NO780257L - OPERATING MECHANISM FOR HIGH VOLTAGE SWITCH. - Google Patents

Description

Operating mechanism for high voltage switch.

The invention relates to an operating mechanism for a high-voltage switch, comprising a cylinder and a piston for making and breaking the switch contacts.

Certain types of high-voltage switches, e.g. of the buffer type, has a relatively long breaking time. Attempts to reduce this breaking time have been achieved with advantage as shown in U.S. Patent Nos. 2,096,619, 2,436,194, 2,476,024 and 2,552,358.

In the case of high-voltage switches of this kind where different mechanical joint systems are used, it is necessary to start the movement of the system as quickly as possible when overcurrent occurs. When overcurrent occurs, it has been found that most mechanical means of initiating the breaking are unsatisfactory simply because of the time loss for applying power when the breaking signal occurs. In later constructions where electric preignitors are used, although these are usually faster, there will be an ignition time that is slower than desired. Ignitors of the so-called bridge wire type thus comprise a resistance wire which ignites a propellant charge directly, resulting in a relatively long ignition time of 1-3 milliseconds. Faster ignition is desirable to break the contacts when overcurrent occurs.

The purpose of the invention is therefore to provide an operating mechanism of the type mentioned at the outset which provides a shorter breaking time.

This is achieved according to the invention by a gas generator containing a fixed explosive charge which, when ignited, produces gas with high pressure against the piston, a fixed propellant charge, an igniter for the generator and a combustible material for igniting the generator, a pre-ignitor for the igniter comprising an electrically sensitive, combustible material and aids

ler for producing an electrical charge in the pre-ignition.

In this way, a spark discharge is achieved which gives a relatively short ignition time of approx. 0.3 milliseconds, so that the operating mechanism can provide breaking of the separable contacts in less than 1 3/4 period or 29.2 milliseconds.

Further features of the invention will appear from claims 2-10.

The invention will be explained in more detail below with reference to the drawings. Fig. 1 shows a side view in section of a high-voltage switch with an operating mechanism according to the invention in a broken state. Fig. 2 shows a section of fig. 1 where the operating mechanism is shown in the closed state.

Fig. 3 shows a longitudinal section through the propellant charge.

Fig. 4 shows a diagram for the movement as a function

of the time for a mechanism with a propellant charge and a pneumatic mechanism.

Fig. 5 shows an enlarged section of fig. 1.

The gas compression switch in fig. 1 comprises a pair of separable contacts 12,14 in an insulating housing 16, with an operating mechanism 18 for breaking and closing the contacts and aids 20 for producing a sudden explosion of a gaseous medium for breaking the contacts.

An insulating housing 16a contains a contact pair, not shown, corresponding to the contacts 12,14. The housings 16, 16a are supported by a support body 22 of insulating material of the same type as for the housings 16 and 16a, e.g. porcelain. The operating mechanism 18 comprises a cylinder 24, a piston 26, a piston rod 28, an angle arm 30 and a connecting rod 332 for moving the contact 14 between the open and closed position in the usual way.

When the piston 26 is moved to the left in the cylinder

26, the piston rod 28 will swing the angle arm 30 clockwise so that the connecting rod 32 is pulled down and the movable contact 14 is removed from the fixed contact 12. A shock absorber 34

is preferably arranged at the left end of the piston rod 28. When the piston rod 28 is driven to the left, a coil spring 36 is compressed. In the compressed state, the spring 36 is ready to close the contacts 12,14 by means of the operating mechanism 18 when a closing signal is received. The spring 36 is tensioned during the breaking operation for the piston rod 28 and is afterwards used to close the contacts 12,14 and return the piston to the right in the cylinder 24. For this purpose, a locking device 38 is arranged to keep the switch in the broken position when the breaking operation is finished. The locking device 38 is operated either by a solenoid, a driving charge or magnetic counteraction coils and comprises a sliding body 39 which enters a slot 40 on the piston rod 28. It should be noted that the locking device can be arranged at any place in the operating mechanism such as e.g. in connection with the angle arm 30 or the operating rod 32.

Furthermore, there is an end drive mechanism 20 with a gun-type gas generator comprising a barrel 42 and a chamber 44 for a propellant charge 50 as shown in fig. 3- The propellant charge comprises a housing 52 with a charge 54 of solid explosive material, an ignition charge 56 and an igniter 58. The propellant charge 54 comprises a combustible material which, when ignited, is brought out into the barrel which opens into the cylinder 24 where the combustion is completed and produces gas which propels the piston 26 from the position in fig. 2 to the switch position in fig. 1. The propellant charge 54 consists of e.g. of double basic smokeless gunpowder. The explosive gas can produce a pressure of 210-700 kg per cm 2 in the cylinder 24 to drive the piston 26 to the left to break the contacts 12,14 and tension the spring 36. A silencer 60 is arranged at the left end of the piston stroke to discharge the gas.

