US3676572A

US3676572A - Extensible cable structure

Info

Publication number: US3676572A
Application number: US148650A
Authority: US
Inventors: Everett H Davies
Original assignee: Barber Colman Co
Current assignee: Schneider Electric Buildings Americas Inc
Priority date: 1971-06-01
Filing date: 1971-06-01
Publication date: 1972-07-11
Anticipated expiration: 1989-07-11

Abstract

A self-reliant cable support of plane flexible insulating material is slit from opposite ends to form elongated strips, each joined to an adjacent strip at one end to produce a serpentine path from an end rigidly mounted on a first piece of equipment, such as an instrument rack, to another end rigidly mounted on a second piece of equipment, such as a measuring or control instrument, movable linearly with respect to the first piece. Wire or other flexible conductors are affixed in a single layer to one surface of the support along the serpentine path, forming a compact extensible structure to transmit signals between said pieces of equipment.

Description

United States Patent Davies 51 July 11, 1972 [$4] EXTENSIBLE CABLE STRUCTURE [2|] Appl.No.: [48,650

[ S 6] Relerences Cited UNITED STATES PATENTS 2,060,913 11/1936 Weaver ..l74/69 FOREIGN PATENTS OR APPLICATIONS l03,556 2/1924 Switzerland ..l74/69 373,l42 4/1923 Germany ..l74/69 Primary Examiner-Darrell L. Clay Attorney-A. Richard Koch ABSTRACT A self-reliant cable suppon of plane flexible insulating material is slit from opposite ends to form elongated strips, each joined to an adjacent strip at one end to produce a serpentine path from an end rigidly mounted on a first piece of equip' ment, such as an instrument rack, to another end rigidly mounted on a second piece of equipment, such as a measuring or control instrument, movable linearly with respect to the first piece. Wire or other flexible conductors are afltxed in a single layer to one surface of the support along the serpentine path, forming a compact extensible structure to transmit signals between said pieces of equipment.

PA'TENT'EBJuL 1 1 I972 INVENTOR EVERE TT H. DA 1/155 AGENT EXTENSIBLE CABLE STRUCTURE BACKGROUND OF THE INVENTION This invention pertains to extensible conductors of electricity, light or fluid between relatively linearly movable pieces of equipment.

Measuring and control instruments are commonly mounted in racks permitting the instrument to be removed from the front of the rack for replacement, repair, adjustment, etc. The back of the rack is frequently substantially inaccessible. Permanent power, control and sensor connections are usually provided at the back of the rack so that they will be protected and not interfere with removal of the instruments. The completion of these connections to the instruments presents an annoying problem.

Some installations have employed rigid plug-in arrangements, which are often unsatisfactory because of misalignment, corrosion, interference by foreign matter, etc. Flexible connections are generally more satisfactory. The connecting flexible conductors are most frequently bundled together to limit relative movement and in lengths sufficient to allow for necessary movement, the slack being allowed to sag. The sagging bundle may interfere with movement of the connected or other instrument and may become abraded by projections. Various schemes for supporting the bundle at intermediate points have been used, including springs, arms and lazy tongs. Flat cables have been sharply bent in zigzag fashion and may be either self-supported or otherwise stifi'ened between the bends. Most of these alternatives have a disadvantage in occupying a considerable space behind the instrument.

SUMMARY OF THE INVENTION The present invention provides support for the conductor, avoids sharp bends, controls and limits flexure, protects against abrasion, provides additional electrical insulation, and provides storage in a limited space. The position of each conductor is fixed with respect to other conductors, controlling electrical interference. The structure is rugged, simple and inexpensive to manufacture.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of an extensible cable structure according to a preferred embodiment of this invention, showing how it is used with the cable structure extended.

FIG. 2 is a side view of the cable structure in use in retracted position.

DESCRIPTION OF THE PREFERRED EMBODIMENT The preferred embodiment shown in the drawings comprises a fixed piece of equipment 1, a linearly movable piece of equipment 2, and an extensible cable structure 3 in accordance with this invention connecting the pieces of equipment. The equipment 1 comprises a permanently mounted terminal board 4 having a plurality of terminals, such as screw terminals 5 and pin type solder terminals 6, mounted thereon and permanently connected to power supplies, sensors and controls (not shown). The equipment 2 (shown in part) comprises a measuring or control instrument (not shown) mounted on a chassis 7, movable linearly toward and away from the terminal board as shown by the double headed arrow. On the chassis are terminals, as in a terminal block 8, for joining with separable terminals on free ends 9', 10', 11' of connecting

wires

9, 10, ll, twisted together in a cable 12 to reduce noise, to the instrument. The other free ends 9", 10", 11" of

wires

9, 10, 11 are soldered to respective control terminals 6 on the terminal board 4.

