JPS6215997B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to electrical connectors for use in harsh environments, and in particular to electrical connectors for use on the surface of the earth by connecting lines to equipment installed underground and/or underwater. It relates to an electrical connector that can relay electrical signals to.

Connectors of this type are used, for example, in seismic exploration in oil and other mineral exploration.

Prior to approximately 1965, the drilling depth limit for oil exploration was approximately 6,100 m (20,000 ft).
It was hot. At this depth, the temperature is 204℃ (400〓)
is rarely exceeded. However, recently,
Drilling depths have become common in excess of about 6100 m, and temperatures can often exceed 260°C (500°C).

Such severe temperature conditions are a problem encountered not only in oil exploration boreholes, but also in underground nuclear explosion monitoring wells, or in other operations.
Furthermore, in underwater investigations, connectors that can withstand high pressure are absolutely necessary.

The connector of the present invention typically includes a male member and a female member.

The female member has a lead wire that is in contact with a conductor element having an elastomer sleeve coated on substantially the entire surface thereof.

The male member has a conductor pin, the center of which is covered with an insulating material and further wrapped with a metal jacket. One end of the pin contacts a conductive element on the female member, and the other end also extends into the housing of the instrument.

Connectors of the type described above can be used satisfactorily at depths of 6100 m or less and temperatures of 204° C. or less. However, there are problems when using connectors at greater depths and at higher temperatures.

The first problem is that the organic materials, such as the elastomeric sheathing in the wires and female members, become carbonized and become unusable at temperatures above about 204°C.

The second and more severe problem concerns the male member.

Ceramic, a suitable heat-resistant refractory material, is known to be effective as an insulator between, for example, a male member pin and a metal jacket. However, if the coefficient of thermal expansion of the metal portion of the male member, such as the jacket, does not match the coefficient of thermal expansion of the ceramic or refractory material, the ceramic and jacket will expand at different rates and the ceramic will crack.

Therefore, in the past, when ceramic made of fireproof material was used as an insulator for the male member of a connector, the ceramic and metal parts were left unfused, giving up on preventing leakage, or Either a metal and a ceramic with matching coefficients of thermal expansion were selected and used, and the two materials were fused to prevent leakage of the components.

Therefore, the materials that can be used are extremely limited. Additionally, many metals that are compatible with ceramics are unsuitable for use underground or underwater. This is because corrosion problems arise due to the alkalis and acids that exist in the subsurface environment.

Therefore, a first object of the present invention is to provide an electrical connector made of a fused metal and ceramic whose coefficients of thermal expansion do not necessarily have to match.

A second object of the present invention is to provide a connector in which more types of metals can be fused with ceramic insulators.

A third object of the present invention is to provide a male member for an electrical connector based on a new manufacturing method.

A fourth object of the invention is to provide an electrical connector having a glass seal ring surrounding the pin between a pair of fireproof sheathings and coupled to the sheathings, the pin and the metal jacket. The object of the present invention is to provide a male member for use in the present invention.

A fifth object of the present invention is to provide an outer sheath made of an elastomer and an inner sheath made of a temperature-resistant polymer, the inner sheath having a means for sealing between itself and a male member. An object of the present invention is to provide a female member for an electrical connector having the following features.

The male member in the connector of the present invention consists of a conductor pin, and a part of the circumferential surface of this pin is surrounded by a seal ring made of compressed glass. Furthermore, the circumferential surface of the pin in the vicinity of the annulus is surrounded by a refractory coating or sleeve. The sleeve is connected to the glass annulus and is fused to the pin, which is also fused to the pin.

A metal jacket surrounds the annulus and the refractory cladding in the immediate vicinity of the annulus. During the production process,
The jacket is contracted and secured around the refractory cladding and the glass annulus, so that it joins and fuses with the glass annulus.

The seal and pin and jacket formed between the glass annulus and the surface of the refractory coating proximal to the glass annulus, along with other features of the connector, prevent high pressure areas on the outside of the connector from entering the appliance housing. to prevent leakage into low pressure areas.

