Source: http://www.google.com/patents/US4830630?dq=7,468,661
Timestamp: 2014-07-24 05:04:36
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Patent US4830630 - Hermetically sealed electrical terminal - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign in<nobr>Advanced Patent Search</nobr>PatentsAn hermetically sealed terminal construction having a terminal pin assembly wherein inner and outer pin parts are interconnected by a fuse link surrounded by a protective capsule defining an expansion cavity, the terminal pin assemblies extending through and being hermetically sealed to sleeves forming...http://www.google.com/patents/US4830630?utm_source=gb-gplus-sharePatent US4830630 - Hermetically sealed electrical terminalAdvanced Patent SearchPublication numberUS4830630 APublication typeGrantApplication numberUS 07/235,027Publication dateMay 16, 1989Filing dateAug 22, 1988Priority dateAug 22, 1988Fee statusLapsedPublication number07235027, 235027, US 4830630 A, US 4830630A, US-A-4830630, US4830630 A, US4830630AInventorsHilliard DozierOriginal AssigneeHilliard DozierExport CitationBiBTeX, EndNote, RefManPatent Citations (5), Referenced by (5), Classifications (10), Legal Events (4) External Links: USPTO, USPTO Assignment, EspacenetHermetically sealed electrical terminalUS 4830630 AAbstract An hermetically sealed terminal construction having a terminal pin assembly wherein inner and outer pin parts are interconnected by a fuse link surrounded by a protective capsule defining an expansion cavity, the terminal pin assemblies extending through and being hermetically sealed to sleeves forming part of the supporting base, including a dielectric sealing member which covers the protective capsules and contiguous portions of the adjoining pin parts, the sealing member being adapted to fracture upon rupture of the protective capsules caused by disintegration of the fuse links, thereby causing the adjoining pin parts and contiguous areas of the sealing member to separate from the remainder of the terminal, thereby cutting off the flow of current through the terminal.
What is claimed is: 1. An hermetically sealed terminal construction comprising,a terminal body comprising a base having inner and outer sides and at least one annular opening therein defined by a sleeve projecting outwardly from the inner side of said base, a terminal pin assembly adapted to be mounted on said base, said terminal pin assembly comprising a pair of pin parts lying in axially spaced relation to each other, a fuse link interconnecting the inner ends of said pair of pin parts, and a protective capsule surrounding said fuse link and engaging the inner ends of said pin parts, said capsule defining an expansion cavity surrounding said fuse link, said capsule being adapted to rupture upon the build-up of pressure in said cavity caused by current induced disintegration of said fuse link, and sealing means securing said terminal pin assembly to said terminal body, with a first of said pin parts extending centrally through said sleeve, and the other of said pin parts and said capsule projecting beyond said sleeve, a first component of said sealing means lying within said sleeve and providing an hermetic seal between said first pin part and said terminal body, a second component of said sealing means comprising a sealing member covering at least one side of said terminal body and surrounding and covering said protective capsule and contiguous portions of the other of said pin parts, said sealing member being adapted to be fractured upon rupture of said protective capsule to separate the other of said pin parts and contiguous areas of said sealing member from the remainder of said terminal. 2. The hermetically sealed terminal construction claimed in claim 1 wherein the first component of said sealing member comprises a glass-to-metal seal, and wherein said second component comprises a molded dielectric sealing member.
4. The hermetically sealed terminal construction claimed in either of claims 2 and 3 wherein said sealing means includes a third component comprising a molded dielectric sealing member covering the remaining side of said terminal body and adjacent portions of said first pin part.
5. The hermetically sealed terminal construction claimed in claim 1 wherein said protective capsule comprises a cup-shaped body having a removable cap at one end thereof.
6. The hermetically sealed terminal construction claimed in claim 5 wherein said cup-shaped body and said removable cap have mating undercut shoulders, whereby said cap is snap-fitted to said body.
7. The hermetically sealed terminal construction claimed in claim 5 wherein said protective capsule is formed from a plastic material, and wherein the walls of said capsule are sufficiently rigid to resist collapse during formation of said surrounding sealing member.
