US3247338A - Actuating system for simultaneously engaging or disengaging the contacts of multiple circuit breakers - Google Patents

Actuating system for simultaneously engaging or disengaging the contacts of multiple circuit breakers Download PDF

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Publication number
US3247338A
US3247338A US281478A US28147863A US3247338A US 3247338 A US3247338 A US 3247338A US 281478 A US281478 A US 281478A US 28147863 A US28147863 A US 28147863A US 3247338 A US3247338 A US 3247338A
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piston
contact members
movable contact
circuit
cylinder
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US281478A
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English (en)
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Gratzmuller Jean Louis
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H33/00High-tension or heavy-current switches with arc-extinguishing or arc-preventing means
    • H01H33/02Details
    • H01H33/04Means for extinguishing or preventing arc between current-carrying parts
    • H01H33/14Multiple main contacts for the purpose of dividing the current through, or potential drop along, the arc
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H3/00Mechanisms for operating contacts
    • H01H3/32Driving mechanisms, i.e. for transmitting driving force to the contacts
    • H01H3/46Driving mechanisms, i.e. for transmitting driving force to the contacts using rod or lever linkage, e.g. toggle
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H33/00High-tension or heavy-current switches with arc-extinguishing or arc-preventing means
    • H01H33/02Details
    • H01H33/28Power arrangements internal to the switch for operating the driving mechanism
    • H01H33/30Power arrangements internal to the switch for operating the driving mechanism using fluid actuator
    • H01H33/34Power arrangements internal to the switch for operating the driving mechanism using fluid actuator hydraulic
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H33/00High-tension or heavy-current switches with arc-extinguishing or arc-preventing means
    • H01H33/008Pedestal mounted switch gear combinations