In one embodiment of the invention, if the coefficient of thermal expansion of the metal jacket does not match the coefficient of thermal expansion of the compressed glass commonly used for sealing, the glass seal collar may be made of two members. , consisting of an inner core of compressed glass and an outer member coated with a relatively thin glass, which has higher thermoplastic properties than the inner core and is located between the inner core and the jacket. has been done.

In another embodiment of the present invention, the glass seal annulus is made primarily of compressed glass that does not match the coefficient of thermal expansion of the fireproof coating and has higher thermoplastic properties compared to the compressed glass. A thin layer of glass is disposed between the contact surface of the refractory coating and the compressed glass core.

It is therefore understood that under certain circumstances, a glass seal annulus may consist of two components: a compressed glass and a glass having enhanced thermoplastic properties compared to the compressed glass.

In a preferred embodiment of the invention, the female member has two protective insulation sleeves. an outer sheath of an elastomeric material and an inner sheath of a heat resistant polymer material such as polytetrafluoroethylene.

The elastomeric sheath seals around the male member at low temperatures, and the polymeric sheath seals around the male member at high temperatures such that the elastomer breaks down and becomes unusable. The inner surface of the heat-resistant polymer sleeve is provided with an annular groove, and the corresponding portion of the male member is provided with a fitting protrusion, so that when the male member and the female member are combined, the jacket of the polymer sleeve and the male member will be tightly sealed.

Next, the present invention will be explained in more detail based on the accompanying drawings.

FIG. 1 generally shows an electrical connector according to the invention consisting of a male member M and a female member F. FIG.

The male member M has a central elongated pin 2 made of a conductive metal such as a 52% nickel alloy, ie Kovar. The pin 2 has a generally circular cross section and has a large diameter portion 6. The end 8 of the small diameter section 4 is designed so that it can fit within the female member F, and the end 10 of the large diameter section 6 can be located within the instrument housing I. End 10 may also be provided with external threads 92 for proper mating with instruments within housing I.

A portion of the circumferential surface of the small diameter portion 4 of the pin 2 is surrounded by a seal ring 12. This seal ring 12
are made of materials such as borosilicate glass, potash glass, barium glass, and other glasses with high compressive strength (hereinafter abbreviated as compressed glass).

On either side of the sealing annulus 12 there are tubular coverings or sleeves 14,16. These sleeves are preferably ceramic made of a suitable refractory material such as aluminum oxide, zirconium oxide, aluminum and silicon oxide compounds, aluminum and magnesium silicate compounds.

The sleeve 14 is located between the end 8 of the pin 2 and the seal ring 12, and the end face 18 is located between the end 8 of the pin 2 and the seal ring 12.
It is connected to 2. The sleeve 16 is located between the sealing ring 12 and the large diameter portion 6 of the pin 2, and has an end face 20 connected to the sealing ring 12.

The metal jacket 22 surrounds the outer periphery of the seal ring 12 and at least the portions of the sleeves 14, 16 closest to the seal ring 12. In this embodiment of the connector, the jacket 22 surrounds the entire length of the sleeve 16 and extends longitudinally beyond the sleeve 16 towards the end 10 of the pin 2. The inner surface 24 of the jacket 22 is coupled to the seal annulus 12 in a manner to be described below. If used in a corrosive environment, it is desirable that the jacket 22 be constructed from a non-corrosive metal. For example, you can use 300 grade stainless steel. Also, any number of non-corrosive metals can be used, such as stainless steel alloys and other metal alloys.

The jacket 22 has a cylindrical portion 26 that can fit within the female member F and a cylindrical portion 28 that can fit within the instrument housing I. As best shown in FIG. 2, the cross-section between the tubular portions 26 and 28 forms an enlarged polygon 27 with an outer surface 29 that allows the male member to be turned and screwed into the instrument housing I. It's getting old.

The sleeve 14 made of ceramic has a cylindrical portion 2.
6 and has an enlarged diameter portion 14a extending longitudinally toward the end 8 of the pin 2. The enlarged diameter portion 14a of the ceramic sleeve 14 and the outer diameter of the cylindrical portion 26 of the jacket 22 are approximately the same except for the annular protrusion 32 projecting from the cylindrical portion 26. The outer diameter of the remaining portion 14b of the ceramic sleeve 14 is approximately the same as the outer diameter of the seal ring 12 and the large diameter portion 6 of the pin 2.