8. The hermetically sealed terminal construction claimed in claim 1 wherein the inner ends of said pin parts have axial bores therein sized to receive the opposite ends of said fuse link, and wherein the inner ends of said pin parts are crimped about the opposite ends of said fuse link.
9. The hermetically sealed terminal construction claimed in claim 8 wherein said protective capsule has recesses in its opposite ends adapted to receive the inner ends of said pin parts.
10. The hermetically sealed terminal construction claimed in claim 1 wherein said sealing member has an annular enlargement surrounding said protective capsule and the contiguous portion of said other pin part, and includes an integral collar at the outer end of said annular enlargement.
11. The hermetically sealed terminal claimed in claim 10 wherein said sealing means includes a sealing member component covering the remaining side of said terminal body, said sealing member component having an annular enlargement surrounding a portion of said first pin part, including an integral collar at the outer end of said last-named annular enlargement.
12. The hermetically sealed terminal construction claimed in claim 1 wherein said terminal body has a plurality of sleeves therein, and wherein a terminal pin assembly is mounted in each of said sleeves.
13. A terminal pin assembly for use in an hermetically sealed terminal, said assembly comprising:a first pin part, a second pin part lying in axially spaced relation to said first pin part, a fuse link interconnecting said first and second pin parts, and a protective capsule surrounding said fuse link and engaging the adjoining ends of said first and second pin parts, the surrounding walls of said capsule being spaced from said fuse link to define an expansion chamber, said capsule being adapted to rupture upon the build-up of pressure in said expansion chamber caused by rapid disintegration of said fuse link. 14. The terminal pin assembly claimed in claim 13 wherein said protective capsule comprises a cup-shaped body having a removable cap at one end thereof.
15. The terminal pin assembly claimed in claim 14 wherein said cup-shaped body and said removable cap have mating undercut shoulders whereby said cap is snap-fitted to said body.
16. The terminal pin assembly claimed in claim 15 wherein said protective capsule is formed from a plastic material.
In contrast to the foregoing, the present invention provides a terminal construction which provides for substantially instantaneous cut-off of current when a predetermined current induced temperature level is reached, including a unique pin construction whereby portions of the terminal pins are physically separated from the remainder of the terminals while maintaining the integrity of the hermetic seals.
SUMMARY OF THE INVENTION An analysis of past failures of hermetically sealed terminals leads to the conclusion that undesirable venting or blow-out of the terminals occurs because of several factors:
In order to prevent these potentially catastrophic failures, the present invention provides a terminal construction wherein the terminal pins are formed by inner and outer pin parts interconnected by a high-temperature, high-current fuse link formed from a silver alloy which will melt and/or vaporize when heated to a predetermined temperature, thereby rapidly breaking the electrical connection between the inner and outer pin parts. Preferably, the fuse link will be formed from a silver alloy having a melting point in the range of 1100�-1450� F., although it will be understood that the melting point and current carrying capacity of the fuse link will be chosen in accordance with the electrical characteristics of the device being operated. For example, in the case of a refrigeration header, the fuse link will be sized to carry current equal to the locked rotor amperage of the compressor for a continuous time period in excess of three minutes and a current of two times the locked rotor amperage for approximately two to six seconds.
In accordance with the invention, either the inner or the outer pin part may be separated from the remainder of the terminal, although preferably the terminal will be constructed so that the outer pin part will separate, thereby giving a visual indication that there has been a major fault condition. To ensure the desired separation of the pin parts, the capsule is preferably formed in two parts, the first comprising a cup-like body adapted to receive one of the pin parts, the body being closed by a cap adapted to make snap-lock connection with the body, the cap engaging the other pin part. When pressure builds up in the capsule due to fuse vaporization, the path of least resistance is through the cap and the areas of the sealing member surrounding the cap, which effectively blows-away the cap, the adjacent pin part and the surrounding areas of the sealing member.
The terminal construction of the present invention may be utilized with either "soft-seal" terminals wherein the terminal pins are mounted to the terminal body by means of a dielectric material which is molded in situ to the body and pins, or utilizing "hard seal" techniques wherein the pins are mounted in the terminal body by means of glass-to-metal or ceramic-to-metal seals. Where "hard seals" are utilized, at least one side of the terminal body, including the fuse links and the protective capsules, will be encased in a molded in situ dielectric sealing material.
