DE3544650A1 - High-speed contact driver for an electrical circuit breaker - Google Patents

Abstract

A bridge contact is arranged above two stationary contact elements, two parallel conductors which are close to one another being used as the bridge contact carrier. A powerful current pulse in the opposite direction within the parallel conductors produces electrodynamic forces which drive the conductors quickly apart from one another. The bridge contact which is supported by the parallel conductors is quickly driven out of contact engagement with the stationary contact elements in order to interrupt the circuit.

Description

High speed contact driver for an electrical

counter

The invention relates to a high speed contact driver for quick disconnection of bridge contacts from a pair of fixed contact pieces.

The US-PS 3,215,796 describes the idea of using a line current / to a current in a current loop that closely includes spaced parallel conductors, to induce to push the conductors apart and movable contact pieces of to separate associated fixed contact pieces.

U.S. Patent 3,168,626 describes a fuse using the kickback forces that are developed by fault currents, flowing in opposite directions through closely spaced, parallel fuse links, around one or both Separate connections and thus interrupt the faulty circuit.

The DS-PS 3 002 065 describes the use of excessive

Line currents flowing in the opposite direction through conductive Pillars flow, uir; to repel one of the pillars and thus form a shunt path to protect a meter.

It is an object of the invention to provide a high speed contact driver arrangement create where a high current pulse is used to electrodynamically repel two conductors, which serve as a contact carrier for a bridge contact, which has two contact pieces within a circuit arrangement to be protected are arranged to provide an extremely fast power interruption in the event of a corresponding command.

According to the present invention, there is provided a high speed contact driver created in which a bridge contact is resiliently or elastically held by a cantilever spring and by two closely spaced electrical conductor is worn. The bridge contact is in electrical contact engagement by a contact spring preloaded with two stationary contact pieces. A current pulse that is fed to the conductors is electrodynamic Repulsion of the conductor and the lifting of the bridge contact away from the fixed contact pieces the preload of the contact spring result.

The invention will now be described with further features and advantages on the basis of the description and drawings of exemplary embodiments explained in more detail.

Figure 1 is a partial sectional view of the high speed contact driver according to the invention.

Figures 2A and 2B show partial sectional views of the contact driver according to Figure 1 before and after excitation.

Figure 3 is a graph of the contact bridge separation force relative to the separation distance between the bridge contact and the fixed contact pieces.

Figure 4 is a partial sectional view of another execution '* approximately example of the high speed contact driver f

according to Figure 1. |

In Figure 1, an embodiment of the high-speed contact driver 10 according to the invention is shown in which
two rigid conductors 11, 12, each carrying a fixed contact piece 13, 14, connected by a bridge contact 15,
are. The bridge contact is carried by two conductors 20, 21, | which are attached at one end to the contact piece in such a way that | that the bridge contact the two conductors electrically in parallel S

switches. The opposite ends of the two conductors are on f? corresponding way with two connection terminals 22.23 ρ

connected by connecting screws 24,25. The electrical cons a bond is established with the two conductors in that ^

a power source is connected to the terminal screws. ψ A block of insulating material 16 of a predetermined mass M ₁ I is at one end of a cantilever or cantilever spring fixed by a screw 19 k 18, and the spring is to egg j ner holder 17 at the opposite end by a getrenn- f th Screw. The mass M _{2 of} the bridge contact is

chosen so that they are very small with respect to the mass M .. des
Is insulating material. A contact spring 26 is on its one
End attached to the bridge contact, and the other end is
firmly attached to a support 27. The tension exerted by the contact spring 26 is set so that the bridge contact is in good electrical connection with the stationary
Contact pieces is held opposite to the force,
by the cantilever spring 18 on the bridge contact via the
serene 20.21 is exercised. If the contact driver is within
If a switch is used, _{the circulating current I 9 flows} between the rigid conductors 11, 12 in the specified direction
by the fixed contacts 13,14 and the bridging contact 15. The length I ^ the conductor 20,21 and the contact distance d .. is set so that a vorbestiminter, gesteu-] erter current pulse I ₁ in the directions indicated a *.

sufficient electrodynamic repulsion between the two
Ladders created to overcome the prestress created by

the contact spring 26 is exerted, and in order to quickly separate the bridge contact from the fixed contact pieces within a time increment of 10-100 microseconds from the start of the current impulse I ₁ .

