GB1596432A - Circuit breaker operating mechanism - Google Patents

Description

(54) CIRCUIT BREAKER OPERATING MECHANISM (71) We, WESTINGHOUSE ELECTRIC CORPORATION, of Westinghouse Building, Gateway Center, Pittsburgh, Pennsylvania, United States of America, a company organised and existing under the laws of the Commonwealth of Pennsylvania, United States of America, 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 statement: This invention relates to a circuit interrupter, and in particular to an operating mechanism for operating a gas circuit interrupter of the "puffer type." Certain types of circuit interrupters, such as the so-called "puffer" circuit breaker, have involved relatively slow contact-opening time periods. Attempts to reduce the opening times have been made with some success, as disclosed in the specification of U.S. Patents Nos. 2,096,619; 2,436,194; 2,476,024; and, 2,552,358.

Inasmuch as circuit breakers of this type involve the use of various mechanical linkage systems, it is necessary to initiate movement of the system as soon as possible when an overcurrent occurs. When an overcurrent occurs, most mechanical devices for initiating the opening of contacts have been found unsatisfactory simply due to the time lost in applying forces once the signal to open occurs; i.e., dwell time. Indeed, more recent innovations using electrical primers although usually faster. still involve an ignition time which is slower than desirable. Thus, the called "bridge-wire" type of primer, comprising a resistance wire which ignites a propellant directly involves a relatively slow ignition time of one to three milliseconds. Faster ignition times are desirable in order to open contacts when overcurrents occur.

According to the present invention. a compressed gas puffer-type circuit interrupter comprises a gas-compressing piston part. a gas-compressing cylinder part. a stationary contact, a cooperable movable contact cooperable with said stationary contact to establish an arc therebetween during the opening operation of the puffer-type circuit interrupter, a hollow movable orifice member to assist in directing compressed gas against said established arc, means attaching said hollow movable orifice member and also said movable contact with one of said gascompressing parts, operating means utilizing explosive detonating means to operate said compressed gas puffer-type circuit interrupter so as to effect motion between said two gas-compressing parts for compressing gas therebetween and thus forcing said compressed gas through said hollow movable orifice and into engagement with the established arc to effect the arc's extinction, the detonating means comprising an igniter, a primer for the igniter, and ignition means for producing an electric charge in the primer, and the ignition means comprising an ignition line for detecting an overcurrent or fault in the circuit of the separable contacts.

The invention will now be described, by way of example, with reference to the accompanying drawings, in which: Figure I is a schematic elevational view, partly in section, showing a puffer type circuit interrupter in the open position; Fig. 2 is a fragmentary sectional view showing the interrupter in the closed position; Fig. 3 is a sectional view through a propellant cartridge; and Fig. 4 is a graph of travel vs. time for the travel characteristics of a propellant actuator and a mechanical actuator.

Fig. 1 illustrates a circuit interrupterofthe compressed gas puffer type and comprises a pair of separable contacts 12, 14 contained within an insulating casing 16, operating means 18 for opening and closing the contacts, and means 20 for generating a sudden expulsion of gaseous medium for opening the contacts.

The pair of contacts 12, 14 are similar to corresponding contacts (not shown) in the casing 16a. Both casings 16, 16a are supported on an upright support 22 of insulating material similar to the casings 16, l6a, such as porcelain.

The operating means 18 comprises a cylin der-piston assembly including a cylinder 24, a piston 26, a piston shaft 28, lever means 30, and " ;;onnecting link 32 for moving the contacts 12. 14 between open and closed positions in a conventional manner.

Generally, when the piston 26 is moved to the left of the cylinder 26 (Fig. I), the piston rod 28 rotates the bell crank lever 30 counterclockwise to pull the link 32 down and open the contacts 12. 14. A shock absorber 34 is preferably provided at the left end of the rod 28. Simultaneously. when the rod 28 is driven to the left, a coil spring 36 is compressed. In the compacted position, the spring 36 is ready to close the contacts 12, 14 through the operating means 18 when a closing signal is received. Thus, the spring 36 is charged or compressed during the opening stroke of the piston rod 28 and is used to subsequently close the contacts 12, 14 and return the piston to the right of the cylinder 24. For that purpose, a latch 38 is provided to hold the circuit interrupter 10 in the open position at the completion of the opening stroke. The latch 38 is a mechanism operated either buy a solenoid, propellant, or magnetic repulsion coils, which comprises a plunger 39 which engages a notch 40 in the piston rod 28. It is noted that the latch may be provided in any other portion of the operating means 18, such as in conjunction with the bell crank lever 30 or the link 32.