Definitions

  • ⁇ lt is manifest that, in order to ensure that s-uch a system is reliable and safe, opening and closing of contacts m-ust be effected simultaneously on all chambers to prevent one of the chambers from being subjected to the total voltage.
  • An object of the present invention is to ensure such simultaneous action not only in normal operating conditions, but also in cases of damage occurring to equipment so that there is a complete guarantee of safe Working in all circumstances.
  • circuit-breaking chambers be mounted at a very great height with a View to insulation from the ground. This involves certain d-iiculties, for example in regard to the construction of insulating pillars and to the control of -moving contacts situated at some considerable distance from the control point located at the earth potential.
  • the present invention relates in particular to circuitbreakers of the 4type described in the second of the above patents, that is to say to the case Where the equipment is provided with a plurality of circuit-breaking chambers. It is sumcient to recall that, when employed for high tension working, these circuit-breakers are provided With a ⁇ connecting insulator rod inserted between a drive member (hydraulic cylinder) lat earth potential and the moving gear under tension.
  • the hydraulic cylinder is for the purpose of closing the circuit-breaker and maintaining it closed against resilient means which are always available and are capable of producing disengagement or opening of the circuit-breaker, with the resilient means being located in the portion under tension. Consequently, the connecting rod or rods always operate under tractive stress.
  • circuit-breaking chambers of several circuit-breakers of this type may be coupled in electrical series, While all cylinders may be supplied or exhausted simultaneously (for example, by means of hydraulic connections in parallel) in order to produce substantial synchronization of the displacements of all moving contacts in the course of engagement or disengagement.
  • All cylinders may be supplied or exhausted simultaneously (for example, by means of hydraulic connections in parallel) in order to produce substantial synchronization of the displacements of all moving contacts in the course of engagement or disengagement.
  • the chamber or chambers would thus be subjected to the total voltage, while the remaining chambers would remain in the closed or engaged position.
  • the object of the present invention is to obviate this disadvantage, whereby, in the case of damage occurring to one of the connecting systems, all circuit-breaking chambers would Ibe simultaneously disengaged.
  • each of said hydraulic cylinders is designed so that its piston is capable of moving beyond its dead-center position. That is to say beyondy the position in which the moving Contact or contacts which it actuates by way of an insulator rod, are engaged or closed, with each hydraulic cylinder comprising in addition means for producing automatically the simultaneous evacuation of all cylinders if their pistons proceed .beyond the normal dead center position mentioned above.
  • shock-absorbing devices are provided in the part under tension, as in the case of the second of the patents mentioned above, and assist in delaying disengagement in the case of a sudden fracture of a connecting rod.
  • the piston likewise proceeds beyond its normal dead-center and produces the same general evacuation of cylinders including the cylinder in question, that is to say, simultaneous disengagement of all chambers.
  • various means may be employed which respond to the position of the pist-on of a hydraulic cylinder and are designed to produce simuitaneous evacuation or" all cylinders.
  • This evacuation of tluid may be controlled, such as for exam- Iple electrically by contact-makers actuated by the piston, or else mechanically by valves opened by the piston or by -a member integral with the piston when it exceeds the normal dead-center position.
  • all hydraulic cylinders are interconnected in hydraulic communication by one or more lines of large cross-section, with exhaust ports being provided in each hydraulic cylinder which are in communication with a zone of low pressure and are uncovered by the piston when it passes beyond normal dead-center.
  • the cross-section of the lines is so calculated that the rate of exhaustion exceeds the rate of supply at the moment of pressure-oil from the power source (for example, an oil-and-air accumulator) to the cylinders.
  • the power source for example, an oil-and-air accumulator
  • each hydraulic cylinder may control one or more than one chamber by way of an insulator rod.
  • the provision of a plurality of chambers is common for very high tensions where one may be required to arrange possibly 6 to l0 circuit-breaking chambers in series. In this case, it is advantageous to group the chambers in pairs over 3 to 5 identical insulator pillars, each being provided with a control cylinder and insulator rod.
  • each of the moving contacts possesses its own transmission mechanism with reverse-motion, whereas the resilient release means, together with the shock-absorbing means may be allotted to each chamber, or, on the other hand, be common to all chambers.
  • FIG. 1 is a diagrammatic view of a circuit-breaker in accordance with the invention, comprising two circuitbreaking chambers, each mounted on an insulator pillar;
  • FIG. 2 is a view, partly in section, of a further ernbodiment in which each insulator pillar supports two circuit-breaking chambers controlled by one and the same insulator rod;
  • FIG. 3 is a fragmentary view partly in section and partly in cross section of a modied form in which each insulator pillar likewise supports two circuit-breaking chambers;
  • FIG. 4 is a view taken along the line IV--lV of FIG. 3;
  • FIG. 5 is a fragmentary view partly in section andV I partly in elevation of a circuit-breaker with two circuitil breaking chambers, in which motion is transmitted from the insulator rod to the moving contacts by means of a mechanism of cranks and levers.
  • the circuit-breaker shown diagrammatically in FIG. l is provided with two circuit-breaking chambers in series and comprises two identical units composed of a moving Contact 1 held permanently in the oit-position by a spring 2 located in the part under tension and brought into contact by a hydraulic cylinder 3 situated at the earth potential at the base of an insulator pillar 4 lled with o-il. rthe connection between the cylinder and the moving contact is provided by a transmission and reversing mechanism 6 in the form of a rack-and-pinion arrangement for example.