The current loop between the terminal screw 24, the conductor 21, the bridge contact 15, the conductor 20 and the terminal screw 25 is formed is shown in Figure 2 (a) no current flows through the loop and a permanent magnetic field is applied to a central section of the conductors, as indicated by the dashed rectangle 30. The essential increase in the electrodynamic repulsive forces, which are exerted on the conductors by the addition of the magnetic field, will be explained in more detail below with reference to FIG explained.

The effect of the electrodynamic forces, shown as F ₁ and F ₁ 'in the indicated directions, is shown in Figure 2 (b) compared to Figure 2 (a). It should be noted that the distance d_ between the conductors in the event of an electrodynamic repulsion is substantially greater than the initial distance d- and that the bridge contact is

15 has separated from the fixed contact piece 13 by an increment djCL. The large separation distance d_ is the effect of the repulsive forces F ₁ , which is proportional to the product of the current I ₁ multiplied by the magnetic field strength exerted by the magnetic field 30. The force on the bridge contact is represented by the force vector F ₂ , which is effective in the specified direction, with a force F 'of the same magnitude in the opposite direction on the block

16 is exercised. Since the mass M _{n of} the contact piece 15 is much smaller than the mass M .. of the block 16, the same forces F2 and F ₂ 'generate a much greater acceleration of the contact piece 15 than that of the block ^ 6. Thus, within the 100 microsecond time frame, block 16 remains essentially stationary.

The change in the force F “on the back contact as one

- m

The function of the distance between the bridging and the stationary contact pieces without a permanent magnetic field 30 is shown at 28 in FIG. It should be noted that the force F ₂ on the bridge contact is very high at the beginning, on the order of about 50 kp, in order to provide a strong acceleration when the current pulse I _{1 is applied} at the beginning and then drops rapidly, when the bridge contact 15 is separated from the fixed contact pieces 13, 14 and the distance from zero to a few thousandths of a millimeter. grows. The effect of the permanent magnetic field 30 is shown at 29 to increase the force exerted on the bridge contact at greater contact spacings.

Another embodiment of the high speed contact driver 10 is shown in FIG. The current loop is between the conductor 20, the bridge contact 15 and the Head 21 formed. TÜne platform 35 made of insulating material that also held by two supports 7, 31 made of insulating material is, has an opening 36 for the passage of two conductors and is used to hold a helical spring 33, which biases the bridge contact against the bias of the contact spring 26 in a similar way to the cantilever spring 18, as described above in connection with the arrangement according to FIG. The platform and the rigid ladders 11,12 are attached to the supports 17, 31 by screws 19, such as it is shown in FIG. The conductors 20, 21 are formed as a secondary winding forming a turn around a toroidal one Core 32 arranged, with a primary winding 34 having many turns by connecting conductors 22,23 and connecting screws 24.25 is connected to an external circuit arrangement. The toroidal core is on the insulating block 16 attached and increased the mass of the block 16 for the advantageous relation between this mass and the mass that forms the bridge contact, as already explained above became. A current pulse which is fed to the connecting conductors 22, 23 is caused by the transformer effect through the Core reinforced and is induced in the conductors 20.21 to

to form the predetermined current I-, which is specified in the Directions flows to separate the ladder.

Above it was shown that an extremely fast contact separation can be achieved against a large contact holding force, such as the contact spring 26 on a small contact mass, such as example. as M ₁ , is exerted relative to a smaller contact separation force, as it is exerted by the cantilever spring 18 on a large mass such as M ^. If electrodynamic. *? Forces are developed to increase the contact separation force, the large power mass remains practically fixed, resulting in great acceleration during the initial contact separation, which is highly desirable in order to limit the magnitude of the switching current. Larger current pulses, such as those represented by I .., can also be used together with stronger magnetic fields in order to further increase the separation forces and to ensure even faster contact separation.

