US2438489A

US2438489A - Cable terminal

Info

Publication number: US2438489A
Application number: US522573A
Authority: US
Inventors: Victor J Andrew
Original assignee: Andrew LLC
Current assignee: Commscope Technologies LLC
Priority date: 1944-02-16
Filing date: 1944-02-16
Publication date: 1948-03-30
Anticipated expiration: 1965-03-30

Description

March 30, 1948. V. .LAANDREw 2,438,489

CABLE TERMINAL Fi-led Feb. 16, 1944 J4 J6 a/5417 1519 @75. Q14 J6 1517 f5 INVEN TOR.

Patented Mar. 30, 1948 CABLE TERMINAL Victor .1. Andrew, Chicago, Ill., assigner, by mesne assignments, to Andrew Corporation, Chicago, Ill., a corporation of Illinois Application February 16, 1944, Serial No. 522,573

Claims. 1

The present invention relates to cable terminals and more particularly to a coaxial conductor` terminal such as used for the transmission of relatively high radio frequencies.

Coaxial cables and concentric conductors are used for the transmission of high frequency radio currents and for such transmission it is desirable to maintain the impedance of the cable or line substantially constant. This is accomplished by sealing the ends of the cable or line and filling the inside of the cable with a dry aeriform suby stance such as dehumidiled air or nitrogen. It

is common to provide a supply of the aeriform substance under pressure so that the substance in the cable is at a slight pressure to prevent condensation therein due to the action known as breathing which results from temperature changes. In order to seal such cable or concentric conductor line it is necessary to provide a proper termination for the cable which does not abruptly change the impedance. It therefore is necessary to minimize shunt capacity which obviously of course is increased by the presence of an insulator.

In accordance with the present invention an insulator is provided which has a relatively good high frequency insulating characteristic and which introduces a minimum amount of shunt capacity between the inner and outer conductors of the cable. Hence the reactance of the insulator is maintained relatively high.

It therefore is an object of the present invention to provide an improved type of cable terminal for coaxial cables.

It is another object of the present invention to provide a sealed coaxial cable terminal which may be readily installed by technicians without the use of special skills or apparatus. Other and further objects of the present invention subsequently will become apparent by reference to the following description taken in connection with the accompanying drawing wherein Figure 1 is an external view of a coaxial cable terminal placed in position at the end of a coaxial cable;

Figure 2 is another view of a coaxial cable terminal partly in cross section to illustrate its structure and the manner in which the cable is secured to the coaxial conductor; and

Figure 3 shows a modified form of the terminal shown in the other gures which is particularly suited for the smaller size coaxial cables.

Referring to Figures 1 and 2 there is shown a cable terminal associated with a coaxial line having an outer conductor I I and an inner conductor I2 which may be supported therein by suitable .bead insulators ,I3 arranged at spaced intervals along the conductors. The outer conductor II is suitably bonded to an outer supporting sleeve I4 which may be provided with a threaded portion I5 upon which suitable mounting or lock nuts I6 are positioned. The forward end of the sleeve I4 is bonded to a cylindrical metal member I1 which in turn is bonded to a-dome shaped glass insulator I8. The dome shaped glass insulator I8 at the top of the dome is bonded to a cylindrical member I9 which is electrically connected to the inner coaxial conductor I2 and to a threaded stud portion 2I which is provided with suitable nuts 22 and washers 23 for supporting a wire terminal 24.

As may be seen from Figure 2 the dome shaped glass insulator I8 surrounds one edge 25 of the cylindrical member I1. The cylindrical member I1 is made of metal alloy which has a temperature coefficient compatible with or substantially equal to the temperature coefilcient of the insulating dome I8. While the edge 25 of the cylindrical member I1 is of lesser thickness than the body of the cylindrical member I1, the edge 25 need not be feathered or in other words reduced in cross section so as to have a knife edge. The inner end of the sleeve I9 terminates in a flanged portion 26 which is tapered appreciably but not necessarily to the extent of providing a sharp knifelike edge so that the glass I8 may surround both sides of the flanged portion 25. The member I9 is also formed of a metal similar to the metal used for the cylindrical member I1 so that the insulating dome I8 is securely bonded thereto.