  • the line in which the current is to be cut or restored is represented by lead-in and lead-out conductors 7, 7' and a linking conductor 3.
  • the cylinders 3, 3 are interconnectedin parallel hydraulically by a line 9 to which is connected a line lll from a source ofizid under pressure (not illustrated; for example a hydraulic power unit comprising an oil-and-air accumulator).
  • the line llt) provides the pressure-oil to feed the hydraulic cylinders which cause the two moving contacts ll, 1' to engage simultaneously and subsequently maintain these contacts in the on-position by hydraulic pressure and without any mechanical locking means.
  • the length of the ⁇ cylinders 3, 3' is so calculatedV that pistons li, l1 at their normal bottom-dead-center position, do not meet bases l2, l2 which are simple removable covers.
  • any one connecting element lying between a moving Contact and its cylinder happens to break, for example the insulator rod 5, the moving contact i is urged towards the olfposition by pressure of its spring 2, while at the same time the piston 11, now no longer retained by the rod 5, is urged downwards towards the ⁇ base of the cylinder yby the oil pressure.
  • the cover i2 is pushed open, which produces immediate exhausting of the cylinder 3 towards the line 9 and cylinder 3 whose cover has been removed.
  • the moving contact l is thus also released under the pressure of its spring 2.
  • the line 10 which remains at all times connected to the pressure-huid source, is provided with a calibrated jet it', so that the rate of exhaustion of the line 9 is greater than the rate or" feed from the line itt.
  • the two moving contacts l, 1 are released simultaneously which prevents one of the circuit-breaking chambers being subjected, even temporarily, to the total voltage which it is not designed to support.
  • the moving mechanism of Ithe circuit-breaker possesses greater inertia than the piston 3 and is provided, in the part under tension, with shock-absorbing and speed control means whereby the exhaust signal occasinned by the complete displacement of the piston 1l is transmitted before the moving Contact l has been able to leave the fixed upper contact 13. Consequently, the effective circuit break occurs in all chambers simultaneously. It is also possible to provide in the vicinity of the cylinders 3, 3 quick-acting exhaust valves ld, 14' of a known type for providing direct evacuation of the with racks and pinions 19, i9 and 2i), 2d.
  • circuit-breaker comprising any number ot insulator pillors and cylinders, with each of said pillars supporting one or more circuit-breaking chambers,
  • evacuation ⁇ may be effected ⁇ by exhaust ports provided in the cylinders. Those ports are uncovered by the pistons when the latter pass -beyond their dead-center position, or else suiiicient travel of the pistons within the cylinders is provided so that all undamaged cylinders are drained into the cylinder whose connecting mechanism is tractured.
  • safety exhaustion may be controlled (for example through valves or electro-valves) by an element integral with the piston instead of by the piston per se, whereby the exhaust lines may be independent of each other, with the speed of the circuit-closing being controlled -by means of jets disposed over the supply circuit for the cylinders.
  • each of the insulator pillars carries several circuit-breaking chambers
  • the embodiment illustrated in FIG. 2 may be employed and in which one and the same insulator rod 5 actuates a plurality of moving contacts 15, i5.
  • a connecting mechanism with a rocking lever In and cranks i7, I7 links the extremity of the insulator rod 5 to racks I3, IS engaging the transmission mechanisms
  • the power for circuit-closing is distributed equally between the ltwo circuit-breaking chambers.
  • Each of the chambers may have its own individual release elements namely ⁇ springs 2i, 2 and shock-absorbing means Z2, 2.2 accommodated in an oil-filled chamber 23 located beneath the chambers.
  • FIGS. 3 and 4 A further embodiment of a connecting mechanism between an insulator rod 5 and two circuit-breaking chambers mounted on one single insulator pillar 4 is shown diagramrnatically in FIGS. 3 and 4.
  • resilient release means spring 2d and shock-absorbing and speed control means oil dash-pot 2S are common to the two chambers that is to say, they iniiuence the actual connecting insulator rod between its upper part and the transri ⁇ his mechanism comprises a double-sided rack 26 which meshes with two identical pinions 27, 27 whose shafts 28, 28 each carry a toothed wheel 29, 29 respectively. These two wheels engage racks 3d, 30' secured to the moving contacts I5,
  • the toothed wheels 29, Z9' are arranged symmetrically about the axis of the rack 26 (FIG. 4) so that the racks 30, Bti lie in two ditlerent vertical planes.
  • This arrangement oiiers the advantage that in addition to symmetry, it enables the mechanism housing (not illustrated) to be divided into three compartments, each sealed from the other, with tight joints 31, 3l being provided at the bearings of the shafts 23, '23.
  • Means of :this type for separating the oil capacities of the circuit-breaking chambers from the transmission mechanism have been described in the first Certificate of Addition to French Patent No. 1,293,609 led on March 21, 1962, under the No. 891,729'.
  • FIG. 5 is a view o'r ⁇ a modied form of construction combining the equal stress transmission system shown in FlG. 2 and the equal travel system shown in FIG. 3.
  • the rocking lever 16 is replaced by intermediate piece 32 of triangular construction which is pivotally connected by one of its apices to the control rod 5', with its other two apices being connected to the small cranks 17, I7 identical to those employed in FIG. 2.
  • this transmission mechanism motion is normally transmitted by giving equai travel to the two moving contacts, but the intermediate piece 32 is capable however of rocking slightly during displacement.
  • the transmission mechanism employed between the extremity of the connecting insulator rod (or piece integral with and moving with said extremity) and the moving contacts is in 4the form of a crank and lever mechanism producing amplification of movements and reverse-motion.