The portion 16a of the ceramic sleeve 16 closest to the large diameter portion 6 of the pin 2 is also the portion 14 of the sleeve 14.
b. It has approximately the same outer diameter as the large diameter portion 6 of the pin 2 and the seal ring body 12. The outer diameter of the portion 16b closest to the seal ring 12 is smaller than the outer diameter of the portion 16a.

A glass insulating tube 30 surrounds the portion 16a and the area extending from the portion 16a to the end 34 of the jacket 22. The inner surface 36 of the jacket 22 includes glass and ceramic members 14, 12, 16, 3.
The shape is such that it fits closely to the outer surface of the 0.

The cylindrical portion 28 of the jacket 22 has a smooth surface portion 28 having a diameter considerably larger than the outer diameter of the cylindrical portion 26.
a, and a bonito screw 38 with a smaller diameter than the same part 28a.
It consists of a pointed end portion 28b in which is engraved.

A resilient O-ring 40 is fitted into an annular groove 42 provided in portion 28a. The metal annular gasket 44 reaches the outer peripheral surface of the cylindrical portion 28 at a continuous portion between the portions 28a and 28b.

The housing I has a hole 46, and the male thread 38 engages with a female thread 48 cut in the hole 46, whereby the housing I and the male member M are coupled. The shape of the hole 46 is set so that the housing I and the cylindrical portion 28 are sealed by the ring 40 and the gasket 44.

The female member F of the connector is provided with an inner sleeve 50 of heat resistant polymer. This cover tube 50 needs to have some elasticity, and is preferably made of polytetrafluoroethylene or other fluorocarbon resin, for example.

The cover tube 50 is provided with a long hole 52. This long hole 5
A rigid sleeve 56 made of, for example, brass is fitted into the second protrusion. Inside the sleeve 56,
A conductive element consisting of a spring 58 with a notched hole made of beryllium-copper alloy or the like is arranged. The sleeve 56 and the spring 58 are connected to the cover tube 5.
The shoulder 84 on the inside of the 0 is in contact with the shoulder 84 .

The spring 58 is composed of a fixed portion 58a and a lip portion 58b, and is biased toward the lip portion 58b and the fixed portion 58a (see FIG. 4), and can be displaced radially, that is, outwardly. Fixed part 58a and lip part 5
8b are separated by a cutout hole 60.

The tip 62 of the lip 58b and the mouth 5 of the elongated hole 52
A hole 68 passes through the extension part 66 of the stationary part 58a located between the stationary part 58a and the stationary part 58a. The long groove 72 of the lip portion 58b is bored opposite to the long groove 70 of the stationary portion 58a, and is aligned with the annular hole 68.

An outer jacket 74 made of an elastomer, such as synthetic or natural rubber, polyethylene, or ethylene-polypropylene rubber, is a heat-resistant inner jacket 50.
surrounding the outside. This cover tube 74 has a long hole 52
It has a hole 76 that aligns with the mouth 54 of the.

The lead wire 78 passes through the inner and outer sleeves to the spring 58 and is coupled to the spring 58 . The lead wire 78 has two protective insulation coatings, an inner coating 80 of high temperature resistant polytetrafluoroethylene or other insulation material.
and an outer covering 82 made of the same elastomer as the outer covering tube 74.

The inner sheath 80 extends through the inner and outer sheaths 50 and 74 to the point where the lead wire 78 is coupled to the spring 58.

The inner diameter of the long hole 52 of the inner cover tube 50 and the outer cover tube 7
The hole 76 of No. 4 has a size that allows the cylindrical portion 26 of the jacket 22 and the enlarged diameter portion 14a of the ceramic sleeve 14 to fit tightly together.