The generator means 20 is a gas generator of a shotgun type comprising a barrel 42 and a receiver or chamber 44. A cartridge load reject assembly 46 comprising a rod 48 is provided to automatically eject and reload cartridges during the closing stroke. A prop ellant cartridge 50 is generally indicated in Fig. 3. Within the cartridge casing 52 there is a propellant charge 54 of solid expulsive material, a charge 56 of igniter material, and a primer 58. The propellant charge 54 of expulsive material comprises an inflammable material which, upon ignition, is propelled through the barrel into the head of the piston cylinder 24 where it completes combustion to generate gas to drive the piston 26 from the closed position (Fig. 2) to the open position (Fig. 1). An example of the propellant charge 54 is a double base smokeless gunpowder.

The expulsive gas may develop a pressure of from about 3,000 to 10,000 psi within the cylinder 24 for driving the piston 26 to open the contacts 12, 14 and to compress the spring 36. A muffler 60 is provided to be effective at the end of the piston stroke 26 (Fig. I) lo exhaust the gas.

The igniter charge 56 is preferably separated by a partition 62 from the propellant charge 54 and is a solid charge which produces a flame for igniting the propellant charge 54. The igniter charge 56 is a burnable material, such as gunpowder known as black powder, or a mixture of amorphous boron powder and potassium nitrate.

The primer 58 is electrically sensitive to a low level signal or electrical pulse supplied by an ignition line 64 which leads from a means (not shown) for detecting an overcurrent or fault in the circuit of the contacts 12, 14. The primer 58 is preferably comprised of an electrically sensitive, flammable mixture.

such as lead styphnate and acetylene black, which ignites when activated by an electric charge to produce a small flame in the igniter charge 56 which, in turn, produces a flame for igniting the propellant charge 54.

In summary, when an electrical or light pulse triggers the firing circuit of the primer 58. the primer is actuated promptly to ignite the igniter charge 56 when in turn ignites the main propellant charge 54. The gas generaled by the propellant charge drives the piston 26 through its power stroke. The piston rod 28 is directly coupled to the linkage or operating means 18. As the contacts 12, 14 open, the spring 36 is charged in readiness for closing the contacts subsequently. When the piston 26 nears the end of its strokes, the motion is dampened by the shock absorber 34 and the piston passes an open exhaust port of the muffler 60 to exhaust the gas into the ambient through the muffler. At the full open position, a ball latch 38 which is spring loaded engages the groove or notch 40 on the rod in the open position to hold the circuit breaker in full open position.

To close the interrupter, a solenoid (not shown) opposing the spring force of the latch 38 is energized and the piston rod 28 is released. As the return spring 36 closes the interrupter, the load-eject mechanism 46 including the rod 48 which extends from a spring backup plate 66 ejects the spent cartridge 50 and loads a new cartridge into the chamber 44. Thus, the circuit interrupter 10 has completed a full open-close cycle and is ready for the next cycle.

Mechanism tests under puffer load simulation indicate maximum breaker interrupting times of less than 1-3/4 cycles (60 Ht) as a result of an actuator powered by solid propellant. The decrease in operating time is due entirely to a reduction in (1) the dead time, and (2) the characteristic rise of the actuator force. As shown in Fig. 4, the dead time A of the propellant actuator is less than 0.5 milliseconds as compared with S milliseconds as indicated by B for a penumatically operated system. The force rise times are typically 1 millisecond and 4 milliseconds for the propellant and pneumatic actuators, respectively. The travel characteristics of both systems are shown in Fig. 4. There is at least 5.5 milliseconds time difference between the two travel characteristics. Circuit interruption can occur at the first current zero following five inches of travel, which implies the breaker interruption time is equal to the time to reach five inches of travel plus 1/2 cycle (8.33 milliseconds). Thus, the propellant system can interrupt in 19.6 plus 1/2 cycle or 27.9 milliseconds. Assuming a relay for providing the signal consumes I millisecond, the total interruption time is less than 1-3/4 cycles (29.2 milliseconds).

