Information
-
Patent Grant
-
6398586
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Patent Number
6,398,586
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Date Filed
Tuesday, May 1, 200123 years ago
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Date Issued
Tuesday, June 4, 200222 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
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CPC
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US Classifications
Field of Search
US
- 439 606
- 439 192
- 439 321
- 439 445
- 439 446
- 439 447
- 439 448
- 439 473
- 439 660
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International Classifications
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Abstract
A combination of a connector (12) and an armored cable (14), where several inches of the front end of the cable armor tube (20) are stripped away to allow a front portion of the cable to bend up to about 90°. A flexible polymer overmold (50) is molded around the front of the armor tube and the rear of the connector and the several inches of wire extending forward of the armor tube. The wire front portions (54) are twisted at least a full turn about the cable axis (44) prior to the overmolding, to reduce wire tension when the front portion of the cable is bent. The overmold has flanges (102) that bottom on one another at a 90° bend of a moderate radius of curvature (R). A wire mesh braiding (80) has a rear end clamped (92) and soldered to the armor and a front end clamped (96) to the connector. An air valve (130) is automatically opened when connectors mate.
Description
BACKGROUND OF THE INVENTION
An armor cable is commonly used in difficult environments such as in sewers to resist damage from rats. The armor tube, which is commonly electrically grounded, enables resilient bending only to very large radius of curvature. In some applications, a connector is required for connecting an end of an armor cable to a cabinet assembly, where the cable may be bent up to 90° within a length of less than one foot. Such cables may include up to 216 wires, and it is important to avoid damage to those wires at the outside of such a bend. The armor cable is often pressurized, as with dry air or nitrogen at 15 psi above atmospheric pressure to keep out moisture and prevent corrosion. When a connector at the end of the cable is to be mated to a corresponding connector on the cabinet, such connections are commonly made in difficult environments and it is desirable to provide an indication to the technician when he has fully mated the two connectors.
SUMMARY OF THE INVENTION
In accordance with one embodiment of the present invention, a combination of connector and cable is provided, where the cable has a steel tube around dozens of wires and where the combination must allow for bending of up to 90° within a space with a length of one foot. The armor is stripped away to leave wire front portions that are uncovered by the armor and that extend to contacts of the connector. A flexible polymer overmold is molded around the uncovered wire portions to protect them and allow for bending. The wire front portions are twisted at least one full turn and preferably more, about the cable axis prior to molding of the overmold. The twisting of the wires results in wires near the outside of the bundle, subjected to much less tension when the overmold with wires therein is bent by 90° about a moderate radius of curvature that is less than one foot.
The overmold has a plurality of radially-outward projecting flanges that are closely spaced along the length of the overmold. The flanges are constructed to stack against one another at the inside of a bend of predetermined radius of curvature that is less than the length of the uncovered wire portions and at least about twice the outside diameter of the overmold.
A wire mesh braiding is provided which has a rear end clamped and soldered around the front end of the armor jacket portion and having a front end that is clamped around a body of the connector. Most of the length of the braiding has a diameter about equal to the outside diameter of the armor tube, but the front end of the braiding has a diameter at least 150% as great. A front portion of the braiding is pulled tight into a cone shape prior to the overmolding.
A valve is mounted on the connector to enable pressurization of the cable. The valve includes a valve element such as a ball lying in a passage of the body of the connector and spring biased forwardly. The second connector device on a cabinet has a projecting pipe that pushes the valve member rearwardly during mating to connect pressure in the second connector to the pressure within the cable.
The mating connectors have shells that are threadably connected and that form a latching mechanism that indicates when the shells have been fully threaded together and that resist unlatching. One shell which forms a coupling ring, has a front edge with multiple teeth while the other shell has a rearward projection lying on a beam that can be axially deflected. As a full threading connection is approached, the teeth brush across the projection while flicking it progressively more forcefully.
