US2829217A - Current responsive control device - Google Patents

Current responsive control device Download PDF

Info

Publication number: US2829217A
Authority: US; United States
Prior art keywords: stud; core; armature; current; extending
Prior art date: 1954-05-25
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Expired - Lifetime

Application number

US432078A

Other languages

English (en)

Inventor

Max B Fornwalt

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

General Electric Co

Original Assignee

General Electric Co

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1954-05-25

Filing date

1954-05-25

Publication date

1958-04-01

1954-05-25 Application filed by General Electric Co filed Critical General Electric Co

1954-05-25 Priority to US432078A priority Critical patent/US2829217A/en

1955-05-23 Priority to CH336486D priority patent/CH336486A/de

1955-05-23 Priority to GB14833/55A priority patent/GB768937A/en

1958-04-01 Application granted granted Critical

1958-04-01 Publication of US2829217A publication Critical patent/US2829217A/en

1975-04-01 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

Links

239000004020 conductor Substances 0.000 description 29
239000002131 composite material Substances 0.000 description 3
230000004907 flux Effects 0.000 description 3
230000000694 effects Effects 0.000 description 2
230000005484 gravity Effects 0.000 description 2
240000001973 Ficus microcarpa Species 0.000 description 1
241001435619 Lile Species 0.000 description 1
230000002159 abnormal effect Effects 0.000 description 1
238000010276 construction Methods 0.000 description 1
230000008878 coupling Effects 0.000 description 1
238000010168 coupling process Methods 0.000 description 1
238000005859 coupling reaction Methods 0.000 description 1
230000003111 delayed effect Effects 0.000 description 1
230000005415 magnetization Effects 0.000 description 1
238000004519 manufacturing process Methods 0.000 description 1
230000000452 restraining effect Effects 0.000 description 1
230000000979 retarding effect Effects 0.000 description 1

Images

Classifications

- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01H—ELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
- H01H71/00—Details of the protective switches or relays covered by groups H01H73/00 - H01H83/00
- H01H71/10—Operating or release mechanisms
- H01H71/12—Automatic release mechanisms with or without manual release
- H01H71/44—Automatic release mechanisms with or without manual release having means for introducing a predetermined time delay

