Hermetically sealing connector and method of use thereof

A connector device and method of use thereof provide positioning and hermetic sealing of electrical contacts in protective housings. The housings protect wires which connect the speed sensor of a turbine engine to a display. The connector supports the electrical contacts in an electrical insulator. The connector includes a malleable flange which is adapted to be hermetically sealed between two housings which protect wires connected to the speed sensor in the turbine engine. The flange is hermetically sealed between a tongue on one housing and a groove in the other housing. The sealing flange extends radially from the central axis of the connector and is compressed by the tongue of a releasable housing into the groove of a permanent housing to form a hermetic seal. The flange supports the electrical insulator which holds electrically conducting inner contacts in position to be slideably mounted into outer contacts which are supported by the connector housing.

The invention relates to the hermetic sealing of connectors between 
housings. More particularly, the invention provides replaceable 
hermetically sealing connectors, which support electrical contacts, and 
are useful for connecting high temperature turbine engine speed sensors to 
a display. Also provided is a cable connector backshell (sleeve) which is 
adapted to hold a cable to the housings which support the contacts. The 
sleeve, the hermetically sealing connector and method of use thereof in 
accordance with the invention are provided for efficient maintenance of 
turbine engine speed sensing systems. Such sensors operate within or near 
the high pressure combustion chamber of turbine engines. The wires from 
the sensor initially pass within a conduit which must be hermetically 
sealed to maintain the pressure of the engine. The wires from the sensor 
are in electrical contact with the cable to a counter and a display for 
monitoring engine speed. For maintenance of the wires, which may have been 
previously misconnected or damaged, the conduit must be disconnected from 
the cable. Hermetic sealing of the conduit is readily obtained by using 
replacement connectors in accordance with the invention. The hermetically 
sealing replaceable connector includes a collar having a sealing flange. 
The collar supports an insulator which holds at least one electrical 
contact in position. The sealing flange is compressed by the tongue of a 
releasably mounted housing (or shell) into the groove of a permanently 
mounted housing (or backshell) to form a hermetic seal. 
It is an object of the invention to provide a readily replaceable 
electrically insulated connector which is hermetically sealable at high 
temperatures and pressures. It is an object of the invention to provide a 
method of hermetically sealing an electrical contact in a housing 
Positioned adjacent to a turbine engine. It is an object of the invention 
to provide a sleeve for connecting a cable to housings which support 
hermetically sealed electrical contacts. 
The prior art does not provide readily replaceable hermetically sealable 
connectors for use at high temperatures. Evans, in U.S. Pat. No. 
4,108,529, discloses an electrical feed-through device for connecting 
electric components on a bulkhead. The device is not disclosed as being 
useful at high temperatures. A part of the dielectric body is physically 
deformed to effect a hermetic seal with the conductive sleeve and/or 
electrical conductor. By contrast, the present invention, by virtue of the 
tongue-and-groove features, provides a dual edge seal which does not 
deform the dielectric. The dual edges are on the mating faces of the shell 
and back shell. This feature provides control of the amount of crush to 
limit the shearing action, thereby preventing breakthrough. The dielectric 
is a rather brittle ceramic in a preferred embodiment of the present 
invention. Such a dielectric would crack if it were crushed as disclosed 
by Evans. The seal of the invention is made by providing a flange of a 
ductile metal, such as nickel, which is brazed to the dielectric. Evans 
seals individual conductors rather than an insert of multiple conductors 
as is provided by the present invention. 
Mattingly, Jr., in U.S. Pat. No. 4,509,814, discloses an electrical 
connector shell assembly. The connector shells of Mattingly do not include 
a hermetically sealing tongue or groove in sealing surfaces adjacent to 
the sealing flange. Further, the sealing flange of Mattingly does not 
support an insulator or a contact as does the sealing flange of the 
present invention. 
Stuart, in U.S. Pat. No. 3,200,366, discloses an annular ring which is 
deformed to seal an electrical connector. However, the ring of Stuart does 
not support an insulator or a contact as does the sealing flange disclosed 
herein in accordance with the present invention. 
Willis, in U.S. Pat. No. 3,861,774, discloses a ground stud assembly. The 
assembly has a single contact surface in the path of flow of the ground 
current. The base is coined to form a mating cavity to receive the head of 
the stud at an upstanding flange around the cavity which is later squeezed 
over onto the head of the stud to secure it in place. Willis neither 
provides support for an electrical contact, which is insulated from the 
housing, nor hermetic sealing. The present invention provides a device and 
a method by which a hermetically sealing electrical contact is replaced 
thereby allowing wiring to be serviced to replace damaged seals or 
contacts. The present invention provides a hermetic connector which may be 
opened (i.e.: to reassign contact and circuit relationships) and then 
resealed hermetically without replacing expensive parts. This provides 
cost effective servicing in which no machining, welding or brazing is 
required, and the risk of damaging the engine, sensor or cable is 
minimized. 
References relating to the connector sleeve of the invention include Martin 
et al., U.S. Pat. No. 1,954,088, which discloses a lock coil; Locati, U.S. 