The novel features of the invention are set forth with particularity in the appended claims. The invention will be best understood from the following description when read in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is an exploded isometric view of a combination connector and cable, and a mating connector device, constructed in accordance with the present invention, and showing the cable both straight and bent.
FIG. 2
a sectional view of the combination of connector and cable of
FIG. 1
, with a 90° bend also indicated.
FIG. 3
is an isometric representation of only the cable of
FIG. 2
, showing the uncovered wire bundle after it has been twisted.
FIG. 4
is an isometric view of a wire mesh braiding, shown clamped to the armor tube of the cable and clamped to the connector;
FIG. 5
is an exploded sectional view showing the front mating end of the connector and the mating end of the connector device of
FIG. 1
, as they closely approach one another for mating, to show the pressured gas valve.
FIG. 6
is an exploded side view of shells of the connector and connector device of
FIG. 1
, with the shell of the connector shown in section.
FIG. 7
is an isometric view of the connector shell of FIG.
6
.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1
illustrates a combination
10
of a connector
12
and cable
14
. The cable
14
includes a jacket assembly
16
comprising an armor tube
20
of a metal such as steel and a rubber-like covering
22
. A bundle
24
of numerous wires
26
lies within the jacket assembly. The connector
12
includes a body
28
with an insulative body part
30
that holds numerous socket contacts
32
with each contact being connected to the front end of one of the wires. The connector
12
is designed to mate with a second connector or connector device
34
that has numerous pin contacts
36
. The connector device
34
has a flange
40
with holes
42
for mounting on a cabinet.
The steel armor tube
20
of the cable has undulations in its diameter that permit it to be bent. However, the armor tube can be resiliently bent only to a large radius of curvature which is about forty times its outside diameter without assurance of no damage to the armor tube. In the case of an armor tube of one inch diameter, this results in a requirement of at least twenty inches in a cabinet structure to account for a 90° bend. Many cabinet assemblies require that the cable be bent by 90° within a space of less than one foot length.
FIG. 1
shows that the combination
10
includes an overmold
50
that is flexible and that allows the wires to be bent to a configuration such as with the overmold at
50
A, where the cable at
14
A extends 90° from its straight position
14
. In the straight cable positions, the axis
44
of the cable is straight. That is, while the cable initially extends in Front F and rear R directions, it can be bent 90°.
FIG. 2
illustrate details of the combination
10
of the connector
12
and cable
14
. A flexible region
52
which extends between the front end of the cable jacket and the connector, includes uncovered wire front portions
54
that are not surrounded by the jacket assembly
14
. This is accomplished by cutting away the polymer sleeve
22
of the jacket to leave its front edge at
60
, and by cutting away the metal armor tube
20
to leave its front edge at
62
. After the polymer sleeve
22
and armor tube
20
have been trimmed, front ends
64
of the wires are connected to the contacts
32
of the connector. Then, the wire bundle along the uncovered wire front portion
54
, is twisted about the cable axis
44
by at least a full turn of 360°, and preferably by three turns.
FIG. 3
shows the wires twisted by three turns. After the uncovered wire, or uncovered wire bundle, is twisted by three turns, it is covered by a compressing layer
66
. Such compressing layer can be a layer of tape wrapped in multiple turns around the twisted wire bundle to compress it and hold its largely cylindrical shape. An alternative, which applicant prefers, is a shrink wrap tube which is a large tube slipped over the twisted wire bundle and then heated to shrink the tube to compress the portion between the front end
62
of the armor tube and wire locations at
70
which are spaced perhaps an inch or two rearward R of the front ends
64
of the wires that connect to contacts of the connector. Thus, the shrink tube has a front end at
72
in FIG.
2
.
