GB1599038A

GB1599038A - Circuit breaker accessory

Info

Publication number: GB1599038A
Application number: GB2430677A
Authority: GB
Original assignee: Dorman Smith Switchgear Ltd
Current assignee: Dorman Smith Switchgear Ltd
Priority date: 1978-05-12
Filing date: 1978-05-12
Publication date: 1981-09-30

Description

(54) CIRCUIT BREAKER ASSEMBLY (71) We, DORMAN SMITH SWITCHGEAR LIMITED, a British Company, of Atherton Works, Blackpool Road, Preston, Lancashire, do hereby declare the invention for which we pray that a patent may be granted to us, and the method by which it is to be performed, to be particularly described in and by the following state ment : - This invention concerns accessories for circuit breakers, and has for its object to provide a novel construction of actuating accessory which may be constructed so as to provide for circuit-breaker tripping operation upon command, or may be constructed for breaker tripping operation upon diminution or shutting-off of the current through the circuit breakers, the accessory being composed of equivalent components in each case but with only a minimum of components differing only in their physical form, so that in practical manufacture of the accessory, only a minimum of parts need to be produced to enable the acces sory to be manufactured in both of its practical forms.

With this object in view the present invention provides an actuating accessory, for use with a moulded-case circuit breaker or breakers, said accessory being in the form of a shunt trip device, as hereinafter defined, or an under-voltage release device and comprising a casing which is adapted to be secured to the circuit breakers with which it is to be used and a rotatable intertrip component adapted to be coupled with a corresponding rotatable element of the circuit breaker(s) so that, when so coupled, rotation of the intertrip component of the accessory from a rest position causes corresponding rotation of the rotatable element of the circuit breaker(s) to cause tripping thereof, the actuating accessory comprising, within its casing, an intertrip lever connected to the intertrip component, an actu awing lever cooperating with the intertrip lever and adapted upon swinging movement to swing the intertrip lever and thereby cause circuit breaker tripping means for biassing the actuating lever in one direction, and a solenoid having an armature or plunger which, when the solenoid is energised, acts on the actuating lever to move it against the biassing force.

Preferably the means for biassing the actuating lever comprises a spring.

It will readily be understood that such an arrangement can be set up to operate in two ways. In a first way, the actuating lever fs at rest when the solenoid is deenergised and is moved to cause tripping of the circuit breakers when the solenoid is energised and its armature displaced. This first form of the accessory will then serve as a shunt trip device adapted to cause circuit breaker tripping upon command, that is to say upon a control current being supplied to the solenoid. Such an accessory is, and hereinafter will be referred to as, a shunt trip device. In a second way, the actuating lever is held in its rest position, against the action of its spring, by the armature or plunger of the solenoid when the latter is energised, and the current for this can be derived from the circuit(s) being protected by the circuit breaker(s). Accordingly, with this second arrangement the accessory is an under voltage release, in that it will cause tripping of the circuit breaker(s) upon failure of the current supply to the circuit breakers or upon diminution of the voltage thereof.

The invention will be described further, by way of example, with reference to the accompanying drawings, in which: Fig. 1 is a side elevation illustrating a commercially-available moulded-case electrical circuit breaker; Fig. 2 is a side elevation illustrating a first embodiment of the actuating accessory of the invention, the accessory being designed for use in conjunction with the circuit breaker of Fig. 1, and being illustrated with its cover removed to reveal its internal construction, and with its components in the "tripped" positions; Fig. 3 is a plan view of the actuating accessory of Fig. 2; Fig. 4 is a side elevation illustrating a second embodiment of the actuating acces sory of the invention, this accessory also being designed for use in conjunction with the circuit breaker of Fig. 1 and also being illustrated with its cover removed to reveal its internal construction but being shown with its solenoid energised so that the accessory is in its non-tripped condition; and Fig. 5 is a plan view of the actuating accessory of Fig. 4.

Features of the embodiments illustrated in Figs. 2 to 5 are the subjects of our copending Patent Applications Nos. 24305/77 (Serial No. 1599037), 24307/77 (Serial No.

1599037) and 24308/77 (Serial No.

1599037).