The switch according to the invention can be used in conjunction with a solid-state switch can be used in parallel to the contact pieces, the current immediately after the contact has been separated from the Contact pieces are diverted away - around the arc energy to reduce substantially and, as a result, to substantially eliminate the detrimental arcing effect on the contact pieces. This in turn allows the contact pieces to be made much smaller, reducing both their thermal mass and their inertial mass is reduced. The reduction in the inertial mass, in turn, allows the contacts to separate more quickly and thus the interruption of the circuit is reached during the early stages of the current curve. the The smaller inertia mass of the Kentakt pieces allows their use a bridge contact between two fixed contact pieces, as in the German patent application filed at the same time P (attorney's reference: 9741-41PS-6329) is explained. the

Bridge contact arrangement, ensures a further reduction in size Mass of the contact pieces, so that an even faster contact separation can be achieved and a Stromuriterbrechung accordingly occurs earlier stages of the current curve.

Claims (17)

Claims 1. High speed contact driver for an electrical Switch, characterized by: two electrical conductors (20,21) arranged side by side are and extend between first and second springs (18,26), a bridge contact (15) which are carried by the electrical conductors and disposed for electrical connection between two fixed contacts (13,14) and _/ Means for providing a predetermined current pulse to the conductors (20,21) for an electrodynamic repulsion of the conductor and separation of the bridging contact (5 1) \ ^r on the fixed contact pieces (13,14). 2. Contact driver according to claim 1, characterized in that that the <=> r.c: -f-e spring (18) denotes Bridge contact (15) from the fixed contact pieces (13,14) biases away and that the second spring (26) the The bridge contact (15) is biased towards the stationary contact pieces (13, 14). 3. Contact driver according to claim 1, characterized in that that an insulating block (16) between fr · rf · rerar see the first spring (18) and the two electrical conductors (20,21) is arranged to hold the two electrical conductors. 4. Contact driver according to claim 1, characterized that two rigid conductors (11, 12) are provided, cL. »The fixed contact pieces (13, 14), wherec = 2 "each time a fixed contact piece is located at the end of each rigid ladder. 5. Contact driver according to claim 1, characterized that the first spring exerts a first force on the bridge contact and the second spring exerts a second force on the bridge contact, the first force being less than the second force. 6. Contact driver according to claim 3, characterized that the insulating block (16) has a first mass and the bridge contact (15) has a second mass having, wherein the second mass is smaller than the first mass and the speed of separation of the Erükenkontaktes promotes from the fixed contact pieces. 7. Contact driver according to claim 3, characterized that the first spring in a cantilevered relation with the insulating block and a fixed bracket is arranged for moving the insulating block, the conductor and the bridge contact in one first level of movement. 8. Contact driver according to claim 7, characterized that two electrical conductors are moved apart in a second plane of movement, which is perpendicular to the first plane. 9. Contact driver according to claim 1, characterized that the second spring has a helical spring. 10. Contact driver after. Claim 1, characterized that the facility for delivery / first
tion of current pulses one and a second connection having, the first terminal to the one conductor
at one end and the second connector to the other
Head connected at one end. 11. Contact driver according to claim 10 / thereby ge I indicates that the electrical conductors | (20,21) at their ends / which have the first and second ant Opposite ends / through the bridge contact (15); are connected to each other. I. Crs I 12. Contact driver according to claim 1 / characterized in that di ^ two conductors (20,21) ψ a first and a second wire predetermined, | have the same length and are arranged such that | the separation distance between the wires is less than the | is a predetermined length. ! i 13. Contact driver according to claim 1, characterized overall I indicates that the device for the supply of current pulses of a toroidal core (32) comprises up Ϊ and the two electrical conductors as at least one f C> secondary winding are arranged on the core. *, 14. Contact driver.according to claim 12, characterized in that § indicates that on the core (32) little- I I at least one primary turn is arranged. I. 15 .. contact driver according to claim 13, characterized in that the toroidal core X (32) in an insulating core support block with means I. r for electrical connection with the two conductors (20,21)] is firmly arranged. | 16. Contact driver according to claim 1, characterized in % indicates that at least one holding | rung plate (35) with an opening (36) for a passage the two conductors (20,21) is provided. 17. Contact driver according to claim 15, characterized in that that the first spring has a helical spring (33) "around the two conductors and between the core support block and the support plate is arranged.