The reason for twisting the wire bundle is to avoid damage to the wire when the bundle is bent by perhaps 90° about a radius of curvature of perhaps four inches. During such a bend, the portions of the wires near the outside of the bend undergo tension that tends to elongate them, while the wire portions at the inside of the bend tend to undergo compression. The tension could cause breakage of wires at the outside of the bend. However, with twisting, the portions of the wires at the outside of the bend do not extend parallel to the outside of the bend, but extend in a helix. As a result, at the outside of the bend, the wires tend to separate from one another rather than being placed under high stress and possibly breaking. Although a twist of at least 360° is preferred, a twist of the wire bundle of at least one-half or three-quarters turn about the cable axis
44
provides some protection against tension damage.
After the bundle of wires is twisted and a compressing layer is applied, an electrically conductive wire mesh braiding, shown in
FIG. 4
at
80
, is applied around the front portion of the cable, including the uncovered wire front portions
54
. The braiding has a tubular rear portion
82
of about the same diameter as that of the armor tube
20
, and having a length in the front and rear directions F, R that is a plurality of times its diameter. The braiding has a front portion
84
of a diameter much greater than that of the tubular rear portion
82
, to surround the rear of the connector body. The rear end
90
of the braiding is mechanically and electrically connected to the armor tube
20
, by a clamp
92
that clamps the braiding around the armor tube. In addition, the clamp
92
is soldered to the braiding rear end
90
and to the armor tube
20
through holes in the braiding. The front part of the braiding is mechanically connected to an outer body part
94
that surrounds the inner body part
30
, by a clamp
96
. It is noted that one of the contacts
32
is a grounded contact that is connected to the front end of the braiding. The wire mesh braiding provides for a grounding connection and EMI (Electro Magnetic Interference) protection that otherwise would be provided by the armor tube
20
, except that the braiding
80
can undergo resilient bending about a smaller radius of curvature.
After the braiding has been clamped in place, the arrangement of braiding, around a compressed layer which surrounds the twisted bundle of wires, is overmolded by the polymer overmold
50
, as shown in FIG.
2
. The polymer overmold has an undulating middle or bendable region
100
that includes a plurality of axially-spaced flanges
102
that project radially outwardly with respect to the cable axis
44
. The flanges are constructed to stack on one another, as shown at
102
A, when the bendable region
100
is bent about a radius of curvature R by 90°. When the overmold is bent at radius R, the length of the bent region of the overmold, along the bent cable axis
44
A, equals its length between locations
104
,
106
. If the length between locations
104
,
106
is ten inches, then the radius of curvature R is about
6
inches. When the flanges are stacked as at
102
A, any further bending of the bendable region encounters much higher resistance, because the thickness T of the overmold to be further bent is twice as great as the initial thickness U between flanges. This prevents a “sharp” bend, such as a 360° bend about a radius of curvature less than the overmold diameter which can result in a “kink”, or permanent bend, in the cable.
The overmold has a rear portion
110
that is about twice the thickness U of the overmold at the radially inner ends of the flanges, so the rear portion
110
is much stiffer than the bendable region
100
. The front part
112
of the overmold is of much greater diameter to fit over the insulating body
30
, body part
94
and clamp
96
.
It should be noted that when the braiding
80
is installed and the combination is placed in a mold, the braiding is placed under tension to form a conical front braiding region
120
extending between the largely cylindrical small diameter rear portion and the larger diameter cylindrical front portion. A clamp
122
prevents expansion of the wire bundle at the rear of the conical region. The two clamps
96
,
122
maintain the tension. The tension assures that the braiding will be in the position that it tends to occupy after the combination is completed and a large rearward force is applied to the cable, with the conical region
120
being in the best configuration to take such tension force.
The cable is designed to hold pressured gas such as dry air or nitrogen, at a pressure such as one atmosphere. This helps to keep out moisture and corrosive chemicals that might otherwise leak in through a damaged portion of the armor tube.
FIG. 2
shows a valve
130
at the front end of the connector, and a tube
132
that extends rearwardly from the valve to the middle of the cable diameter, to carry such compressed gas into or out of the bundle of wires that lies within the overmold or jacket assembly of a cable.