  • This mechanism is accommodated in an oil-lled casing which also encloses the shock-absorbing system and is mounted on the upper portion of the insulator pillar supporting the circuit-breaker and carries the circuitbreaking chambers. It is also possible to employ a dry casing and in which case the hydraulic shock-absorber is provided with its own oil supply.
  • a hydraulic cylinder (not illustrated) which exerts a pull on a hollow connecting insulator rod Ille, preferably of plastic reinforced with fiber-glass.
  • the upper extremity of the rod lit-i is connected by means of a Steeve 196 to a shock-absorber rod 168 carrying a piston 1li@ slidably mounted within a shock-absorber cylinder 112.
  • This cylinder is connccted to top cover 114 of the insulator pillar N2 and is immersed in the oil contained in a casing lie also mounted on the upper part of the pillar 162.
  • Packing material IIS ensures duid-tightness during motion of the rod 163 between the casing 116 and the interior of the pillar 1&2 which is filled with insulating oil.
  • Two circuit-breaking chambers 120, 126' arranged in a general incline, are mounted on the casing 1Std.
  • a moving contact 22 r may be provided, which is slidable within a lead-in contact 124 and may engage at top-dead-center in a iixed contact (not illustrated) but is located at the upper part of the chamber (in the ligure the circuitbreaker is shown in ⁇ the reiease or off position).
  • the transmission mechanism between the working insulator rod IM and each of the moving contacts comprises a lever 12e provided with arms of unequal length and which is pivotally mounted on a ixed axis 128 carried aaaasss by the casing 116 and comprises two small connecting cranks 130 and 132.
  • the crank 130 is pivotally connected by one of its extremities to extremity 1310i the longer arm of the lever 126, and by its other extremity to a sliding cross-piece 13- to which the moving contact 122 is secured and whose movement is guided by two guide rods 136, 136 which may also assist in maintaining the circuitbreaking chamber 120 in position.
  • the crank 132 is articulated by one extremity to extremity 1330i?
  • the connecting piece 140 serves as a stop for the completion of the release stroke and also as a connection tothe spring release means which will be described hereinafter.
  • the ratio of the arms of the lever 126 is so calculated that, for a short displacement of the group comprising the cylinder piston, insulator rod 104, shock-absorber rod 108 and conncctf ing piece 140 (that is to say, for a small consumption of oil in the cylinder), the moving contacts perform their complete stroke.
  • a transmission mechanism is illustrated which offers a multiplication ratio of approximately 1A with reverse-motion.
  • the release spring is located in the part liable to be under tension, as has been described in French Patent No. 1,293,609 and also in the first Certiicate of Addition No. 891,729.
  • the release spring 143 is located above the casing 116 and between the circuit-breaking chambers 120, 120. It is securely ixed at its lower extremity to a ibase 144 mounted on the casing and cooperates at its upper extremity with a movable thrust washer 1de secured to a rod 14S integral with the connecting piece 140.
  • Engagement of the contacts may be automatically maintained by the oil-pressure which remains at the level in the cylinder, the release or disengaging action being obtained by exhausting the cylinder.
  • the release spring 143 brings the thrust washer 146 once more upwards, thus involving the whole group 148-140- 108, whereby the moving contacts are withdrawn by the pivoting of the levers 126.
  • the two symmetrical cranks 132 may be connected alternatively by a common pivot to the connecting piece 140 instead of to two separate pivots 152, 154.
  • the release spring and shock-absorber may be located at different points from those illustrated, and it is possible in particular to mount the shock-absorber within the spring, with said unit being located inside or outside the casing 116.
  • circuit-breaking chambers are designed for example for 75,000 volts, a 450,000 volt circuitbreaker may be employed in accordancewith the invenrod in accordance with one of the embodiments of F lGS.
  • circuit-breakers It is known that the response of circuit-breakers is not only dihoult on a short-circuit, but also in the case of an insulating fault occurring on the supply line not far from the circuit-breaker (a case referred to generally as a Telec fault) and also in the case of the circuitbreaking of no-load lines where the capacity of conductors plays an important part. It would appear then that, as the case may be, the circuit-breaker may -be presented with phenomena which are purely of ohmic, or self-inductances, or even capacitive type, and that it must be capable of ensuring the break even in the case of very considerable dephasing in one or other direction of voltage in relation to intensity.
  • each circuit-breaking chamber which resistance is arranged in parallel with the upper and lower xed contacts (the resistance rnust be cut in turn after opening of the circuit-breaker) or preferably, the insertion of a resistance betweenV the upper contact and an additional, intermediate rixed contact.
  • the break is thus effected in two stages, with the rst stage consisting of inserting said resistance in the circuit, and the second stage of interrupting the current passing through the resistance.
  • the rst stage consisting of inserting said resistance in the circuit
  • the second stage of interrupting the current passing through the resistance.
  • each chamber is of course subjected to the phenomena which has just been described, but, in addition, the distribution of tension amongst the vario-us chambers after the break may tend to be irregular, especially if no auxiliary distributor equipment (resistances or condensers) is provided. lt is therefore also advantageous in this case to provide additional displacement after circuit-breaking on the moving contacts.
  • the increase of displacement of the moving contacts may be effected without difliculty on circuit-breakers according to the invention by virtue of the pull-system with reduction and reverse-motion, especially with the use of racks and pinions. Indeed, it is suiioient to increase the travel of the drive member, that is to say, of the hydraulic cylinder associated with the connecting insulator rod controlling the moving contact or contacts, and Yto extend by several teeth the racks connected to the insulator rod and moving contacts.