Dealing firstly with Fig. 1, this illustrates a form of moulded case electrical circuit breaker already on the market. This circuit breaker comprises a moulded plastics casing 10 recessed at each end at 11 and 12 for respective terminals (not visible) for connecting the circuit breaker into a circuit intended to be protected against overload and short circuit by the circuit breaker. A tripping mechanism (not visible) within the casing 10 is operative, upon occurrence of sustained overload or short circuit conditions, to interrupt the continuity between the two terminals of the circuit breaker, for example by causing a movable contact carried by a movable contact arm, to move away from a fixed contact. This tripping mechanism includes a dolly 13 which is shown in its "off' position. In this, the movable contact is separated from the fixed contact, and the circuit through the circuit breaker is interrupted. Movement of the dolly 13 to its "on" position (which is not illustrated in the drawing) actuates the mechanism within the casing 10 to close the movable contact into engagement with the fixed contact.

The mechanism of the circuit breaker also includes a rotatable element, in the form of a rotatable member 14, accessible from outside the casing 10. The rotatable member 14 is formed with a diametricallydisposed slot 15 in each of its ends for reception of coupling slips (not shown) so that when two circuit breakers are disposed side-by-side in register with one another the rotatable members 14 thereof are coupled together in such a manner that rotational change of the orientation of the rotatable member 14, in one of the breakers, which occurs upon tripping of said breaker, results in corresponding rotational movement of the rotatable member 14 of the other breaker and causes that breaker to trip also. The same occurs for all breakers, however many may be coupled together.

Turning now to Figs. 2 and 3 the actuating accessory here illustrated is a shunt trip device. It will be appreciated that this accessory comprises a casing 16 which is separately formed with respect to, and corresponds in configuration to that of the casing 10 of the circuit breaker of Fig. 1, so that the accessory can be mounted sideby-side with the circuit breaker and secured together therewith, e.g. by bolts or rivets (not shown) through holes 17, 18, 19 and corresponding holes 20, 21, 22 in the circuit breaker. In practice, as many as four of the circuit breakers of Fig. 1 can be assembled together to form a multi-pole circuit breaker assembly, with their mechanisms coupled by way of their rotatable members 14, so that all of the circuit breakers will trip in unison. It will be seen from Fig. 2 that the actuating accessory has a corresponding intertrip component in the form of a rotatable intertrip member 23, with a slot 24 therein appropriately disposed for it to be coupled to the rotatable member(s) 14 of the circuit breaker(s). The intertrip member 23 is pivotally located by its ends in the casing 16 and its cover (which is removed in Fig. 2).

An actuating mechanism within the casing 16 is carried by a U-shaped mounting bracket 25 providing a web 25 along the opposite edge of which are flanges 27 and 28. The flange 27 has mounted thereon a coil 29 of a solenoid 30 having an armature or plunger 31, this coil 29 abutting by one end against the flange 27 (to which it is secured) and locating at its other end on a protrusion 32 within the casing 16. This protrusion 32 is formed integrally with an abutment wall 33 facing the respective end of the coil 29 so as to be spaced slightly away from said end of the coil 29. Thus, there is a possibility of adjusting the coil 29 to a small extent towards the abutment wall 33, by corresponding movement of the mounting bracket 26.

This adjusting movement is provided for by means of a bracket-load spring 34, disposed between the flange 28 of the bracket 25 and an adjacent abutment wall 35 of the casing 16 said spring 34 loading the bracket 25 towards the abutment wall, 33, in combination with an adjusting screw 36 which threadedly engages into a hole in the flange 27 of the bracket 25 and which locates by its head 37 within the protrusion 32. An adjusting hole 38 is provided in the abtument wall 33 to permit access to the head 37 of the screw 36 for adjusting purposes, and will be understood that the hole 38 is smaller than the head 37 so that the latter cannot enter the hole 38 and that the hole 38 is sealed up with an appropriate compound (not shown) after adjustment has been effected pursuant to assembly of the accessory in the factory.

A pivot pin 39 is fixed to the web 26 of the bracket 25 and this provides a first axis for one end of an actuating lever 40 to the other end of which is abutted by an extension 41 of the armature or plunger 31. This armature or plunger 31 is shown in Fig. 2 in its extended condition, corresponding to the coil 29 having been energised, and can return by shifting to the left (considered as in the drawing) from the position shown in Fig. 2. A resetting spring 43 is connected by one end to the flange 27 and by its other end to the actuating lever 40 to load the latter and the plunger 31 from the illustrated position and back into an initial rest position indicated at 31a.

Fixed to the intertrip member 23 is an intertrip lever 44 from which projects a peg 45 disposed so as to be engageable by the actuating lever 40.