FIG. 5
shows details of the valve
130
. The valve includes a valve element
132
in the form of a ball that lies within a passage
134
. The valve passage is shown formed in the body
30
of the connector, although it could be formed by a separate metal tube within the rest of the plastic body. The valve passage forms a seat
136
, and a spring
140
biases the valve member forwardly against the seat to stop the escape of pressured gas from the cable. An entrance
142
extending into the mating face
144
, or surface of the connector
12
, is designed to receive a pipe
150
on the mating connector device
34
. It is noted that the contacts
32
of the connector
12
are socket contacts and that the connector body forms leadins
152
for guiding pins into the socket contacts. The mating connector
34
has pin contacts
160
that project from a mating face
162
, or surface of the connector device for insertion into the socket contacts. The connector device has a peripheral wall
163
that surrounds the pins
160
and tube
150
to protect their rear ends.
As the connectors approach each other, the pin contacts
160
enter the socket contacts
32
, and the pipe
150
passes through the entrance
152
into the valve passage
134
. The pipe pushes back the valve element to position
132
B. At full insertion, holes
164
in the pipe communicate with the valve passage
134
, so pressured gas can flow from the pipe
150
into the valve passage
134
, and through the tube
132
into the inside of the armor tube of the cable, or vice versa. In some cases, an end of the cable opposite the connector
12
, is connected to another cabinet with a source of pressured gas. The valve
130
remains closed to keep in the pressured gas, until the connectors are mated, to minimize loss of gas. It is noted that it is possible to form the pipe
150
on the connector and, where desirable, provide a separate shutoff valve to prevent loss of gas in the cable until the connector is mated with another connector such as one on a cabinet.
FIG. 2
shows that the connector
12
includes a coupling ring in the form of a shell
170
with a threaded inside
172
that can threadable engage the threaded outside of the shell of the mating connector device.
FIGS. 6 and 7
show the coupling ring shell
170
and the mating shell
180
of the connecting device
34
. The coupling ring shell
170
forms a ring
182
of teeth
184
. The teeth are closely spaced, with the particular ring
182
having thirty-eight teeth at a pitch angle of about 9.5°. The mating shell
180
includes a second cylinder
190
having a main part
192
and having a circumferentially-extending slot
194
forming a beam
196
. The beam has a projection
200
that projects rearwardly R from the rest of the beam
196
. The opposite ends of the beam are connected to the main part
192
.
As the coupling ring shell
170
is threaded onto the shell
180
, the teeth
184
approach the projection
200
. Initially, the addendum, or axially most forward end
210
of a tooth brushes by the projection
200
. The addendum of each tooth lies axially forward of the tooth dedendum, or tooth bottom
211
. The next tooth then can be moved circumferentially across the projection
200
, but with moderate resistance, and with a “click” sound being generated. A technician who is turning the coupling ring shell
170
(or the outer cylinder
220
shown in FIG.
2
), can feel the sudden increased resistance followed by a sudden decrease in resistance, to turning, as a tooth brushes by the projection. In most cases, the technician will turn the coupling ring shell until perhaps one or two additional teeth pass by the projection, at which time there is a high resistance to further turning. The “click” sound and click tactile feedback transmitted to the technician who is turning the coupling ring, informs that technician that the shells of the two connectors have been properly mated and that the connector has been turned sufficiently for full installation. It is desirable that the teeth
184
be angularly spaced by no more than about 15°, so a plurality of teeth can brush pass the projection as the coupling ring shell approaches full threaded connection. With a fifteen degree pitch, there are at least twenty-four teeth per full turn. The number of teeth that will brush by before there is high resistance to further turning, also depends upon the thread pitch and the resilience of the beam
196
.