FIG. 5 is a vertical sectional view similar to FIG. 4 illustrating the condition of the parts upon melting of the fuse link.
FIG. 6 is a vertical sectional view similar to FIG. 5 showing the manner in which external portions of the terminal have been separated from the remainder of the terminal under major fault conditions.
FIG. 7 is a side elevational view of a terminal utilizing glass-to-metal seals in partially assembled condition.
FIG. 8 is a side elevational view of the terminal of FIG. 7 in the fully assembled condition.
FIG. 9 is a side elevational view of the terminal of FIG. 8 showing the separation of the outer portion of one of the terminal pins.
FIG. 10 is a vertical sectional view similar to FIG. 4 illustrating a terminal in which the terminal pin assembly is reversed so that the inner pin part will break away.
FIG. 11 is a vertical sectional view similar to FIG. 8 showing a reversed terminal pin assembly with a glass-to-metal seal.
DESCRIPTION OF THE PREFERRED EMBODIMENTS As seen in FIG. 1, the terminal pin assembly, indicated generally at 1, comprises a first or inner pin part 2 and a second or outer pin part 3 interconnected by a fuse link 4. Preferably, the pin parts 2 and 3 will be formed from a copper alloy, whereas the fuse link will be formed from a silver alloy. In the embodiment illustrated, the fuse link is cylindrical and is adapted to have its opposite ends received in axial bores 5 in the pin parts 2 and 3, with the inner ends of the pin parts crimped about the ends of the fuse link, as indicated at 6, thereby ensuring positive electrical contact between the pin parts and the fuse link. The fuse link need not be cylindrical, but rather may be formed as a flat strip or of other configuration, such as a rectangular bar. To this end, the bores 5 in the pin parts can be configured to conform to the configuration of the fuse link, or the opposite ends of the fuse link can be configured to be received in the bores 5.
Preferably, the inner pin part 2 will be provided with a tapered knurled portion 7 which will assist in preventing rotation of the pin part, as well as provide an enlarged surface area which will tightly bond to the sealing member in which the terminal pin assembly is mounted. The inner pin part 2 also may be provided with one or more enlarged shoulders 8 which further enhance the surface area of the bond with the sealing member and additionally serve to resist contraction of the sealing material during curing.
In cases where a major fault causes very high currents to flow, and the vaporization of the fuse material is very rapid, extremely high internal capsule pressures result. In order to prevent continuous arcing and temperature build-up, the protective capsule 9 is designed to be popped apart and is preferably formed in two parts which, as best seen in FIG. 2, comprise a cup-like body 11 and a cap 12 adapted to be snap-fitted to the open end of the cup-like body 11. To this end, the body 11 and cap 12 are provided with mating undercut shoulders 13 and 14 which provide an interlock. Preferably, the body and cap will be formed from a high temperature plastic material, such as 6--6 Nylon or Polycarbonate, which is sufficiently strong to prevent collapse during the molding of the conductor pin assemblies to the terminal body. In this connection, the terminal pin assembly, i.e. the inner and outer pin parts, the fuse link, and the protective capsule will be pre-assembled to the condition shown in FIG. 1 prior to assembly with the body of the terminal. Preferably, the inner ends of the pin parts 2 and 3 will seat in mating recesses 15 and 16 formed in the cup-like body 11 and cap 12, respectively.
Referring next to FIGS. 3 and 4, the terminal body, indicated generally at 17, is of shallow cup-shaped configuration, having an annular body wall 18 terminating at its outermost end in an out-turned mounting flange 19 and at its innermost end in a base 20 interrupted by spaced apart integral sleeves 21 lying within the confines of the annular body wall 2. The configuration of the terminal body 17 is conventional for a three-pin terminal and can be formed of any suitable material, although for most installations a steel body is preferred since it is inexpensive and can be readily formed into the desired shape. The particular material from which the body member is formed is normally determined by the mode of installation of the terminal, depending upon whether it is to be welded, soldered, braised, threaded, press-fitted or adhesively secured in place. The configuration of the sleeves 21 does not constitute a limitation upon the invention, and they may be of cylindrical or tapered configuration, or otherwise configured to effectively increase the area of interface between the sealing material and the terminal body, so as to inhibit the formation of leakage paths from one side of the terminal to the other due to thermal expansion and contraction of the parts. To this end, and as shown in FIG. 4, the distal ends of the sleeves 21 may be relieved and flanged, as indicated at 22.