Since the metal used for the cylindrical members I1 and I9 is more expensive than other metals, and furthermore requires skilled technique to bond such metal to another metal such as the copper or bronze used in a coaxial cable or lines, the sleeve I1 fits into a recessed portion 21 adjacent one end of the sleeve I4 which may be provided with a shoulder portion 28 for limiting the inward movement of the sleeve I1 and also the inward movement of the outer coaxial conductor II. The sleeve I4 preferably is made of brass or some metal or alloy which may be readily bonded to the outer coaxial conductor II by soft soldering. The cylindrical metal member I1l is bonded to the sleeve I4 by any suitable process such as welding, brazing, or silver soldering. Such brazing or silver soldering is indicated by the lillet 28.

In order to facilitate the connection between the cylindrical member. I9 and the inner conductor I2, the cylindrical member I9 ls provided with an internal sleeve 3| of brass, copper, or the like which in turn is bonded to the cylindrical member I9 in any suitable manner including the methods mentioned for joining the cylindrical member l1 with the sleeve I4. In order to prevent undue mechanical stress from being applied to the insulator I8 which possibly might fracture or otherwise injure the insulator, it is preferable to connect the wire terminal 24 to the threaded stud 2| by means of nuts 22 prior to the time that the stud 2| is mounted in position relative to the cylindrical sleeves I3 and'3l. The stud 2| therefore is provided with a reduced cylindrical portion .32 adapted to fit within the sleeve 3|. The inner conductor I2 of the coaxial cable extends into the sleeve 3| a portion of its distance, and prior to insertion thereto the end of the conductor l2 preferably .is tinned with solder. Similarly the reduced portion l3| may be tinned before insertion into the sleeve 3|. Thereafter heat may be applied to the cylindrical member |9 so as to bring about a sweatedsoldered joint. The heat required to form the sweated soft solder joint is considerably less than the heat required to introduce any adverse strains or eiects in the glass insulator |8.

The glass used for the dome shaped insulator seal I8 is of a material having a certain desired temperature coeicient which may be matched by a special metal alloy of chromium, nickel, and iron. This combination provides a proper seal between glass and metal, and the alloy metal surfaces are then bonded by brazing, welding, or soldering to other metal parts which may be joined to the coaxial cable by soft soldering. lf a. low temperature solder containing sixty per cent tin and forty per cent lead is used, there is no danger of cracking the glass insulator from the heat of soldering. While glass does not have as good high frequency insulating qualities as other insulating materials, the Vvolume of the glass between the inner and the outer conductors is maintained at a minimum where obviously the electric field is the greatest and hence the dielectric losses are much less than the losses encountered if a ceramic insulator were used for a terminal. For example at 400 megacycles an ordinary ceramic insulated terminal may present a capacity of 50 micromicrofarads corresponding to a reactance of 8 ohms. Assuming that the load into which the cable is operating is a '10 ohm resistive load, this load will receive a negligible portion of the transmitted power since for all practical purposes the cable is practically shorted at its terminal end. With a terminal of the type shown and described there is but a very small shunt capacitance and a very small series inductance, the effects of which may readily be balanced out. It therefore will be appreciated that there has been provided a cable terminal which gives satisfactory high frequency performance and which provides a permanent leak-proof terminal.