The ignition charge 56 is preferably separated from the driving charge 54 by a partition 62 and consists of a solid charge which produces a flame for igniting the driving charge 54. The ignition charge 56 is made of combustible material such as black powder or a mixture of amorphous boron powder and potassium nitrate.

The igniter 58 is electrically sensitive to a low-level signal or electrical pulse from an ignition lead 64 leading from an overcurrent or fault detection device not shown in the breaker circuit. The igniter 58 preferably consists of an electrically sensitive, flammable mixture such as e.g. lead styphnate and acetylene soot which ignites when activated by an electrical discharge which produces a small flame in the ignition charge 56 which in turn supplies an f-flame which ignites the propellant charge 54.

When an electrical pulse ignites the igniter 58, this ignites the ignition charge 56 which in turn ignites the driving charge 54. The gas produced by the driving charge drives the piston

26 whose piston rod 28 is directly connected to the operating mechanism 18. When the contacts are broken, the spring 36 is tensioned

for subsequent closing of the contacts upon tripping. When the piston 26 approaches the end of its working stroke, the movement is dampened by a shock absorber 34 and the piston passes an open exhaust opening to a silencer 60 which releases the gas into the surrounding air. In a fully broken state, the locking device 38, which is spring-loaded, will enter the groove 40 on the piston rod and hold this and thus the switch in a fully broken state.

To close the switch, a solenoid is not shown

which counteracts the spring force in the locking device 38 energized and the piston rod 28 is released. As a result of the return spring 36, the switch closes and an ejector mechanism ejects the empty explosive charge housing 50 and places a new charge in the chamber 44. The switch has thus completed an entire switch-close period and is ready for the next one.

The operating mechanism according to the invention provides a breaking time of less than 1 3/4 period as a result of the driving charge. The reduction in breaking time is entirely due to a reduction in dead time and an increase in operating power. As shown in fig. 4, the dead time a of the propellant charge is less than 0.5 milliseconds compared to 3 milliseconds for a pneumatically driven system. The start of force development is 1 millisecond or 4 milliseconds. There is at least a 5.5 millisecond difference between the two movement characteristics. Break can occur at the first zero crossing after 12.5 cm of movement, which means that the break time is equal to the time to reach a movement of 12.5 cm plus half a period (8.33 milliseconds). With propellant charge, breaking can occur in 19.6 milliseconds plus a half period equal to 27.9 milliseconds. If it is assumed that the generation of the trigger signal requires 1 millisecond, the total switching time will be less than 1 3/4 period (29.2 milliseconds).

The contacts 12 and 14 are preferably provided with an arc extinguishing device comprising a gas compression piston part 68 which cooperates with a cylinder part 70. It further comprises a hollow movable nozzle 72 to guide the direction of the compressed gas flow towards an arc not shown which is produced between the stationary contact 12 and the movable contact 14 when these are moved apart. The cylinder part 70 together with the movable contact 14 is mounted on a rod 74 which is in drive connection with the operating rod 32. When the contact 14 is moved to the broken position, gas in the space 76 between the cylinder and the piston is compressed and forced into the space between the separated contacts to extinguish an arc that forms between them.

An operating mechanism according to the invention with driving charge not only reduces costs, but also improves the effectiveness of high-voltage circuit breakers.

Claims (10)

1. Operating mechanism for a high-voltage switch, comprising a cylinder and a piston for making and breaking the switch contacts, characterized by a gas generator containing a solid explosive charge which, when ignited, produces high-pressure gas against the piston, and a solid propellant charge, an igniter for the generator and a combustible material for igniting the generator, an igniter for the igniter comprising an electrically sensitive, combustible material and aids for producing an electric charge in the igniter. 2. Mechanism according to claim 1, characterized in that the igniter comprises a mixture of boron and potassium nitrate. 3. Mechanism according to claim 1 or 2, characterized in that the ignition material comprises black powder. 4. Mechanism according to one of claims 1-3, characterized in that the igniter comprises a mixture of lead syphonate and acetylene soot. 5. Mechanism according to claims 2, 3 and 4, characterized in that a closing spring is arranged between the cylinder and the piston to return the piston to the support position. 6. Mechanism according to claim 5, characterized in that the piston works with a pressure of between 210 and '700 kg/cm2. 7. Mechanism according to claim 6, characterized by a releasable locking device which holds the contact in the broken position. 8. Mechanism according to claim 7, characterized in that the generator comprises a solid explosive charge of double basic smoke guard gunpowder. §. Mechanism according to one of the claims 1-8, vessel actuated by a hollow, movable nozzle to direct a stream of the compressed gas towards the arc which is formed between the contacts during refraction, aids for attaching the nozzle and also the movable contact to the piston. 10. Mechanism according to claim 9, characterized in that the locking device is releasably connected to a device which holds the contacts in the broken position.