The inner sleeve 50 is provided with an annular groove 85 positioned so as to align with the annular protrusion 32 when the enlarged diameter portion 14a of the ceramic sleeve 14 contacts the rigid sleeve 56 and the spring 58. Both cover tube 7
Since 4 and 50 are elastic bodies, the annular protrusion 32 fits into the annular groove 85 when combined with the male member.

When assembling the male component, shoulders may occur due to the different inner and outer diameters of the various components mentioned above.
This shoulder assists in assembling the parts.

When the refractory sleeve 16 is inserted from the end 8 of the pin 2, it comes into contact with the large diameter portion 6 of the pin 2. Next, when the insulating tube 30 is fitted into the portion 28b of the jacket 22 and the completed unit is inserted from the end 8 of the pin 2, the shoulder 86 will fit into the portion 1 of the fireproof sleeve 16.
6a, shoulder 88 of sleeve 14 contacts jacket 22.

After assembling the components described above, selectively heating and then cooling the jacket 22 causes the jacket 22 to
shrinks and sticks around the ceramic and glass parts.

A preferred method of assembling the male member M is to assemble the male member M.
is placed in an induction electric furnace. Then, since the jacket 22 is made of metal and has heat conductivity, it heats up faster than the insulating glass, the glass seal ring, and the ceramic sleeve.

Depending on the material used, the male part M is heated to the required temperature and then cooled at a low temperature for a relatively short period of time. The jacket is held at a low temperature for a period sufficient to temper the glass seal annulus 12, and then further cooled to room temperature.

Heating and cooling temperatures and times will vary depending on the materials used. Cooling is preferably performed in an argon, nitrogen, or other inert gas atmosphere to prevent oxidation of the metal parts of the connector.

Cooling and concomitant contraction of the jacket causes the multiple parts to adhere tightly together and the jacket 22 to bond or fuse to the ceramic sheath. Further, due to the contraction, the insulating cylinder 30 fuses or connects the pin 2 and the jacket 22, so that the pin 2 is prevented from rotating due to the rotational force when they are connected by the male screw 92.

By cooling and shrinking followed by heating, the seal ring 1
2 are connected to the pin 2, the jacket 22, and the ceramic sleeves 14, 16 at faces 90, 24, 18, 20, respectively. The bond between the parts is a chemical bond and a physical seal, the latter being a tight bond of the two parts by shrinkage.

The fluid tight seal of surfaces 90, 24, 18, 20 is ensured in several ways. In one embodiment of the invention, the coefficient of thermal expansion of seal annulus 12 is matched to the coefficient of thermal expansion of jacket 22. Therefore, these two members expand and contract in a mutually complementary manner, and the seal ring 12 will never crack due to the expansion of both members. Further, both members firmly press against each other while effectively maintaining the seal on the surface of the seal ring 12.

Metals with a coefficient of thermal expansion matching that of compressed glass are often noncorrosive, such as stainless steel or stainless steel alloys, but metals with a coefficient of thermal expansion matching that of refractory materials are generally corrosive or otherwise corrosive. Otherwise, they either have poor physical properties, are difficult to obtain, or are unsuitable for underground use because of their magnetic properties.

The term "matching" as used for the coefficients of thermal expansion of various materials does not necessarily mean that the coefficients of thermal expansion are the same, but rather that the original state of the connector when exposed to temperature changes. This means that it expands and contracts while maintaining its .

FIG. 5 shows another embodiment of the invention.

In this case, the coefficient of thermal expansion of the metal jacket does not match the coefficient of thermal expansion of the compressed glass typically used to make the seal annulus 12.

In this embodiment, the seal ring 12 has a core 12a of borosilicate glass, potassium soda, barium glass, or other compressed glass with superior thermoplastic properties than the core 12a, and the jacket 2
2, and an outer covering 12c made of relatively thin glass and provided between the core 12a.

Suitable glasses for the outer coating 12c include those containing relatively large amounts of lead oxide or heavy metal oxides, such as silicate, borate, or borosilicate glasses. The thermoplastic coating can typically be a high lead silicate glass containing 72%, 14%, and 14% PbO, _B2O3 , and _SO2 by weight, respectively _. . Also,
Other glasses can also be used as long as they have thermoplastic properties better than compressed glass.