The mode of operation of this actuating accessory will readily be understood from the foregoing description. The accessory is mounted side-by-side with, and is operatively coupled to, one or more circuit breakers as described, and the solenoid coil 29 is connected by way of appropriate lead 46, 47 and terminals 48 and leads (not shown) to means (such as a control device which senses one or more parameters in an industrial process) which will supply current to the coil 29 when tripping of the circuit breakers is required. Normally, the armature or plunger 31 is in the rest position 31a. Upon the coil 29 being energised the armature or plunger 31 is shifted to the right into the tripping position shown in Fig. 2) causing pivoting of the actuating lever 40 in a clockwise direction, thereby to cause corresponding pivoting of the intertrip lever 44 in an anticlockwise direction. This latter pivoting causes corresponding pivoting of the intertrip member 23 and consequential tripping of the circuit breakers.

Upon the coil 29 being de-energised, the accessory is reset by the force of the spring 43 acting upon the actuating lever 40 thus disengaging it from the pin 45 on the intertrip lever 44.

It will be understood that adjustment of the screw 36 serves to adjust the instant of tripping of the circuit breakers since this adjusts the bracket 26 and actuating lever 40 relative to the intertrip member 23.

Turning now to Figs. 4 and 5, these figures illustrate a second embodiment of the accessory of the invention, which is an under voltage release device. From comparison of the figures it will be clear that this accessory comprises a large number of components which are substantially identical with those already described with reference to Figs. 2 and 3. Accordingly, similar reference numerals have been allocated to these parts, which do not have to be described in detail again. In Fig. 4, the accessory is shown in its condition cor responding to the solenoid coil 29 being energised so that the accessory is in its non-tripped condition.

In this embodiment, the actuating lever 40 is pivotally mounted upon a respective pivot pin 50 which is differentialy positioned compared with the pivot pin 39 of Fig. 2, so as to form the actuating lever into a two-armed lever of which the larger arm is abutted by the extension 41 of the solenoid's armature or plunger 31 and the shorter arm is abutted by an actuating spring 51 carried by a guide rod 52 pivotally connected to said shorter arm and slidably located in a hole in the flange 27 of the bracket 26. Peg 53 secured to the intertrip level 44 for abutment by the shorter arm of the actuating lever is positioned closer to the extreme end of the lever 44 as compared with the peg 45 in Fig. 2.

With this embodiment, so long as the coil 29 of the solenoid is energised, the armature of plunger 31 is retained in the extended position illustrated, with the extension 41 abuting the longer arm of the actuating lever 40 and thereby holding the shorter arm thereof away from engagement with the peg 53. Accordingly, assuming the solenoid 30 to be connected so as to be energised by the same current supply as is supplied to the circuit breaker(s), the actuating accessory will remain in its illustrated non-tripping condition. Should, however, there be a failure of the power supply or a significant reduction in the voltage thereof, the solenoid 29 becomes correspondingly de-energised, and the armature or plunger 31 is able to move to the left towards the rest position indicated at 31a under the influence of the actuating spring 51 acting on the actuating lever 40. The latter engages, of course, with the peg 53, so that the intertrip lever 44 is pivoted on the same way as described with reference to the arrangement of Figs.

2 and 3 to cause tripping of the circuit breaker(s) to which the accessory is coupled.

The two described accessories, although operating under different circumstances, are constructed largely with identical components, it being necessary to modify only a minimum of the common components, and to employ a minimum of alternative components to achieve the two differentlyoperating arrangements.

Concerning the embodiment of Figs. 4 and 5 of the drawings, one problem is to ensure that the mechanical work output of the coil, having a short stroke and being continuously-rated, is adequate to store sufficient energy in the spring 51 to ensure an an adequate safety margin over the work required to trip the circuit breaker(s).

Comparable problems, in the past, have been overcome in the circuit breakers embodying undervoltage release devices by providing resilient mechanical reset means for the coil, driven by the operating dolly of the circuit breaker. Since, the holding force of a coil is very much greater than that which it can pull in against, a much stronger spring can t;e used to provide the necessary margin of trip energy. However, these mechanical reset means present pro blems which are avoided in the accessory of Figs. 4 and 5 which is designed to achieve resetting, purely electrically.