In a combination of the construction shown in
FIG. 2
that applicant has designed, the cable has
216
wires and the connector has
216
corresponding contacts. The armor tube has an outside diameter G of one inch, the compression layer
66
has an outside diameter of about one inch, the wire mesh braiding has an outside diameter E of about one inch, and the overmold has an outside diameter D of two inches. That is, the radially outer ends of the flanges lie on an imaginary cylinder of two inches diameter. The bendable region
100
of the overmold has a length of about ten inches between its opposite ends
104
,
106
. The braiding has a diameter inside the clamp
96
of 3.25 inches. The wire is twisted by three full turns between one end of the uncovered wire portion at the front end
62
of the armor tube and the front end of the compression layer at
70
.
Thus, the invention provides a combination of connector and cable with a rugged and flexible transition between the cable and connector. A flexible polymer overmold is molded around uncovered wire front portions, with the overmold being elongated along the axis of the cable and being bendable. The uncovered wire front portions are twisted at least one-half turn and preferably at least one full turn about the cable axis, and with the overmold being molded around the wire front portions after they have been twisted. The overmold has a plurality of radially-outwardly projecting flanges which are constructed to stack one-against-another at the inside of a bend of the overmold, where the bend has a radius of curvature that is at least twice the outside diameter of the overmold. The uncovered wire portions are surrounded by an electrically conductive wire mesh braiding having about the same diameter as the armor tube along most of its length, and having an enlarged front end that is clamped to a metal ground cylinder lying around the body. A transition in diameter of a front portion of the braiding, is achieved by pulling the braiding into a conical shape prior to the overmolding. Front and rear ends of the braiding are clamped in place. A valve for passing pressure gas into or out of a cable, has a valve element that is pushed rearwardly by a pipe on the mating connector device to pass air between the connectors. A pair of shells, or cylinders, on the connector and connector device that are threaded together during connector mating, are constructed with one having a beam with a rearward projection and with the other having a shell with a ring of teeth that approach the projection to provide audible and tactile feedback.
Although particular embodiments of the invention have been described and illustrated herein, it is recognized that modifications and variations may readily occur to those skilled in the art, and consequently, it is intended that the claims be interpreted to cover such modifications and equivalents.
Claims
- 1. A combination of a connector and a cable, where said cable has a cable axis and said cable includes a jacket assembly and a plurality of wires lying within said jacket assembly, with a front portion of said jacket assembly removed to expose wire front portions, wherein each wire front portion has a front end, and said connector includes a primarily insulative body and a plurality of contacts mounted in said body, each uncovered wire front portion extending to one of said contacts and each contact connected to said front end of one of said wire front portions, including:a flexible polymer overmold that is molded around most of the lengths of said wire front portions, said overmold being elongated parallel to said cable axis and being bendable; said wire front portions are twisted at least one-half turn about said cable axis, with said overmold being molded about said wire front portions after said wire front portions have been twisted.
- 2. The combination described in claim 1 wherein:said overmold has a bendable region forming a plurality of radially outwardly projecting flanges with radially outer ends that lie on an imaginary cylinder of predetermined cylinder diameter; said flanges are constructed to stack one-against-another at the inside of a bend along said bendable region, where the bend has a radius of curvature that is at least about twice said cylinder diameter, but no more than ten times said cylinder diameter.
- 3. The combination described in claim 1 wherein:said plurality of wires is twisted by at least one complete turn.
- 4. The combination described in claim 1 wherein:said plurality of wires includes a bundle of at least two dozen wires extending along said cable axis, and said bundle is twisted by at least about two complete turn about said cable axis, whereby to avoid tensile damage to wire portions that lie near a radially outer portion of said bundle when said bundle is bent about an axis that is perpendicular to said cable axis.