Definitions

This invention relates to current-responsive control devices and, more parti-cularly, to an electromagneticallyoperated, current-responsive trip device for a circuit breaker.
a convenient manner of operating an electroresponsive device in response to predetermined current conditions in an electrical conductor is to provide the device with a magnetizable core mounted about the conductor.
a magnetizable core mounted about the conductor.
Such a core when sutciently magnetized in response to predetermined current conditions in the conductor can be utilized to attract an armature, which upon actuation, will perform a preselected control function.
the magnetization of the core has been appreciably influenced, not only by current conditions in the one conductor about which the core is mounted, but also by current conditions in the adjacent conductors.
a current-responsive control device is provided with a magnetizable core mounted about one conductor of a plurality of closely spaced conductors
the current-responsive device is the calibrated, time-delayed tripping device of a circuit breaker
armature movable toward said core in response to current flowing through said stud in excess of a predetermined value is arranged to perform a preselected control function.
Fig. l is an elevational view showing a current-responsive circuit breaker trip device embodying my invention.
Fig. 2 is an elevational view showing a current-responsive circuit breaker trip device embodying my invention.
FIG. 3 is a plan view, partly in section, of the trip device of Fig. l.
Fig. 3 illustrates an arrangement in which a trip device such as shown in Figs. l and 2 is applied to each of the three closely spaced poles of 'a circuit breaker.
Figs. l and 3 i have illustrated my invention as applied to a timedelayed electro-magnetic trip device of a circuit breaker. Since the circuit breaker mechanism forms no part of the present invention, l have shovyn only such parts of the breaker as are required for an understanding of my invention.
Figs. l and 3 i have shown a circuit breaker it) comprising a rotatable trip shaft il having trip members 12, 12a, and 12b suitably secured thereto.
the trip shaft il. is rotated sufciently in a counterclockwise direction (as seen in Fig. l) by a force applied to any one of the trip members 12, 12a or 12b, the shaft 11 acts to release a suitable latch (not shown).
Each pole of the circuit breaker comprises an elongated terminal conductor, or stud, such as 1S about which is mounted magnetizable U-shaped core 16 of a trip device i7.
the stud 15 is formed in two parts 18 and 19 which are secured together by bolts 20 threaded into suitable apertures in part 19.
the composite stud structure comprises transversely-spaced, longitudinally-extending segments 2l and 22 and a transversely-extending portion 23 electrically interconnecting the segments.
the U- shaped core 16 is mounted in a position in which its bight portion 27 extends longitudinally of the stud 15 and its legs 24 straddle the transversely-extending stud portlon 23.
the composite stud l5 may be thought of as having staggered, transverselyextending, longitudinally-spaced recesses 23a and 23b which receive the legs 24 of the U-shaped core.
the recess 23a of Fig. 3 has, opposite its mouth, an end wall which faces toward the adjacent stud 15u, and the recess 23b has, opposite itsmouth, an end wall 29 which faces away from the adjacent stud 15a.
the core and the segment 22 are provided with registering openings receiving suitable bolts 2S.
the openings in segment 22 are threaded so that the correspondingly threaded bolts 25 may be tightened to clamp the core firmly against the segment 22.
this armature structure 3h comprises a pair of independently-movable armatures 3l. and 32 mounted to pivot about a trans ⁇ versely-extendiug shaft 33.
This shaft 33 which is suitably supported on the extended legs 34 of a pair of spaced U-shaped frame members secured to the laminated cores i6, carries a suitable sleeve 33a for spacing the armatures 3l and 32.
the armatures 3l and 32 are biased to a disabled position against a stop 35 by means of gravity and by means of calibrated springs 39, d3, and 56 forming a part of a timing mechanism 36, which is enclosed by a housing 36a.
springs and the timing mechanism are described in greater detail hereinafter.
the housing 36a is joined to the core by suitable support brackets 36b so that the composite trip device constitutes a unitary structure which may be assembled as a unit about the stud 1S.
the escapement mechanism 3'7 is eiective to provide a relatively short inverse time delay in the movement olf armature 32 to the attracted position when the stud l5 is energized by currents within a predetermined intermediate range of values.
the other armature 31 is delayed by means of the dashpot 38 to respond at a slower rate than armature
the escapement-retarded armature 32 alone trips the breaker for this intermediate range of currents.
lt is to be understood that the speed at which the armature 32 moves varies directly with the magnitude of the current, so that an inverse time element is provided for this intermediate range of currents.
the dashpot-retarded armature 3l rather than the escapement-retarded armature, is effective to trip the breaker. More particularly, for such low current conditions, the attractive force provided by the magnetic core lo is insutlcient to overcome the force of calibrating spring d3 associated with the escapement-retarded armature .32 but is sufficient to overcome the forces restraining the dashpot-retarded armature 31. As a result, under such low current conditions, the dashpot-retarded armature ic alone elective to trip the breaker. lt is to be understood that the speed at which the dashpot-retarded armature 3l moves varies directly with the magnitude of the current, so that an inverse time element is provided for this lower range of currents.
the armature 3l is permitted to move to its attracted position substantially instantaneously by means of a yielding connecticn provided by a break-away spring 39, to be described in greater detail hereinafter.
the break-away spring 39 in effect, forms a positive coupling between arma- 31 ci the dashpot piston dl).
the attractive forces on the armature are sutlicient to stretch the spring 39 and permit the armature 31 to ore-ak away from the restraint of the retarded dashpot piston dil and to move substantially instantaneously into the attracted position.
crank 40a having one end coupled to armature 32 through a link 44, which is pivotally connected to the armature 32.
the other end of the crank 40a is coupled to escapement wheel 41 by means of a rack 42 and pinion 42a.
a tension spring 43 connected to the crank 40a provides a force which biases the armature 32 toward the droppedout position of Fig. l.
Suitable means (not shown) are provided for adjusting the tension of spring 43 whereby the response of armature 32 to predetermined current conditions may be suitably calibrated.
This linkage 5l comprises a crank 51, which is pivotally mounted on a xed pivot 52 and has one end suitably coupled to dashpot piston dil.