For a given coil of small size suitable for this application with a given maximum dissipation, it is possible to obtain more mechanical work output if it is energised by A.C. rather than D.C. Since the work output is proportional to the area under the force/distance curve, it is also im portant to ensure that the characteristic of the spring used to store this energy closely matches the coil's force/distance curve in shape. This cannot always be achieved by adjustment of the spring force and rate alone, so in the arrangement of Figs. 4 and 5 the geometry has been so arranged that the distance between the axis of the spring 51 and the pivot 50 alters appreciably due to the relatively large angle of movement of the actuating lever 40. Thus, when the armature or plunger 31 is withdrawn to its position indicated at 31a, the spring 51 is extended and producing low force and, in addition, its axis extends close to the pivot 50 thereby giving low torque and, in turn, low initial resistance to travel of the armature or plunger 31. Towards the end of the travel of the armature or plunger 31, when the available force of the coil 29 is approaching its maximum, the spring 51 is more compressed but, in addition, its axis is relatively much further from the pivot 50 so that the effect on the resistance which the coil 29 must overcome increases disproportionately.

By careful arrangement of these several parameters, it is possible to achieve a very close degree of matching between the characteristics of the coil 29 and the spring 51 thereby obtaining an arrangement which will reset efficiently against the action of the spring 51, and yet store sufficient energy to ensure reliable tripping action when the coil is de-energised.

The invention is not confined to the precise details of the illustrated examples, and variations may be made thereto.

WHAT WE CLAIM IS: - 1. An actuating accessory, for use with a moulded-case circnuit breaker or breakers, said accessory being In the form of a shunt trip device, as hereinbefore defined, or an under-voltage release device, and comprising a casing which is adapted to be secured to the circuit breaker(s) with which it is to be used and a rotatable intertrip component adapted to be coupled with a corresponding rotatable element of the circuit breaker(s) so that, when so coupled, rota tion of the intertrip component of the accessory from a rest position causes corresponding rotation of the rotatable element of the circuit breaker(s) to cause tripping thereof, the actuating accessory comprising, within its casing, an intetrtrip lever connected to the intertrip component, an actuating lever cooperating with the inter trip lever and adapted upon swinging movement to swing the intertrip lever and there by cause circuit breaker tripping, means for biassing the actuating lever in one direction, and a solenoid having an armature or plunger which, when the solenoid is energised, acts on the actuating lever to move it against the biassing force.

2. An acuating accessory as claimed in Claim 1 in which the actuating lever is mounted on a bracket.

3. An actuating accessory as claimed in Claim 2 in which the bracket is displace able relative to the intertrip lever.

4. An actuating accessory as claimed in Claim 2 or 3 in which one end of the actuating lever is pivotally mounted on the bracket, the arm of the actuating lever being operative, on pivoting, to swing the intertrip lever and cause circuit breaker tripping.

5. An actuating accessory as claimed in Claim 4, in which the biasing means comprises a spring attached at one end to the bracket and at its other end to end, remote from the pivotal mounting, of the actuating lever.

6. An actuating accessory as claimed in Claim 5 in which the armature or plunger of the solenoid, when the solenoid is energised, acts on said end of the actuating lever remote from the pivotal mounting to pivot the actuating lever against the force of the spring thereby swinging the intertrip lever to cause circuit breaker tripping, the accessory thus acting as a shunt trip device.

7. An actuating accessory as claimed in Claim 2 or 3 in which the actuating lever is a two armed lever pivotally mounted on the bracket.

8. An actuating accessory as claimed in Claim 7 in which the armature or plunger of the solenoid, when the solenoid is energised, acts on one arm of the actuating lever to hold the actuating lever against the biassing force of the biassing means, and when the solenoid is de-energised the biassing means acts to pivot the actuating lever such that the other arm of the actuating lever engages the intertrip lever to swing

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Claims

**WARNING** start of CLMS field may overlap end of DESC **.

work required to trip the circuit breaker(s).

Comparable problems, in the past, have been overcome in the circuit breakers embodying undervoltage release devices by providing resilient mechanical reset means for the coil, driven by the operating dolly of the circuit breaker. Since, the holding force of a coil is very much greater than that which it can pull in against, a much stronger spring can t;e used to provide the necessary margin of trip energy. However, these mechanical reset means present pro blems which are avoided in the accessory of Figs. 4 and 5 which is designed to achieve resetting, purely electrically.