Pat. No. 4,685,761, which discloses an electrical contact assembly and 
method of assembly; Wahl, U.S. Pat. No. 3,137,925, which discloses a 
method of splicing insulated conductors and O'Keefe et al., U.S. Pat. No. 
3,323,098, which discloses a sub-miniature coaxial connector.

BRIEF DESCRIPTION OF THE INVENTION 
A connector device and method of use thereof provide positioning and 
hermetic sealing of electrical contacts in protective housings. The 
housings protect wires which connect the speed sensor of a turbine engine 
to a display. The connector supports the electrical contacts in an 
electrical insulator. The connector includes a collar having a malleable 
flange which is adapted to be hermetically sealed between two housings 
which protect wires connected to the speed sensor in the turbine engine. 
The flange is hermetically sealed between a tongue on one housing and a 
groove in the other housing. The sealing flange extends radially from the 
central axis of the collar and is compressed by the tongue of a releasable 
housing into the groove of a permanent housing to form a hermetic seal. 
The collar, thus held by its sealing flange to the housings, supports the 
electrical insulator which holds electrically conducting inner contacts in 
position to be slideably mounted into outer contacts which are supported 
by a mating connector which is coupled to the releasable housing. 
DETAILED DESCRIPTION OF THE INVENTION 
With more particular reference to the drawings, a preferred embodiment of 
the invention is shown in FIGS. 1 through 15 wherein the same numeral 
refers to the same item in each of the several figures. With more 
particular reference to FIG. 1, a connector assembly in accordance with 
the present invention is shown at 10. The connector assembly 10 is adapted 
to maintain sealing during turbine engine operation. The connector 
assembly 10 includes a releasable sealing housing 12, sometimes referred 
to as a connector shell, and a permanently mounted sealing housing 14, 
sometimes referred to as a backshell. Hermetically sealed between the 
releasable housing 12 and the permanent housing 14 is connector 15. The 
flange 16 extends radially from the collar 17 which supports the 
electrical insulator (or dielectric material), 18. The insulator 18, which 
preferably is made of ceramic and is disc shaped, supports the inner 
contacts 20, 21, 22 and 23. 
The flange 24 of the releasable housing 12 includes the tongue 26. The 
releasable housing 12 includes step-wise grooves 28, 30 and 32 
circumferentially around its outer body. Flange 34 of permanent housing 14 
includes the groove 36. 
In the assembled position, as shown in FIG. 1, the groove 36 of flange 34 
fits over the tongue 26 of flange 24. The keys 18" (shown in FIG. 13) of 
the housing 100 are adapted to slide within and be guided by keyways 18' 
(shown in FIG. 2) of the releasable housing 12. The keys 18" and keyways 
18' are held in alignment, and are adapted to position the inner contacts 
20 and 22 through apertures 64' and 64" in insulator 64 and into the outer 
contacts 58 and 60. Bolts or screws are inserted through apertures 38, 40, 
42 and 44 of flange 34 and are tighted into the threaded passages 70, 71, 
72 and 73 of flange 24. The bolts or screws through apertures 38, 40, 42 
and 44, hold the tongue 26 in the groove 36 with the flange 16 compressed 
therebetween, thereby hermetically sealing the releasable housing 12 to 
the permanent housing 14. 
Conductors 46 and 48 are enclosed by conduit 50 and extend into resilient 
insulator 19 and are connected to inner contacts 20 and 22. During 
maintenance operations, the resilient insulator 19 is pressed into housing 
14 to expose the ends of conductors 46 and 48 for connection to inner 
contacts 20 and 22. Conductors 46 and 48 are connected to the speed sensor 
51. The speed sensor 51 is connected to the turbine engine 52. 
Conductors 54 and 56 are connected to the outer contacts 58 and 60. 
Conductors 54 and 56 are enclosed in cable 62. Nut 86 connects the housing 
12 to the cable sleeve 88. The outer contacts 58 and 60 engage inner 
contacts 20 and 22. The inner contacts 20 and 22 extend through the 
insulators 18 and 64. Insulator 64 is supported by releasable housing 12. 
FIG. 2 is an end view along line 2--2 in FIG. 1 of releasable housing 12. 
Threaded passage walls 70, 71, 72 and 73 are adapted to receive bolts, 
which also extend through aperture walls 38, 40, 42 and 44 of permanent 
housing 14 (shown in FIG. 12) to connect the housings. The inner contacts 
20, 21, 22 and 23 are supported by insulator 18. Inner contacts 20 and 22 
extend through insulator 64 into outer contacts 58 and 60, as described 
above. 
FIGS. 3 and 4 show side and end views respectively of a disposable 
connector 15 having inner contacts 20, 21, 22, and 23 supported by the 
insulator 18 in the collar 17. The cylindrical collar 17 includes a flange 
16 as shown in side and end views in FIGS. 5 and 6 respectively. The 
collar 17 is adapted to support insulator 18 as shown in FIG. 1. 
Preferably, the collar 17 is made of a malleable metal such as nickel. 