the other end of the crank 5i is coupled through spring 39 to a link 53, which in turn, is pivotally joined at its upper end to armature 3i.
the lower end of link 53 is carried by a support arm 5ft, which is freely pivoted on pivot 52.
the break-away spring 39 normally urges the crank Sl to pivot counteclockwise about its pivot S2 and into a position wherein a stop 55 on the crank 51 abuts against support arm 54.
the spring 39 acts as an essentially rigid link and thus, the armature 31 moves as a unit with the retarded dashpot piston 4t). However, for currents above this limit, the armature 31 moves the link 53 downward with suicient speed and force to stretch the spring 39 so as to permit the armature to move essentially free of ⁇ restraint from dashpot 38, whereby to permit an instantaneous response of armature 31.
a spring 56 is provided for biasing the armature 31 to its dropped-out position.
the tension of this Spring 56 can 'be adjusted 'by means of an adjusting nut 57, whereby the response of armature 31 to predetermined current conditions may be suitably calibrated.
Suitable means, not shown, are also provided for adjusting the tension of break-away spring 39 whereby further calibration of the armature may be carried out.
current responsive trip devices of the general type shown in the drawing have been utilized, it has been customary to mount the U-shaped core about the elongated stud in such a manner that the legs of the corc are disposed in a plane perpendicular to the longitudinal axis of the stud.
cent conductors have detrimentally affected this calibration of the trip device and have resulted in unpredictable operation thereof.
Constructing and arranging the maogegaan? netic core of the stud in accordance with the present invention makes it possible to maintain this calibration of the trip device constant and essentially independent of current conditions in the adjacent conductors.
the U-shaped core is disposed in a plane which is generally perpendicular to the plane in which similar cores have previously been disposed. As may Abe seen in Fig.
each of the cores 16, 16a, and 16h of the respective trip devices 17, 17a and 17b is disposed in a plane which extends longitudinally with respect to the elongated conductive studs 15, a and 15b.
the core 16 can be considered as being disposed in a plane A-A which extends longitudinally with respect to its associated stud 15.
This plane A-A in which the two legs of the core are disposed, is referred to hereinafter as the major plane of the core.
This major plane is also disposed generally perpendicular to a reference plane that contains the longitudinal axes of the adjacent conductive studs.
each stud serves as a shield which tends to conne the stray flux from its associated core Vand essentially prevents such flux from linking with an adjacent core.
This shielding effect together with the maximum-spacing eifect effectively reduces the flux linkage between adjacent poles to a value which is negligible.
my trip device may be calibrated to perform in a predetermined manner in response to predetermined current conditions in its stud, and this calibration will be maintained essentially independent of current conditions in the adjacent studs.
the current-responsive trip unit 17b is essentially independent of current conditions in studs 15 and 15a. Accordingly, irrespective of the current conditions in studs 15 and 15a, when the current in stud 15b exceeds a predetermined value the armature structure (not shown) of trip unit 17b will always respond in a predetermined manner to actuate the trip member 12b and trip breaker. Similarly, trip unit 17a, which is arranged to actuate trip member 12a, will respond only to current conditions in stud 15a, and trip unit 17 only to current conditions in stud 15. Thus, each of the trip units 17, 17a and 17b may be calibrated to respond to predetermined current conditions in its particular stud and this calibration will be unaffected 'by varying current conditions in adjacent studs.
this adjustment or precalibration may be performed with the assurance that the precalibration will be preserved in the completed circuit breaker.
the subassembly is then detached from the test fixture and, thereafter, may be mounted upon the stud part 18 at any desired time without any further calibration being required.
a plurality of closely-spaced, generally-parallel, elongated conductive studs having their longitudinally-extending central regions disposed in a predetermined reference plane, one of said elongated conductive studs comprising longitudinally-extending, transversely-spaced segments and a transversely-extending portion electrically interconnecting said segments, a magnetizable U-shaped core having a bight portion extending longitudinally of said one stud and a pair of ⁇ spaced legs straddling said transversely-extending portion whereby said core is arranged to be magnetized by current flowing through said one stud, said core having a major plane in which its two legs are disposed, said major plane being generally perpendicular to said reference plane, a magnetizable armature movable toward said core in response to current flowing through said one stud in excess of a predetermined value, and means responsive to said armature movement for actuating said
a pair of closelyspaced, generally-parallel, elongated conductive studs one of said studs having staggered transversely-extending longitudinally-spaced recesses, one of said recesses having an end wall facing toward the other of said studs and the other of said recesses having an end wall facing away from said other stud, a magnetizable U-.shaped core having a pair of spaced legs disposed within said recesses whereby said core is arranged to be magnetized by current flowing through said one stud, and a magnetizable yarmature movable toward said core in response to current flowing through said one stud in excess of a predetermined value, and means responsive to said armature movement for actuating said control element.
a pair of closelyspaced, generally-parallel, elongated conductive studs having their longitudinally-extending central regions disposed in a predetermined reference plane, one of said conductive studs having a portion extending transversely thereto, a magnetizable U-shaped core having a pair of spaced legs straddling said transversely-extending portion whereby said core is arranged to be magnetized by current flowing through said one stud, said core having a major plane in which its two legs are disposed, said major plane extending longitudinally of said one stud and being generally perpendicular to said reference plane, an armature movable toward said core in response to current flowing through said one stud in excess of a predetermined value, and means responsive to said armature movement for actuating said control element.