FIG. 6 shows yet another embodiment.

In this embodiment, ceramic sleeves 14,1
The thermal expansion coefficient of 6 is the core 12a of the seal ring 12.
It is not consistent with that of . The embodiment shown in FIG.
It is composed of a central annular core 12a made of compressed glass as described above, and annular end coverings 12b and 12d made of glass having thermoplastic properties superior to that of the core 12a.

As described in the embodiment of FIG. 5, the relatively thin thermoplastic coatings 12b, 12d are comprised of high lead silicate or other similar materials. coating 12b,
12c and 12d are actually extremely thin and have the thickness of a single molecule, but are shown thick for convenience of explanation.

In the embodiment of FIGS. 5 and 6, the glass seal ring is constructed from two parts. namely, compressed glass and glass that has superior thermoplastic properties compared to compressed glass.

In these embodiments, the compressed glass is first bonded to the thermoplastic glass and then to the jacket or refractory section. If the compressed glass core is not surrounded by a thermoplastic glass cladding,
All three parts above are combined.

In a further embodiment, a layer of thermoplastic glass (not shown) is provided in the sealing ring 12 near the pin 2.

The connector of the present invention therefore includes a number of means for preventing leakage from a high pressure area outside the connector to a low pressure area within the instrument housing I, as well as providing a number of other advantages. I hope you understand what is going on.

At low pressures, the female member's outer sleeve 74 seals against the tubular portion 26 of the jacket 22 to prevent leakage between the male and female members. At high temperatures above 204 degrees Celsius (400 degrees Celsius), the outer jacket 74 loses its properties and does not provide an effective seal. At higher temperatures and pressures, the outer sleeve 74 compensates for the inner sleeve 50, which sometimes cannot provide an effective seal at lower pressures. The sealing properties of the polymer inner jacket are enhanced by the annular groove 85 and annular ridge 32.

The rigid brass sleeve 56 prevents the sleeves 50 and 74 from protruding into the notch 60, which would be problematic under any pressure. Similarly, gasket 40
prevents leakage between the housing I and the tubular portion 28 at low temperatures, while the gasket 44 prevents leakage between the same portions at high temperatures and pressures.

If for some reason fluid leaks between the male and female parts, further leakage into the housing between the parts of the male member is prohibited because the parts of the male member are fused together. Ru.

Seal ring body 1 made of glass with high compressive force
2 helps protect the ceramic insulating sleeves 14, 16 from cracking due to expansion of the jacket 22. If the ceramic sleeve 14 cracks or for some other reason leaks from the end of the lead wire in the female member through the male member, this leakage is caused by the seal formed in the seal annulus 12. and cannot reach below the instrument housing.

Therefore, the use of a relatively small sealing ring 12 allows the use of a ceramic sleeve, which is preferred as an insulator, over the entire main portion of the male member. The coefficient of thermal expansion of the ceramic sleeve does not necessarily have to match the coefficient of thermal expansion of the metal jacket.

As already mentioned, the pin 2 may be made of a nickel alloy or other metal having the same coefficient of thermal expansion as the ceramic, in order to further increase the outstanding properties of the connector according to the invention.

Next, embodiments of the present invention will be listed.

(1) In the electrical connector described in the claims, the seal ring is made of compressed glass.

(2) In the electrical connector described in the claims, the coefficient of thermal expansion of the seal ring body must match the coefficient of thermal expansion of the jacket.

(3) In the claimed electrical connector, the sealing annulus consists of an inner core made of compressed glass and a relatively thin layer of glass having superior thermoplastic properties to the core; , be placed between the core and the jacket.

(4) In the electrical connector recited in the claims, the seal ring body consists of a central core made of compressed glass and both end coatings made of glass having superior thermoplastic properties compared to the core; The end covering shall be thinner than the core and located between the core and one of the refractory coverings.

(5) In the claimed electrical connector, the jacket has a portion that extends longitudinally beyond the second fireproof coating toward the second end of the pin, and the and the extension of the above jacket.