- 5. The combination described in claim 1 wherein said connector has a mating end and Including a second connector device which has a mating end that is mateable to said connector by moving said connector device along a connector axis toward said connector, with said connector and connector device each having a shell with one of said shells being a coupling ring shell that is rotatable, and where one shell has an external thread and the other has an internal thread and threadably receives the other shell, including a latching mechanism that resists unthreading of said shells and that indicates when the shells are being fully mated, wherein:a first of said shells includes a first cylinder with a front edge having multiple teeth angled apart about said axis, with said teeth having teeth dedendums and having teeth addendums spaced forwardly of said teeth dedendums; a second of said connectors includes a second cylinder having a main part and having a circumferentially-extending slot forming a circumferentially-extending beam lying rearward of the slot, said beam having circumferentially spaced opposite ends each merging with said main part and said beam forming a projection that projects rearwardly and that is positioned to engage said teeth as said shells are threaded together.
- 6. The combination described in claim 1 wherein said jacket includes a metal armor tube, and said connector has a metal ground cylinder that extends around said contacts and that has a diameter that is greater than the outside diameter of said armor tube, including:an electrically conductive wire mesh braiding having a tubular rear portion of a first diameter that is about the same as an outside diameter of said armor tube and having a length that is a plurality of times said first diameter, said braiding having a front portion with a diameter that is at least 150% of said first diameter, with a rear end of said braiding being mechanically and electrically fixed to said armor tube and with a front end of said braiding being fixed to said connector.
- 7. The combination described in claim 6 wherein:said braiding has a transition region lying between a front end of said braiding rear portion and said braiding front portion, and including first and second clamps with said first clamp fixing said braiding front portion to said connector and with said second clamp fixed to said front end of said braiding rear portion, with said braiding pulled into a conical shape along said transition region.
- 8. The combination described in claim 6 including:a compressing layer of insulative material which tightly surrounds said twisted wire front portions, with said braiding surround said compressing layer.
- 9. The combination described in claim 1 wherein said cable contains gas at a pressure above atomospheric pressure and said connector has a connector mating face with said contacts lying thereat, and including a mating connector device with a device mating face and with contact devices that are accessible at said device mating face and that are mateable to said contacts, said contacts and contact devices comprising pins and sockets, including:a valve mounted on said connector, said valve having a valve element and said body forming a passage that surrounds said valve element and a seat lying forward of said valve element, said valve element being spring biased against said seat to close said valve, and including a tube extending rearwardly from said passage to at least said wire front ends; said passage having an entrance lying at said connector mating face and leading to said passage; said connector device having a pipe that projects rearwardly from device mating face and which is of a slightly smaller diameter than said entrance to project through said entrance into said passage and move said valve element rearwardly away from said seat, said pipe having side walls with a hole that passes pressured air to pass gas between said pipe and said passage; said pin and socket elements being positioned to mate as said pipe passes through said entrance during mating of said connectors.
- 10. The combination described in claim 9 wherein:said contacts of said connector are socket contacts that are recessed in said connector mating face, and said contact devices are pin contacts that project rearward of said device mating face, said connector device having a peripheral wall that projects rearward of said device mating face and that surrounds rear ends of said pin contacts and a rear end of said pipe.
- 11. The combination of a connector and a cable, wherein said cable has a cable axis and said cable includes a metal armor tube having an outside armor tube diameter and having an armor tube front end, and at least one wire lying within said armor tube, and wherein said connector includes a body and at least one contact lying in said body and connected to said wire, said body having an outside diameter at least 150% as great as said armor tube diameter, including:an electrically conductive wire mesh braiding having a tubular rear portion of about said armor tube diameter and mechanically and electrically attached to said armor tube front end; said braiding having a tubular front portion that is connected to said connector; said braiding tubular front portion lies around said body, and said braiding has a portion that has been tensioned into a conical portion extending between said front and rear portions, and including a clamp lying around said braiding at a rear end of said conical portion.
- 12. The combination described in claim 11 wherein:said at least one wire is flexible so it can be bent by at least 90° along a length between a front end of said armor tube and a rear end of said body; said braiding tubular rear portion has a length that is at least twice its diameter; and including a polymer overmold that is molded around said braiding, around said armor tube rear portion and around a portion of said metal ring, said overmold having a flexible overmold portion that extends forwardly from said armor tube front end by at least twice an outside diameter of said flexible over mold portions, said flexible overmold portion being resiliently bendable by at least 90° about a radius that is four times said outside diameter of said flexible overmold portion.