a plurality of closely-spaced, generally-parallel, elongated conductive studs having their longitudinaly-extending central regions disposed in a predetermined reference plane, one of said conductive studs having a portion extending transversely thereto, a magnetizable U-shaped core having a bight portion extending longitudinally of said one stud and a pair of spaced legs straddling said transversely extending portion whereby said core is arranged to be magnetized by current flowing through said one stud, said bight portion and said two legs being disposed in a plane which extends generally perpendicular to said reference plane, a magnetizable armature movable toward said core in response to current flowing through said one .stud in excess of a predetermined value, and means responsive to said armature movement for actuating said trip element.
a circuit breaker trippable to interrupt current owing in a circuit extending through said breaker, said circuit including a plurality of closely-spaced, generallyparallel, elongated conductive studs having their longitudinally extending central regions disposed in a predetermined reference plane, one of said elongated studs comprising longitudinally-extending, transversely-spo-ced segments and a transversely-extending portion electrically interconnecting said segments, a magnetizable U-shaped core having a pair of spaced legs straddling said transversely-extending portion whereby said core is arranged to be magnetized by current flowing through said one stud, .said core having a major plane in which said two legs are disposed, said major plane extending longitudinally of said one stud and generally perpendicular to said reference plane, a magnetizable armature movable toward said core in response to current flowing through said one stud in excess of a predetermined value, and means responsive to said armature movement for tripping said breaker.
a control arrangement comprising a pair of closely-spaced, generally-parallel elongated conductive studs, one of said studs including longitudinally-extending, transversely-spaced segments and a transversely-extending portion eiectrically interconnecting said segments, one of said segments being located adjacent the other of said studs and the other of said segments being located at a greater distance from said other stud, a magnetizable U-shaped core having a pair ot' spaced legs straddling said transversely-extending portion whereby said core is arranged to be magnetized by current owing through said one stud, said core having a major plane in which its two legs are disposed, said major plane extending longitudinally of said one stud, and a magnetizable armature movable toward said one core in response to current flowing through said one stud in excess of a predetermined value.
a control arrangement comprising a plurality of closely-spaced, generally-parallel, elongated conductive studs, one of said studs having staggered, transverselyextending, longitudinally-spaced recesses, one of said recesses having an end wall facing toward the other of said studs and the other of said recesses having an end wall facing away from said other stud, a magnetizable U-shaped core having a pair of spaced legs disposed within said recesses whereby said core is arranged to be magnetized by current flowing through said one stud, and a magnetizable armature movable toward said core in response to current flowing through said one stud in excess of a predetermined value.
a current-responsive assembly including a pair of closely-spaced, generally-parallel elongated conductive studs having their longitudinally-extending central regions disposed in a predetermined reference plane, one of said studs comprising two portions, one of said stud portions comprising a longitudinally-extending segment and a transversely-extending segment joined thereto, the other of said stud portions comprising a longitudinally-extending segment, means for detachably securing said transversely-extending segment to the longitudinally-extending segment of said other portion, a magnetizable U- shaped core having a bight portion extending longitudinally of said stud and a pair of spaced legs straddling said transversely-extending segment whereby said core is arranged to be m'agnetized by current flowing through said one stud, said core having a major plane in which its two legs are disposed, said major plane being generally perpendicular to said reference plane, and an armature movable toward said core in response to current flow through said one stud in excess of
a plurality of closely-spaced elongated conductive studs each including longitudinally-extending, transversely-spaced segments and a transverselyextending portion electrically interconnecting said segments, the longitudinally-extending central regions of said uds being disposed in a predetermined reference plane
a phtrality ot magnetizable U-shaped cores each having a pair of spaced legs straddling one of said transverselyextending stud portions whereby each of said cores is arranged to be magnetized by current owing through the associated stud about which it is mounted
each of said cores having a major plane in which its two legs are disposed, said major planes extending longitudinally with respect to said studs and disposed generally perpendicular to said reference plane and a plurality of magnetizable armatures each of which is mounted adjacent one of said cores and is movable toward said one core in response to current liowing through the associated stud in excess of a predetermined value.
a circuit breaker trippable to interrupt current llowing in a circuit extending through said breaker, said circuit including a plurality of closely-spaced elongated studs having their longitudinally-extending central regions disposed in a predetermined reference plane, each comprising longitudinally-extending, transversely-.spaced segments and a transversely-extending portion electrically interconnecting said segments, a magnetizable U-shaped core associated with each of said studs, each of said cores having a pair of spaced legs straddling said transverselyextending portion of said stud whereby said core is arranged to be magnetized by current flowing through said stud7 each of said cores having a major plane in which its two legs are disposed, said major planes extending longitudinally with respect to said studs and disposed generally perpendicular to said reference plane, a magnetizable armature associated with each of said cores and movable toward said core in response to current i'lowing through the associated stud in excess of a predetermined value
an electro-responsive control arrangement comprising a pair of elongated conductors mounted in closelyspaced, generally-parallel relationship, the longitudinally-extending central regions of said conductors being disposed in a predetermined reference plane, at least one of said conductors comprising spaced, longitudinally-extending segments and a transversely-extending portion electrically interconnecting said segments, a current-responsive device sensitive to current in said one conductor mounted about said transversely-extending portion with the major plane of said device extending longitudinally of said one conductor and in non-intersecting relationship with adjacent portions of the other of said conductors, said major plane being generally perpendicular to said reference plane.