  • Such an arrangement enables the path of the moving contacts to be extended without any great increase in the inertia of the parts or of the volume of the casings and is described in the French Certificate of Addition No. 891,729.
  • An actuating system for an electric circuit breaker of the type including at least two stationary contact members, at least two contact members movable each relative to one of the stationary contact members between closed and opened positions, and elastic means arranged to urge constantly each movable contact member towards the opened position
  • said actuating system including a plurality of single acting Huid pressure actuators, there being one actuator for each two movable contact members, each actuator including a cylinder, a piston slidable in the cylinder through a limited stroke extending between a lirst position of the piston corresponding to the closed position of the correlated movable contact members and a second position of the piston corresponding to the opened position of the correlated movable contact members, means including a supply line interconnecting the interior of the cylinders behind the pistons for supplying pressure uid to the interior of all of the cylinders, transmission means operably relating each movable contact member with the corresponding piston for moving the movable contact members to the closed position against the action of the elastic means as the piston
  • An actuating system for an electric circuit breaker of the type including at least two stationary contact members, at least two contact members movable each relative to one of the stationary contact members between closed and opened positions, and elastic means arranged to urge constantly each movable contact member towards the opened position, said actuating system including a plurality of single act-ing fluid pressure actuators, there being one actuator for each two movable contact members, each actuator including a cylinder, a piston slidable in the cylinder through a limited stroke extending between a first position of the piston corresponding to the closed position of the correlated movable contact members and a second position of the piston corresponding to the opened position of the correlated movable Contact members, means including a supply line interconnecting the interior of the cylinders behind the pistons for supplying pressure fluid to the interior of all of the cylinders, transmission means operably relating each movable contact member with the corresponding piston for moving the movable contact members to the closed position against the action of the elastic means as the pistons are moved to the first position under the
  • An actuating system for an electric circuit breaker of the type including at least two stationary contact mem. bers, at least two contact members movable each relative to one of the stationary contact members between closed and opened positions, and elastic means arranged to urge constantly each movable contact member towards the opened position, said actuating system including a plurality of single acting uid pressure actuators, there being one actuator for each two movable contact members, each actuator including a cylinder, a piston slidable in the cylinder through a limited stroke extending between a first position of the piston corresponding to the closed position of the correlated movable contact members and a second position of the piston corresponding to the opened position of the correlated movable contact members, means including a supply line interconnecting the interior of the cylinders behind the pistons for supplying pressure iiuid to the interior of all of the cylinders, transmission means operably relating each movable contact member with the corresponding piston for moving the movable contact members to the closed position against the action of the elastic means as
  • the actuating system as claimed in claim 3 including compression spring means located above the crank means connected to the means movable with the insulator rod.
  • An actuating system for an electric circuit breaker of the type including at least two stationary contact members, a corresponding number of contact members movable each relative to one of said stationary contact members between closed and opened positions, and elastic means arranged to urge constantly each movable contact member towards the opened position, said actuating system comprising a plurality of single acting iiuid pressure actuators, there being one actuator for each movable contact member, each actuator including a cylinder, a piston slidable in the cylinder through a limited stroke extending between a iirst position of the piston corresponding to the closed position of the correlated movable contact member and a second position of the piston corresponding to the opened position of the correlated movable contact member, means including a supply line interconnecting the interior of the cylinders behind the pistons for supplying pressure uid to the interior of all of the cylinders, transmission means operably relating each movable contact member with the corresponding piston for moving the movable contact members to the closed position against the action of the
  • said transmission means comprise a tubular pillar supported by the cylinder of each fluid pressure actuator and having a top end, a member of insulating material extending through each tubular pillar, said elastic means being defined by compression springs resting on the top end of the pillars, a spring compressing washer, and each member of insulating material interconnecting the corresponding piston and spring compressing washer whereby said member -is subjected solely to tensile stress.
  • each cylinder is provided with exhaust port means so located as tobe exposed by its piston during displacement of the piston for producing evacuation of the cylinders .in response to complementary displacement of one of the pistons.
  • each cylinder is open at the end in front of the piston f and a removable cover closes the open end so that when the piston in the cylinder moves past the rst position away from the second position, the cover is ejected thereby causing instant evacuation of all cylinders.