The contacts 12, 14 are operatively associated with arc extinguishing structure comprising a gas compressing piston part 68 which is operatively associated with a gas compressing cylinder part 70. The structure also comprises means defining a hollow movable orifice member 72 to assist in directing compressed gas against an arc (not shown) that may develop between the stationary contact 12 and the movable contact 14 when the latter is moved to the open position as shown in Fig. 5. The cylinder part 70, together with the movable contact 14, is mounted on the shaft 74 which is operatively connected to the connecting link 32. Accordingly, when the contact 14 moves to the open position (Fig. 5), a gas within a space 76 between the cylinder and piston parts 68, 70 is compressed and forced into the space between the separating contacts in order to facilitate in extinguishing an arc created during opening of the contacts.

Thus, the propellant-type actuator of this invention not only reduces cost, but improves performance.

WHAT WE CLAIM IS: 1. A compressed gas puffer-type circuit interrupter comprising: a gas-compressing piston part, a gascompressing cylinder part, a stationary contact, a cooperable movable contact cooperable with said stationary contact to establish an arc therebetween during the opening operation of the puffer-type circuit interrupter, a hollow movable orifice member to assist in directing compressed gas against said established arc, means attaching said hollow movable orifice member and also said movable contact with one of said gas-compressing parts, operating means utilizing explosive detonating means to operate said compressed gas puffer-type circuit interrupter so as to effect motion between said two gas-compressing parts for compressing gas therebetween and thus forcing said compressed gas through said hollow movable orifice and into engagement with the established arc to effect the arc's extinction, the detonating means comprising an igniter, a primer for the igniter, and ignition means for producing an electric charge in the primer, and the ignition means comprising an ignition line for detecting an overcurrent or fault in the circuit of the separable contacts.

2. A circuit interrupter as claimed in claim I in which spring means are provided for returning the piston to a contact-closed position and in which latch means are provided for holding the contacts in the open position.

3. A circuit interrupter as claimed in claim 2 in which the latch means are releasably connected to the operating meatus for holding the contacts in the open position.

4. An electric circuit interrupter, constructed and adapted for use, substantially as hereinbefore described and illustrated with reference to the accompanying drawings.

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

Claims (4)

**WARNING** start of CLMS field may overlap end of DESC **. time to reach five inches of travel plus 1/2 cycle (8.33 milliseconds). Thus, the propellant system can interrupt in 19.6 plus 1/2 cycle or 27.9 milliseconds. Assuming a relay for providing the signal consumes I millisecond, the total interruption time is less than 1-3/4 cycles (29.2 milliseconds). The contacts 12, 14 are operatively associated with arc extinguishing structure comprising a gas compressing piston part 68 which is operatively associated with a gas compressing cylinder part 70. The structure also comprises means defining a hollow movable orifice member 72 to assist in directing compressed gas against an arc (not shown) that may develop between the stationary contact 12 and the movable contact 14 when the latter is moved to the open position as shown in Fig. 5. The cylinder part 70, together with the movable contact 14, is mounted on the shaft 74 which is operatively connected to the connecting link 32. Accordingly, when the contact 14 moves to the open position (Fig. 5), a gas within a space 76 between the cylinder and piston parts 68, 70 is compressed and forced into the space between the separating contacts in order to facilitate in extinguishing an arc created during opening of the contacts. Thus, the propellant-type actuator of this invention not only reduces cost, but improves performance. WHAT WE CLAIM IS:

1. A compressed gas puffer-type circuit interrupter comprising: a gas-compressing piston part, a gascompressing cylinder part, a stationary contact, a cooperable movable contact cooperable with said stationary contact to establish an arc therebetween during the opening operation of the puffer-type circuit interrupter, a hollow movable orifice member to assist in directing compressed gas against said established arc, means attaching said hollow movable orifice member and also said movable contact with one of said gas-compressing parts, operating means utilizing explosive detonating means to operate said compressed gas puffer-type circuit interrupter so as to effect motion between said two gas-compressing parts for compressing gas therebetween and thus forcing said compressed gas through said hollow movable orifice and into engagement with the established arc to effect the arc's extinction, the detonating means comprising an igniter, a primer for the igniter, and ignition means for producing an electric charge in the primer, and the ignition means comprising an ignition line for detecting an overcurrent or fault in the circuit of the separable contacts.

2. A circuit interrupter as claimed in claim I in which spring means are provided for returning the piston to a contact-closed position and in which latch means are provided for holding the contacts in the open position.

3. A circuit interrupter as claimed in claim 2 in which the latch means are releasably connected to the operating meatus for holding the contacts in the open position.

4. An electric circuit interrupter, constructed and adapted for use, substantially as hereinbefore described and illustrated with reference to the accompanying drawings.