- 13. The combination describe claim 11 wherein:said at least one wire includes a bundle of at least two dozen wires extending along a bundle axis, and said bundle is twisted by at least one complete turn about said bundle axis, whereby to reduce the possibility of tension damage to one of said wires when said bundle is bent 90° about an axis that is perpendicular to said bundle axis.
- 14. The combination of a connector and a cable, where said cable has a cable axis, a bundle of wires extending along said axis and a protective jacket assembly lying around said wires with a length of said jacket being striped away to leave front uncovered wire portions extending forward of a front end of said jacket, and where said connector has an insulative body and a plurality of contacts lying in said body and connected to front ends of said wires, comprising:a polymer overmold that is molded around a portion of said connector along a majority of the length of said uncovered wire portions, and around a portion of said jacket assembly; said overmold has a bendable region, said bendable region forming a plurality of radially outwardly projecting flanges with radially outer ends that lie on an imaginary cylinder of predetermined cylinder diameter; said flanges are constructed to stack one-against-another at the inside of a 90° bend that extends along said bendable region and about a bend axis that is perpendicular to said cable axis when said cable is unbent, where the bend has a radius of curvature that is between about twice and six times said cylinder diameter.
- 15. The combination of a connector and a cable, where said cable includes a gas tight metal armor tube and a plurality of wires lying within said armor tube, and said connector includes a body with an axis and a plurality of contacts mounted in said body and connected to said wires, said body having a front mating face and said contacts having mating front ends that are accessible at said mating face, wherein:said body forms a passage extending parallel to said axis and said connector includes a valve having a moveable valve element lying in said passage, said passage having a seat lying forward of said valve element and said valve element being spring biased forwardly against said seat to close the valve, said body having an entrance hole extending from said mating face and through said seat to receive a projecting pipe that moves said valve element rearwardly; said passage extends to the rear of said body and communicates with the inside of said armor tube, whereby to enable simultaneous electrical and pressured gas connection of the connector with a mating connector device.
- 16. The combination described in claim 15 wherein:said armor tube has a front end and said wires extend forwardly beyond said armor tube front end; and including a flexible polymer overmold that has an overmold rear portion that is molded around said armor tube front end, an overmold front portion molded around at least a rear portion of said body, and an overmold middle portion that extends between said overmold front and rear portions and that is gas tight, said overmold rear, front end middle portions being integral.
- 17. The combination described in claim 15 wherein:said contacts are socket contacts; and including a connector device that is mateable with said connector, said connector device having a rear mating face surface and a plurality of pin contacts projecting rearwardly from said rear mating face surface for insertion into said socket contacts; said connector device has a pipe that projects rearwardly from said mating face surface and which is of a slightly smaller diameter than said entrance to project through said entrance hole into said passage and move said valve element rearwardly away from said seat, said pipe having side walls with a hole that passes pressured gas to pass gas between said passage and the inside of said pipe.
- 18. A method for connecting a cable to a connector, where said cable has a plurality of wires lying within a jacket that includes a metal conductor, and where said connector includes a body, and a plurality of contacts lying in said body, comprising:stripping away said jacket to leave uncovered front wire end portions, and connecting front ends of said uncovered wire end portions to said contacts of said connector; molding an overmold around said body, around a front end of said metal tubular conductor of said jacket and around a majority of the length of said uncovered wire end portions; said metal conductor of said jacket is a metal tube and said connector body has a diameter that is more than 150% of the diameter of said metal tube; and including applying a tubular wire mesh braiding with an enlarged front end around said front wire end portions, including clamping a rear end of said braiding around said metal tube, and clamping a front portion of said braiding around said body.
US Referenced Citations (18)