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  • Driving Mechanisms And Operating Circuits Of Arc-Extinguishing High-Tension Switches (AREA)
  • Shearing Machines (AREA)
  • Fluid-Damping Devices (AREA)
  • Mechanisms For Operating Contacts (AREA)
US281478A 1962-05-25 1963-05-20 Actuating system for simultaneously engaging or disengaging the contacts of multiple circuit breakers Expired - Lifetime US3247338A (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
FR898712A FR1334353A (fr) 1962-05-25 1962-05-25 Disjoncteur à chambres de coupure multiples
FR912043A FR82440E (fr) 1962-05-25 1962-10-12 Disjoncteur à chambres de coupure multiples

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Publication Number Publication Date
US3247338A true US3247338A (en) 1966-04-19

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ID=26195862

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Application Number Title Priority Date Filing Date
US281478A Expired - Lifetime US3247338A (en) 1962-05-25 1963-05-20 Actuating system for simultaneously engaging or disengaging the contacts of multiple circuit breakers

Country Status (10)

Country Link
US (1) US3247338A (fr)
AT (1) AT245668B (fr)
BE (1) BE632763A (fr)
CH (1) CH398746A (fr)
DE (1) DE1225268B (fr)
ES (1) ES288270A1 (fr)
FR (2) FR1334353A (fr)
GB (1) GB1016194A (fr)
NL (1) NL293165A (fr)
SE (1) SE308928B (fr)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3562465A (en) * 1968-10-21 1971-02-09 Ite Circuit Breaker Ltd Telescopic switch for isolated phase bus
US3657495A (en) * 1969-05-09 1972-04-18 Merlin Gerin High-voltage disconnecting switch with sliding contact
US3855433A (en) * 1973-12-10 1974-12-17 S & C Electric Co High voltage switch arrangement
US6946609B1 (en) * 2004-11-08 2005-09-20 General Electric Company Alignment mechanism for a telescopic switch

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3566054A (en) * 1968-02-13 1971-02-23 Gen Electric High voltage circuit breaker comprising a mechanical linkage interconnecting its components for synchronized operation thereof
FR2496334A1 (fr) * 1980-12-16 1982-06-18 Merlin Gerin Interrupteur monopression a mecanisme bielle-manivelle loge a l'interieur de l'enveloppe etanche
FR2514555A1 (fr) * 1981-10-12 1983-04-15 Alsthom Atlantique Disjoncteur a gaz sous pression comprenant pour chaque phase deux chambres de coupure disposees en v

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
None *

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3562465A (en) * 1968-10-21 1971-02-09 Ite Circuit Breaker Ltd Telescopic switch for isolated phase bus
US3657495A (en) * 1969-05-09 1972-04-18 Merlin Gerin High-voltage disconnecting switch with sliding contact
US3855433A (en) * 1973-12-10 1974-12-17 S & C Electric Co High voltage switch arrangement
US6946609B1 (en) * 2004-11-08 2005-09-20 General Electric Company Alignment mechanism for a telescopic switch

Also Published As

Publication number Publication date
BE632763A (fr)
DE1225268B (de) 1966-09-22
SE308928B (fr) 1969-03-03
GB1016194A (en) 1966-01-05
FR82440E (fr) 1964-02-07
NL293165A (fr)
FR1334353A (fr) 1963-08-09
AT245668B (de) 1966-03-10
CH398746A (fr) 1966-03-15
ES288270A1 (es) 1963-07-16

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