open face of said connector for receiving said terminator electrode prior to entry and after removal of the terminator electrode from the receiving electrode, said body, including a sidewall tapering from said open face end to produce a flow path of successively increasing section, a pressure relieving member within said conductive body cavity, said relieving I member comprising a tubular member of mesh screen,

means positioning said member said body cavity substantially concentrically within said flow path adjacent said remote end to receive and condense a pressure wave generated by an arc during entry or removal of said terminator from said connector.

2. A connector as claimed in claim 1, wherein said tubular member comprises a metallic, mesh screen wound spirally into tubular form.

3. A connector as claimed in claim 1, wherein said tubularmember is fabricated of a sheet of fine mesh copper screening configured into tubular form.

4. A connector as claimed in claim ll, wherein said tubular member comprises a copper mesh screen tube plated with a transition metal.

5. A connector as claimed in claim 3, wherein said tubular member comprises a nickel-plated sheet of screen material.

6. A connector as claimed in claim 3, wherein said tubular member comprises a platinum-plated sheet of screen material.

7. A connector as claimed in claim 3, wherein said tubular member comprises a palladium-plated sheet of screen material.

8. A connector as claimed in claim 1, wherein there is interposed between said connector and said tubular member a tubular scraping edge of dielectric material axially aligned in said cavity to engage the arc follower in surface contact therewith, and a surface positioned to deposit material scraped from said follower adjacent said screen.

9. A receivingconnector for a load break terminator having a central conductive, rod-shaped electrode with an arc follower at the exposed end thereof,

said connector comprising an annular receiving electrode for receiving said terminator electrode through an open face at one end of said connector and for engaging said terminator electrode to complete a current transmitting path between said electrodes,

a conductive body in said connector for completing a heavy power transmitting path from said receiving electrode to a connecting member at the remote end of said bushing,

an arc suppressant member adjacent the open face of said connector for receiving said terminator electrode prior to entry and after removal of the tenninator electrode from the receiving electrode,

and a pressure relieving member within said conductive body cavity,

and a scraping member disposed coaxially of said receiving electrode,

means mounting said scraping member inwardly of said receiving electrode in position to engage said terminator electrode and follower,

said scraping member comprising a ring sized to interferingly receive the arc follower and scrape materials therefrom,

said scraper member tapered from said ring to deposit scraped materials rearwardly of said receiving electrode.

10. A connector as claimed in claim 9, wherein said scraper ring is fabricated of dielectric, arc-suppressant material.

11. A receiving connector for a load break terminator having a central conductive electrode, said connector comprising an electrode for receiving said terminator electrode through an open face at one end of said connector and for engaging said terminator electrode to complete a current transmitting path therebetween, a conductive body in said connector for completing a heavy power transmitting path from said receiving electrode to connecting member at the remote end of said connector, a housing surrounding said conductive body to enclose said conductive body and produce an otherwise closed and walled cavity therein, an arc snufi'mg member adjacent the open face of said connector for receiving said terminator electrode prior to entry and after removal of the terminator electrode from the receiving electrode, the walls of said cavity positioned to channel a pressure wave generated by an arc toward said remote end during entry or removal of said terminator from said connector, and means within said conductive body cavity for condensing and diffusing a pressure wave, said last-mentioned means comprising a contoured member contained inwardly of the axial extension of the walls of the cavity and extending into said cavity from said remote end within the path of the pressure wave to diffuse the generated pressure wave channelled thereto.

12. A connector as claimed in, claim 11, wherein said snuffing member comprises a tubular member of polyoxymethylene with structural filler material.

13. A connector as claimed in claim 12, wherein said structural filler material is a glass fiber filler.

14. A connector as claimed in claim 11, wherein said glass fiber filler is borosilicate.

15. A connector as claimed in claim 11, wherein said condensing and diffusing means comprises an enlargement in said cavity with an inner diameter at least twice that of the bore of said snuffing member.

16. A connector as claimed in claim 15, wherein said condensing and diffusing means comprises a configured end face of said cavity confronting any pressure wave generated in said connector cavity.

Claims

1. A connector for receiving a load break terminator having a central conductive electrode, said connector comprising an electrode for receiving said terminator electrode through an open face at one end of said connector and for engaging said terminator electrode to complete a current transmitting path therebetween, a conductive body in said connector for completing a heavy power transmitting path from said receiving electrode to a connecting member at the remote end of said connector, a housing surrounding said conductive body to enclose said conductive body and produce an otherwise cLosed cavity therein, an arc suppressant member adjacent the open face of said connector for receiving said terminator electrode prior to entry and after removal of the terminator electrode from the receiving electrode, said body, including a sidewall tapering from said open face end to produce a flow path of successively increasing section, a pressure relieving member within said conductive body cavity, said relieving member comprising a tubular member of mesh screen, means positioning said member said body cavity substantially concentrically within said flow path adjacent said remote end to receive and condense a pressure wave generated by an arc during entry or removal of said terminator from said connector.

3. A connector as claimed in claim 1, wherein said tubular member is fabricated of a sheet of fine mesh copper screening configured into tubular form.

4. A connector as claimed in claim 1, wherein said tubular member comprises a copper mesh screen tube plated with a transition metal.

9. A receiving connector for a load break terminator having a central conductive, rod-shaped electrode with an arc follower at the exposed end thereof, said connector comprising an annular receiving electrode for receiving said terminator electrode through an open face at one end of said connector and for engaging said terminator electrode to complete a current transmitting path between said electrodes, a conductive body in said connector for completing a heavy power transmitting path from said receiving electrode to a connecting member at the remote end of said bushing, a housing surrounding said conductive body to enclose said conductive body and produce an otherwise closed cavity therein, an arc suppressant member adjacent the open face of said connector for receiving said terminator electrode prior to entry and after removal of the terminator electrode from the receiving electrode, and a pressure relieving member within said conductive body cavity, and a scraping member disposed coaxially of said receiving electrode, means mounting said scraping member inwardly of said receiving electrode in position to engage said terminator electrode and follower, said scraping member comprising a ring sized to interferingly receive the arc follower and scrape materials therefrom, said scraper member tapered from said ring to deposit scraped materials rearwardly of said receiving electrode.

11. A receiving connector for a load break terminator having a central conductive electrode, said connector comprising an electrode for receiving said terminator electrode through an open face at one end of said connector and for engaging said terminator electrode to complete a current transmitting path therebetween, a conductive body in said connector for completing a heavy power transmitting path from said receiving electrode to connecting member at the remote end of said connector, a housing surrounding said conductive body to enclose said conductive body and produce an otherWise closed and walled cavity therein, an arc snuffing member adjacent the open face of said connector for receiving said terminator electrode prior to entry and after removal of the terminator electrode from the receiving electrode, the walls of said cavity positioned to channel a pressure wave generated by an arc toward said remote end during entry or removal of said terminator from said connector, and means within said conductive body cavity for condensing and diffusing a pressure wave, said last-mentioned means comprising a contoured member contained inwardly of the axial extension of the walls of the cavity and extending into said cavity from said remote end within the path of the pressure wave to diffuse the generated pressure wave channelled thereto.

12. A connector as claimed in claim 11, wherein said snuffing member comprises a tubular member of polyoxymethylene with structural filler material.