The modification shown in Figure 3 is particularly suited for the smaller sizes of coaxial cables and lines. In this modification the glass insula- Ator 33 is secured to a cylindrical metal member 34 which fits into a recess 35 adjacent a shoulder 38 formed within an externally threaded member 31. 'Ihe externally threaded member 31 is provided with a cylindrical internal bore 38 adapted to receive the outer conductor of a coaxial cable. The member 31 is formed of a material such as brass or copper so that it may be secured to the outer conductorof the coaxial line or cable by soft solder. The member 31 is bonded to the cylindrical member 3d by welding. brazing, or silver soldering as indicated by the fillet 39. The other end of the dome shaped insulator 33 is joined to a flanged portion 4| formed at one end of'a hollow externally threaded member d2. The member 42 is also made of a metal alloy having a temperature coefilcient substantially equal to or compatible with the temperature coeiilcient of the i dome shaped glass insulator 33. In order that the member 42 may be secured by soft soldering to the inner conductor of a coaxial line or cable, one end of the member 42 is provided with a recessed portion 43 in which is mounted a sleeve 44 which sleeve is formed of brass or copper. The sleeve 44 1s bonded to the member 42 by brazing, welding, or silver soldering. The modification thus illustrated is particularly adapted for smaller coaxial conductors or cables in the vicinity of one quarter inch.

While for the purpose of illustration and explanation certain specific embodiments of a coaxial line or cable terminal have been shown. it is to be understood that variations may be made in the arrangement of the components and in their structure as may be commensurate with the scope and spirit of the invention set forthin the appended claims. n

The present invention is hereby claimed as follows:

1. A sealed terminal unit for concentric conductors comprising two sleeves of dlerent size adapted to be bonded to the inner and outer conductors of concentric conductors in linear spaced apart positions, a hollow insulating member interposed between said sleeves, and a plurality of metal members each having a'temperature coeicient compatible with the temperature coeirlcient of said insulating membensaid metal members each being bonded to said insulator and to one of said metal sleeves.

2. A sealed terminal unit for a transmission line having concentric conductors comprising two metal sleeves of different size adapted to be soldered to the inner and outer conductors of said concentric conductors in linear spaced apart relation, a dome shaped thin walled hollow glass insulating member interposed between said sleeves, and metal members having a temperature coeftlcient substantially equal to the temperature coefficient of said insulating member, said metal of said cylindrical metal members, a metal sleevev of a different metal adapted to be bonded to the inner coaxial conductor, said latter metal sleeve being bonded to the smaller one of said cylindrical metal members.

4. A gas tight sealed terminal unit for connection to a coaxial line comprising an apertured dome shaped glass insulator bonded to two cylindrical metal members of different diameters, said metal members having a temperature coefficient substantially equal to the temperature coefficient of said insulator, a metal sleeve of` a different metal capable of being bonded by soft solder to the outside of the outer conductor of a coaxial line, said metal sleeve being bonded to the larger one of said cylindrical metal members, another metal sleeve of a material capable of being soft soldered to the inner coaxial conductor, said latter metal sleeve being bonded to the smaller one oi said cylindrical metal members. A

5. A gas tight sealed terminal unit for connection to a coaxial line having two concentric conductors comprising' an apertured dome shaped thin walled hollow glass insulator, two cylindrical metal members of different diameters having' a temperature coefiicient substantially equal to the temperature coefiicient of said insulator, the smaller one of said metal members being bonded to the aperture of said dome shaped glass insulator, the other oi said metal members being bonded to the other end oi' said dome shaped glass insulator, a metal sleeve of a different metal adapted to receive and to be soldered with soit solder to the outside diameter of the outer conductor of a coaxial cable, said metal sleeve being bonded to the larger one of said cylindrical metal members, a second metal sleeve oi a different metal adapted to receive and to be soldered with soft solder to the-inner coaxial conductor, said one oi' said first mentioned cylindrical metal members.

VICTOR J, ANDREW.

REFERENCES CITED The following references are of record in the le of this patent:

` UNITED STATES PATENTS Number Name Date 2,144,222 Hellman Jan. 17, 1939 2,322,233 Granger June 22, 1943 1,814,851 Prince July 14, 1931 2,127,408 Kaar Aug. 16, 1938 1,888,071 Case Nov. 15, 1932 2,210,699 Bahls Aug. 6, 1940 1,575,994 Laise Mar. 9, 1926 2,299,750 Hull et a1. Oct. 27, 1942 FOREIGN PATENTS Number Country Date 685,211 Germany Dec. 14, 1939 OTHER REFERENCES Serial No. 532,040, Gonnington (A, P. 0.), published May 18, 1943.