In the embodiment of FIGS. 3 and 4, the terminal pin assemblies 1 are mounted in the sleeves by means of a sealing member or insulator 23 which hermetically seals the terminal pin assemblies to the terminal body 17. The sealing member 23 is preferably formed as a unitary body composed of a dielectric material molded in situ to the desired configuration, the sealing member being bonded to both sides of the base 20.
Various known sealing materials may be used, such as epoxy molding compounds marketed under the trademark Epiall. On the inner side of the terminal body, the sealing member includes annular enlargements 24 which surround the sleeves 21 and adjacent areas of the inner pin parts 2, together with an enlarged central portion 25 interconnecting the sleeve-surrounding annular enlargements 24. On its outerside, the sealing member 23 is provided with similar annular enlargements 26 which surround the protective capsule 9 and adjoining portions of the outer pin parts 3. The outer side of the sealing member 23 also includes an enlarged central portion 27 which interconnects the annular enlargements 26. If desired, the annular enlargements 24 and 26 may be provided with integral collars 28 and 29 surrounding the inner and outer pin parts 2 and 3, respectively, at the points where the pin parts emerge from the enlargements, the collars acting to relieve stress concentrations which could result in aging cracks in the peripheral areas of the seals immediately surrounding the pin parts. The collars additionally serve as seats for a plug other connector for receiving the pin parts. It will be understood that the pin parts may be provided with conventional conductor tabs at one or both ends, as may be required for a particular installation.
In the event one or more of the terminal pin assemblies is subjected to a major fault condition, the fuse links 4 for such pins will melt or vaporize in the area of cavity 10 in the protective capsule 9, such condition being illustrated in FIG. 5 wherein the fuse link residue is indicated at 30. The disintegration of the fuse link cuts-off current flow through the terminal pin and hence to the compressor motor.
In cases where a major fault causes very high currents to flow, and the vaporization of the fuse material is extremely rapid, extremely high internal pressures will be generated within the capsule 9. In order to relieve this pressure in a manner which will prevent venting of the terminal and yet positively cut off current flow, the protective capsule is designed to be separated, the pressure generated in the cavity 9 causing the cap 12 to be blown away, carrying with it portions of the surrounding annular enlargement 26 and the outer pin part 3. This action is illustrated in FIG. 6. While the precise areas of fracture may vary, fracture will normally occur along the annular walls of the enlargements 26 which are relatively thin and hence offer less resistance to rupture than other areas of the sealing member. Even though the terminal is effectively destroyed insofar as future use is concerned, it nonetheless maintains its integrity in that a blow-out of the sealing material within the sleeves 21 is prevented. After separation, any exposed portion of the inner pin part 2 is encased by the cup-like body 11, or if the cup-like body is also dislodged, the exposed portion of the inner pin part is essentially flush with the remainder of the sealing member and hence cannot serve as a usable contact should service personnel attempt to reconnect the terminal.
Referring next to FIGS. 7-9 which illustrate an alternative embodiment of the invention utilizing glass to metal seals, and wherein like parts have been given like reference numerals, the inner pin parts 2a will comprise steel pins, such as high conductivity copper core steel pins, which are necessitated by the fact that their coefficient of expansion is compatible with the glass seals 31 utilized to secure the inner pin parts 2a to the levels 21a in the terminal body 17. In this embodiment, the inner pin parts 2a are first assembled in the manner shown in FIG. 7, whereupon the terminal pin assemblies are then completed by the attachment of the fuse links 4, the protective capsules 9 and the outer pin parts 3a. When the terminal pin assemblies are completed, the sealing member 23a is molded in situ to the terminal body 17, thereby completing the terminal, which takes the configuration shown in FIG. 8. Since the inner pin parts 2a are sealed to the terminal body 17 by the glass seals 31, it is necessary to fill the mold for the sealing member 23a from both sides of the terminal body. It may be noted, however, that it is not absolutely necessary to have the sealing member 23a cover the inner side of the terminal body since the terminal is already sealed with glass. However, it is preferred to include the internal portion of the sealing member since it significantly increases the over-surface path to ground and requires much more internal contamination before arcing can occur.