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Breakers (AREA)

US432078A 1954-05-25 1954-05-25 Current responsive control device Expired - Lifetime US2829217A (en)

Priority Applications (3)

Application Number	Priority Date	Filing Date	Title
US432078A US2829217A (en)	1954-05-25	1954-05-25	Current responsive control device
CH336486D CH336486A (de)	1954-05-25	1955-05-23	Elektromagnetische Auslösevorrichtung
GB14833/55A GB768937A (en)	1954-05-25	1955-05-23	Improvements in and relating to electromagnetic control devices

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
US432078A US2829217A (en)	1954-05-25	1954-05-25	Current responsive control device

Publications (1)

Publication Number	Publication Date
US2829217A true US2829217A (en)	1958-04-01

Family

ID=23714670

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US432078A Expired - Lifetime US2829217A (en)	1954-05-25	1954-05-25	Current responsive control device

Country Status (3)

Country	Link
US (1)	US2829217A (de)
CH (1)	CH336486A (de)
GB (1)	GB768937A (de)

Citations (6)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
GB252697A (de) *	1925-05-28	1926-11-04	The British Thomson-Houston Company Limited
CH142860A (fr) *	1928-05-10	1930-10-15	Delle Atel Const Electr	Dispositif de déclenchement à relais.
US2000442A (en) *	1934-05-15	1935-05-07	Ite Circuit Breaker Ltd	Electric circuit interrupter
US2027221A (en) *	1934-07-19	1936-01-07	Westinghouse Electric & Mfg Co	Direct trip device
US2043306A (en) *	1932-10-29	1936-06-09	Westinghouse Electric & Mfg Co	Circuit interrupter
US2144501A (en) *	1935-01-19	1939-01-17	Westinghouse Electric & Mfg Co	Circuit breaker

1954
- 1954-05-25 US US432078A patent/US2829217A/en not_active Expired - Lifetime
1955
- 1955-05-23 GB GB14833/55A patent/GB768937A/en not_active Expired
- 1955-05-23 CH CH336486D patent/CH336486A/de unknown

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
GB252697A (de) *	1925-05-28	1926-11-04	The British Thomson-Houston Company Limited
CH142860A (fr) *	1928-05-10	1930-10-15	Delle Atel Const Electr	Dispositif de déclenchement à relais.
US2043306A (en) *	1932-10-29	1936-06-09	Westinghouse Electric & Mfg Co	Circuit interrupter
US2000442A (en) *	1934-05-15	1935-05-07	Ite Circuit Breaker Ltd	Electric circuit interrupter
US2027221A (en) *	1934-07-19	1936-01-07	Westinghouse Electric & Mfg Co	Direct trip device
US2144501A (en) *	1935-01-19	1939-01-17	Westinghouse Electric & Mfg Co	Circuit breaker

Also Published As

Publication number	Publication date
CH336486A (de)	1959-02-28
GB768937A (en)	1957-02-20

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US2829217A (en)	1958-04-01	Current responsive control device
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US2508178A (en)	1950-05-16	Circuit interrupter
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US2486300A (en)	1949-10-25	Electromagnetic trip circuit breaker
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US2178083A (en)	1939-10-31	Circuit controlling device
US2586326A (en)	1952-02-19	Circuit interrupter trip device
US2840663A (en)	1958-06-24	Circuit breaker
US3622923A (en)	1971-11-23	Electromagnetic device for circuit breaker trip assembly unit