FIG. 7 is an end view along line 7--7 in FIG. 1 of releasable housing 12. A 
side view of the releasable housing 12 is shown in FIG. 8. The tongue 26 
extends from flange 24 as shown in FIG. 9. FIG. 10 shows the tongue and 
groove adjacent to the flange 16 during the sealing process. The tongue 26 
is adapted to fit into the groove 36 of permanent housing 14 shown in a 
side and an end view in FIGS. 11 and 12 respectively. The apertures 38, 
40, 42 and 44 are adapted to receive the bolts which extend through the 
threaded passage walls 70, 71, 72 and 73. Upon tightening bolts into the 
threaded passages, the tongue 26 forces the adjacent portion of the flange 
16 into the groove 36 of the permanent housing 14 hermetically sealing the 
housings 12 and 14 together. The conductors 54 and 56 are connected to 
counter 80 which is connected to display 84 by a cable of conductors 82. 
Thus, the signal from the speed sensor 51 is conducted to counter 80 and 
the output thereof displayed by display 84. 
In accordance with the invention, hermetic sealing electrical contacts in 
housings, is accomplished by positioning a connector between a first and a 
second housing. As shown in the Figures, the connector has an electrically 
insulating body, at least one electrically conducting contact, and a 
collar having a malleable flange. The flange is positioned between the 
tongue and groove of the permanent and releasable housings. 
When a repair inside of the housings is needed, for example because of 
improper connection or disconnection of the wires, the housings are 
unbolted. After the repair is made, a replacement connector, as shown in 
FIG. 3, is used in place of the original connector. The housings are 
repositioned to hermetically seal along said replacement connector's 
sealing flange. 
A linear cable (or wiring harness) connector sleeve 88 is shown in FIG. 13. 
The flange 87 of nut 86 overlaps the flange of connector housing 100. The 
connector housing 100 has shoulder 101 and a groove wall 102. The sleeve 
88 includes bend 106 which fits into the groove enclosed by groove wall 
102. Groove wall 104 encloses a groove into which fits bend 108 of sleeve 
88. Bend 108 holds sleeve 88 to cable adaptor 110. Prior to forming bends 
106 and 108, one end of sleeve 88 is positioned even with the side of 
flange 109 of adaptor 110, and the other end is positioned against the 
shoulder 101 of connector housing 100. 
The sleeve 88 may be bent by tack welding and rolling, magnetic pulse 
forming or other suitable methods that physically deform the sleeve into 
the grooves. Beneficially the sleeve cavity is maximized by not having 
shoulders protrude therein. Replacement of the sleeve is generally 
required each time it is removed because of deformation of the sleeve, 
which occurs during removal. Thus, unauthorized removal of the sleeve is 
readily detectable. 
FIG. 14 shows an elbow sleeve 114 having crimped bends 106 and 108. The 
bend 106 extends into the groove adjacent wall 102 as shown in FIG. 13 and 
holds sleeve 114 to the connector housing adjacent to nut 86. The crimped 
bend 108 extends into the groove adjacent to wall 104 and holds sleeve 114 
to the cable adaptor 110. 
FIG. 15 shows an elbow (angular) sleeve having a larger diameter section 
214 and a smaller diameter section 216. Bend 206 extends into a groove 102 
as shown in FIG. 13 and holds the larger diameter section of the cable 
connector to the connector housing adjacent to nut 86. The bend 208 
extends into a groove therebeneath and holds the smaller diameter section 
216 of the sleeve to cable adaptor 210. 
The hermetic seal is effective to prevent leakage. A helium mass 
spectrometer is used for leak detection following temperature and pressure 
cycles such as those shown in the Table below. 
LEAKAGE TEST SEQUENCE 
In sequence 1 of the Table, the high pressure sealing test is started at 
70.degree. F. and 60 psig. The pressure inside the conduit 50 (chamber) is 
increased in increments of 40 psi until reaching 780 psig to test the 
sealing of the connector flange 16. This pressure is maintained for 30 
minutes. A change in gauge pressure check from the beginning to the end of 
the 30-minute holding period is an indication of a leakage through the 
seal at flange 16. Then the pressure inside the conduit is lowered to 0 
psig. 
This procedure is then repeated at the temperatures shown in the Table 
below for sequences 2-16 of the Table to complete the testing for leakage. 
TABLE 
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LEAKAGE TEST SEQUENCE 
PRESSURE 
SEQUENCE NUMBER 
CONDUIT TEMPERATURE .degree.F. 
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1 70 
2 130 
3 180 
4 230 
5 280 
6 330 
7 380 
8 430 
9 480 
10 530 
11 580 
12 630 
13 680 
14 730 
15 780 
16 850 
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Preferably, the sealed housing remains hermetically sealed to at least 
500.degree. F. and 600 psig. More preferably, the sealed housing remains 
hermetically sealed to at least 600.degree. F. and 700 psig. 
Other features, advantages and specific embodiments of this invention will 
become readily apparent to those exercising ordinary skill in the art 
after reading the foregoing disclosures. In this regard, while specific 
embodiments of this invention have been described in considerable detail, 
variations and modifications of these embodiments can be effected without 
departing from the spirit and scope of the invention as disclosed and 
claimed.