The extensible cable structure 3 comprises a self-reliant support 13 of normally plane flexible insulating material such as nylon sheet. The support 13 is slit from one end to form a central strip 14 to be fixedly mounted at a disjoined mountable end 15 upon the terminal board 14 as by screws 16. The remaining portions are slit from the other end 17 to form

strips

18, 19, 20, 21 parallel to strip 14. Strips 19, 20 are joined at the other end 17 to strip 14, and are joined to

respective strips

18, 21 at

opposite ends

22, 23 respectively to provide a pair of mirror image serpentine paths in the support. The disjoined ends of the

outer strips

18, 21 are shown attached to a bar 24 mountable on the chassis 7 as by screws 25. A smooth circular or rounded hole 26 at the closed end of each slit relieves stress at such points to prevent tearing. The cable 12, following a serpentine bath from terminal board 4 to terminal block 8 along strips 14, 19, 18 (or 14, 20, 21), is affixed as by straps 27 to that normally plane surface 28 of support 13 which is remote from the terminal board 4 to further insulate and protect the wires 9, l0, 1 1 from terminals 5, 6. The straps may be retained in place by notches 29 in one or both edges of strips l4, l8, 19, 20, 21 or by the holes 26. A shielded power cable 30, comprising

wires

31, 32, 33 having

free ends

31', 32, 33' and 31", 32", 33" respectively connecting screw terminals 5 to power terminals (not shown) on the instrument 2, is also affixed the support 13 as by straps 27. Any conductors, such as

cables

12 and 30, alfixed to the support 13 are arranged in a single layer to conserve space, avoid abrasion, and control electrical interference.

The support 13 is initially attached rigidly to the terminal board 4 by screws 16 through the disjoined mountable end 15, and the free ends 9", 10", 11", 31, 32', 33 are connected to respective terminals 6, 5. With the instrument 2 positioned away from the terminal board 4, the bar 24 is drawn forward and fastened to chassis 7 by screws 25, causing the

strips

14, 18, 19, 20, 21 of support 13 to assume a zigzag configuration, as shown in FIG. 1. The free ends 9', 10, 11' are plugged into the terminal block 8, and free ends 31", 32", 33" are connected to power terminals (not shown). The instrument 2 is then moved to its installed position close to the terminal board 4, as shown in FIG. 2. The extensible cable structure 3 then occupies little space, flat against the terminal board 4 with the support 13 providing protection for the wires and

cables

12, 30 from the terminals 5 (not shown), 6. There are no sharp bends in the wires and cables at any time and flexure is limited, providing small likelihood of wire breakage.

While this embodiment has the mounted

ends

15 and 24 in mutually perpendicular orientation, it will be obvious that mounted end 24 could lie in the same plane as, or in a plane parallel to, mounted end 15. Other flexible conductors, such as light conducting filaments and fluid conducting tubes, may be substituted for electric wires. The various types of flexible conductors affixed to the support 13 may be considered as a flat cable and are so referred to in the term, "extensible cable structure, used to describe this invention. The scope of the invention is defined by the claims and is not limited to the preferred embodiment described and shown herein.

I claim:

1. An extensible cable structure to transmit signals between relatively movable free ends comprising a self-reliant support of flexible material, said support having a normally plane surface, parallel strips formed of said support, respective ends of each inner of said strips joined to a respective adjacent of the strips to form a serpentine path of said support between disjoined ends of the outer of the strips, said disjoined ends movable from the normal plane of said support to produce a zigzag configuration of the strips, and a conductor affixed to said surface along said serpentine path between the disjoined ends whereby the free ends of said conductor are movable by the disjoined ends with minimum controlled flexure of said conductor.

2. An extensible cable structure according to claim 1 further comprising another conductor affixed to said surface to form a single layer of conductors in side by side relation between said free ends.

3. An extensible cable structure according to claim 1 wherein the junction between said adjacent strips is smoothly rounded to reduce stress concentration.

4. An extensible cable structure according to claim 1 additionally comprising means for mounting said disjoined ends to relatively movable members.

5. An extensible cable structure according to claim 1 wherein said joined strips form a second serpentine path as a mirror image of the first serpentine path, one of said disjoined ends common to both paths, the others of said disjoined ends movable as a unit with respect to the common end whereby twisting of said support is reduced.

6. An extensible cable structure according to claim 1 wherein said conductor is a wire.

7. An extensible cable structure according to claim 1 wherein said support is an insulator.

8. An assembly transmitting electrical signals between pieces of relatively movable electrical equipment comprising a first terminal protruding from one of said pieces of equipment, a second terminal on another of said pieces of equipment, a self-reliant support of flexible material, said support having a normally plane surface, parallel strips formed of said support, respective ends of each inner of said strips joined to a respective adjacent of the strips to form a serpentine path of said support between disjoined ends of the outer of the strips, one of said disjoined ends rigidly attached to the one of said pieces of equipment with the first terminal separated by said support from the plane surface, another of said disjoined ends rigidly fastened to the other of said pieces of equipment, said disjoined ends movable from the normal plane of said support to produce a zigzag configuration of the strips in response to separative movement of said pieces of equipment, and a conductor affixed to said surface along said serpentine path between the disjoined ends, a first free end of said conductor connected to said first terminal, another free end of the conductor connected to said second terminal whereby the signals may be transmitted through said conductor between said pieces of relatively movable equipment with minimum controlled flexure of the conductor and increased protection for said conductor from abrasion by and shorting to the first terminal.

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