For a given coil of small size suitable for this application with a given maximum dissipation, it is possible to obtain more mechanical work output if it is energised by A.C. rather than D.C. Since the work output is proportional to the area under the force/distance curve, it is also im portant to ensure that the characteristic of the spring used to store this energy closely matches the coil's force/distance curve in shape. This cannot always be achieved by adjustment of the spring force and rate alone, so in the arrangement of Figs. 4 and

5 the geometry has been so arranged that the distance between the axis of the spring

51 and the pivot 50 alters appreciably due to the relatively large angle of movement of the actuating lever 40. Thus, when the armature or plunger 31 is withdrawn to its position indicated at 31a, the spring 51 is extended and producing low force and, in addition, its axis extends close to the pivot 50 thereby giving low torque and, in turn, low initial resistance to travel of the armature or plunger 31. Towards the end of the travel of the armature or plunger 31, when the available force of the coil 29 is approaching its maximum, the spring 51 is more compressed but, in addition, its axis is relatively much further from the pivot 50 so that the effect on the resistance which the coil 29 must overcome increases disproportionately.

By careful arrangement of these several parameters, it is possible to achieve a very close degree of matching between the characteristics of the coil 29 and the spring 51 thereby obtaining an arrangement which will reset efficiently against the action of the spring 51, and yet store sufficient energy to ensure reliable tripping action when the coil is de-energised.

The invention is not confined to the precise details of the illustrated examples, and variations may be made thereto.

WHAT WE CLAIM IS: - 1. An actuating accessory, for use with a moulded-case circnuit breaker or breakers, said accessory being In the form of a shunt trip device, as hereinbefore defined, or an under-voltage release device, and comprising a casing which is adapted to be secured to the circuit breaker(s) with which it is to be used and a rotatable intertrip component adapted to be coupled with a corresponding rotatable element of the circuit breaker(s) so that, when so coupled, rota tion of the intertrip component of the accessory from a rest position causes corresponding rotation of the rotatable element of the circuit breaker(s) to cause tripping thereof, the actuating accessory comprising, within its casing, an intetrtrip lever connected to the intertrip component, an actuating lever cooperating with the inter trip lever and adapted upon swinging movement to swing the intertrip lever and there by cause circuit breaker tripping, means for biassing the actuating lever in one direction, and a solenoid having an armature or plunger which, when the solenoid is energised, acts on the actuating lever to move it against the biassing force.
2. An acuating accessory as claimed in Claim 1 in which the actuating lever is mounted on a bracket.
3. An actuating accessory as claimed in Claim 2 in which the bracket is displace able relative to the intertrip lever.
4. An actuating accessory as claimed in Claim 2 or 3 in which one end of the actuating lever is pivotally mounted on the bracket, the arm of the actuating lever being operative, on pivoting, to swing the intertrip lever and cause circuit breaker tripping.
5. An actuating accessory as claimed in Claim 4, in which the biasing means comprises a spring attached at one end to the bracket and at its other end to end, remote from the pivotal mounting, of the actuating lever.
6. An actuating accessory as claimed in Claim 5 in which the armature or plunger of the solenoid, when the solenoid is energised, acts on said end of the actuating lever remote from the pivotal mounting to pivot the actuating lever against the force of the spring thereby swinging the intertrip lever to cause circuit breaker tripping, the accessory thus acting as a shunt trip device.
7. An actuating accessory as claimed in Claim 2 or 3 in which the actuating lever is a two armed lever pivotally mounted on the bracket.
8. An actuating accessory as claimed in Claim 7 in which the armature or plunger of the solenoid, when the solenoid is energised, acts on one arm of the actuating lever to hold the actuating lever against the biassing force of the biassing means, and when the solenoid is de-energised the biassing means acts to pivot the actuating lever such that the other arm of the actuating lever engages the intertrip lever to swing

said intertrip lever and cause circuit breaker tripping, the accessory thus acting as an under-voltage release device.
9. An actuating accessory as claimed in Claim 8, in which the biassing means is a spring which acts on said other arm of the actuating lever.
10. An actuating accessory as claimed in Claim 9 in which the spring is carried by a guide rod.
11. An actuating accessory as claimed in Claim 9 or 10 in which said one arm of the actuating lever, on which the armature or plunger of the solenoid acts, is longer than said other arm of the actuating lever on which the spring acts.
12. An actuating accessory as claimed in any of Claims 9 to 11 in which the perpendicular distance between the line of action of the spring force and the point about which the actuating lever is pivoted is greater when the spring is compressed prior to tripping than when it is extended subsequent to tripping.
13. A moulded-case circuit breaker and, mounted side-by-side with and operatively coupled to the circuit breaker, an actuating accessory as claimed in any one of the preceding claims.