In use, the terminal of FIGS. 7-9 will perform in the same manner as the emodiment shown in FIGS. 1-6, the parts separating in the manner illustrated in FIG. 9 when one or more of the pin assemblies is subjected to fault conditions.
As seen in FIG. 10, the position of the terminal assemblies may be reversed so as to locate the fuse link 4 and capsule 9 on the inside of the terminal body 17, in which event the outer pin parts 3 become the inner pin part 3b and the inner pin parts 2 become the outer pin parts 2b. Similarly, the positions of the sealing member 23b will be reversed so that the enlargements 26b will surround the protective capsules 9. While in this instance the inner pin part 3b will separate on the inner side of the terminal body, the annular enlargement 26b will fracture in the same manner as shown in FIG. 6, thereby maintaining the integrity of the hermetic seals in the areas of the sleeves 21 while breaking the circuit between the pin parts.
In like manner, and as seen in FIG. 11, the construction of the glass-to-metal hermetically sealed terminal of FIGS. 7 and 8 may be reversed, in which event the inner pin parts 2a become the outer pin parts 2c and the outer pin parts 3a become the inner pin parts 3c. In this instance, the outer pin parts 2c will be first sealed to the body 17 by the glass or ceramic seals 31c, whereupon the fuse links 4 and inner pin parts 3c on the inner side of the terminal body will be assembled and the sealing member 23c molded in situ with the enlargements 26c surrounding the capsules 9 and adjacent portions of the pin parts 3c.
Patent CitationsCited PatentFiling datePublication dateApplicantTitleUS3160460 *Jan 17, 1962Dec 8, 1964Fusite CorpTerminal assembly having conductor pins and connector blockUS4461925 *Aug 31, 1981Jul 24, 1984Emerson Electric Co.Hermetic refrigeration terminalUS4480151 *Jul 19, 1982Oct 30, 1984Hilliard DozierTemperature stable hermetically sealed terminalUS4609774 *Jun 18, 1985Sep 2, 1986B & W Electronic Enclosures, Inc.Electrical terminal construction with fusible sectionUS4739551 *Jul 14, 1986Apr 26, 1988Emerson Electric Co.Hermetic terminal assembly pin and method and apparatus for making the same* Cited by examinerReferenced byCiting PatentFiling datePublication dateApplicantTitleUS4964788 *Mar 21, 1990Oct 23, 1990Tecumseh Products CompanyHermetic terminal with terminal pin assemblies having fusible links and motor compressor unit including sameUS8339773 *May 27, 2010Dec 25, 2012Abb S.P.A.Device for connecting an electric line to a circuit breakerUS20100304590 *May 27, 2010Dec 2, 2010Abb S.P.A.Device For Connecting An Electric Line To A Circuit BreakerEP0447607A2 *Aug 29, 1990Sep 25, 1991Tecumseh Products CompanyHermetic terminal with terminal pin assemblies having fusible links and motor compressor unit including sameWO2005083846A1 *Feb 24, 2005Sep 9, 2005Kemlon Products & Dev Co LtdHybrid glass-sealed electrical connectors* Cited by examinerClassifications U.S. Classification439/620.29, 439/736, 174/152.0GM, 337/3International ClassificationH01H85/20, H01R13/52Cooperative ClassificationH01R13/521, H01H85/201European ClassificationH01R13/52F, H01H85/20CLegal EventsDateCodeEventDescriptionJul 29, 1997FPExpired due to failure to pay maintenance feeEffective date: 19970521May 18, 1997LAPSLapse for failure to pay maintenance feesDec 26, 1996REMIMaintenance fee reminder mailedSep 2, 1992FPAYFee paymentYear of fee payment: 4RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services©2012 Google