(6) In the electrical connector described in the preceding paragraph, the male member shall further include a gasket, which gasket shall be placed on the outer circumferential surface of the jacket extension in order to provide a seal between the jacket extension and the appliance.

(7) In the claimed electrical connector, the female member is comprised of an elastic heat-resistant polymer inner jacket having an aperture for receiving the male member; an elastomeric outer sleeve having a hole aligned with the opening of the sleeve, and a conductive element extending through the sleeves;
Means for removably engaging the first end of the pin is disposed within the inner sleeve and means for making electrical contact between the pin and the conductive element.

(8) In the electrical connector described in the preceding paragraph, the jacket has a hole and a portion that is tightly fitted into the hole of the outer cover tube, has an annular protrusion on its outer peripheral surface, and has an inner cover tube. has an annular groove in the hole,
When the male member and the female member are connected, the annular protrusion should fit tightly into the annular groove.

(9) In the electrical connector described in paragraph (7) above,
The female member further has a rigid sleeve disposed within the bore and means for making electrical contact with the pin;
The removably engaging means comprises a conductor spring that comes into contact with the conductor element.

(10) In the electrical connector described in paragraph (6) above,
The inner cover tube is made of fluorocarbon resin.

(11) In the electrical connector described in paragraph (6) above,
The conductive element includes a lead wire, an internal insulating heat-resistant polymer sheath disposed around the lead wire, and
It shall consist of an outer protective elastomeric sheath disposed around this inner sheath.

(12) In the electrical connector described in the claims, the coefficient of thermal expansion of the pin must match the coefficient of thermal expansion of both fireproof coatings.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional front view of a portion of the electrical connector and instrument housing of the present invention, with several parts of the connector not shown in section. Figure 2 shows 2- in Figure 1.
FIG. 2 is a cross-sectional view of the male member along two lines. FIG. 3 is a cross-sectional view taken along line 3-3 in FIG. 1, showing a state in which the female member is fitted with the male member.
FIG. 4 is a diagram showing the same part as FIG. 3, but showing a state in which the female member is not fitted with the male member. FIG. 5 is an enlarged longitudinal sectional view of a portion of a male member showing one type of glass seal ring. FIG. 6 is an enlarged longitudinal sectional view of a portion of a male member showing another type of glass seal ring. M...Male member, F...Female member, I...Instrument housing, 2...Pin, 4...Small diameter part, 6...Large diameter part, 8, 10...End part, 12...Seal ring body ,1
2a...Core, 12c...External coating, 12b, 1
2d... Annular end covering, 14, 16... Sleeve, 18, 20... Surface, 22... Metal jacket, 24... Inner surface, 26, 28... Cylindrical part, 27
... Enlarged polygonal part, 30 ... Insulating tube, 32 ... Annular protrusion, 36 ... Inner surface, 38 ... Male thread, 40 ...
... O-ring, 42 ... Annular groove, 44 ... Annular body gasket, 46 ... Hole, 48 ... Female thread, 50 ...
Inner cover tube, 52... long hole, 54... mouth, 56...
... Rigid sleeve, 58 ... Spring, 58a ... Fixed part, 58b ... Lip, 60 ... Notch hole, 62 ...
Tip, 66... Extension, 68... Hole, 70, 72
... Long groove, 74 ... External cover tube, 76 ... Hole, 78
... Lead wire, 80 ... Inner covering, 82 ... Outer covering, 85 ... Annular groove, 84 ... Shoulder, 90 ...
Face, 86, 88...Shoulder, 92...Male thread.

Claims (1)

[Claims] 1 Consisting of a male member and a female member that can be detachably connected to each other, the male member includes a conductor pin having a first end and a second end, and a glass conductor pin surrounding the outer periphery of the pin in the middle between these ends. a first fireproof coating surrounding the outer periphery of a portion of the pin in the vicinity of the seal ring and between the first end of the pin and the seal ring; a second refractory coating adjacent and surrounding a portion of the pin between the seal annulus and the second end of the pin; 1. An electrical connector comprising a metal jacket surrounding the outer periphery of portions of both refractory sheaths, the seal ring being coupled to the jacket, the pin, and both refractory sheaths.