SE460812B - switchgear - Google Patents

Description

i gßflyIIIIIN] ||| wWmlrl [l |||||||| l |, | r, "TnuHW ,, 2 466 * 812 'Has a high current so that contact welding is avoided, but at the same time the design has the disadvantage that the contactor Due to the contact attraction can not be used for breaking currents exceeding a relatively moderate overcurrent value.By placing the magnets in direct connection to the contact point _ also disappears the possibility of blowing out the arc in the contactor extinguisher with the help of the magnetic field generated by the current. This is partly due to the fact that the contact pressure-increasing magnets shield the field around the contact point, and partly because with this magnetic placement it is necessary to design the contacts so that the current goes straight through the magnetic circuit and not in a loop path, which would have given a blow of the arc_ against the extinguishing lamella package.

It is further known to arrange U-shaped traction magnets in contactor-like devices to increase the contact pressure in the event of moderate overcurrents, see for example Swedish Explanatory Note 8103400-1.

These tensile magnets are intended to, in conjunction with repulsion magnets, make these devices sent to be able to break short-circuit currents as well. The pull magnets are so dimensioned that they saturate when the overcurrent exceeds a value corresponding to normal motor starting currents, eg 10 times the rated current.

These devices are special designs and therefore relatively expensive compared to ordinary contactors.

DISCLOSURE OF THE INVENTION The object of the present invention is to provide an electrical switch with a current-dependent contact pressure amplifying magnetic circuit which prevents contact lifting in the critical overcurrent range up to about 30 times the rated current, but which at the same time allows the circuit breaker * to be used. the limit determined by the breaking capacity of the electrical switch. This is achieved according to the present invention by means of an electrical coupler which has the features stated in the characterizing part of claim 1.

By arranging according to the invention a contact pressure-enhancing magnetic circuit, where the magnetic core is silently connected to the contact conductor of the electrical coupler and the armature is silently connected to the movable contact, the following advantages are achieved: a) b) c) d) d) f) 9) Resistance at the arc screen. ~ «--..._....._., .....- ..» ..... w ................... ......................... ~ .......... ~ ....-- .., __... .._ ...___ __., TR * 3 130.812 The electrodynamic repulsive forces can be balanced out so that a higher lifting current is obtained. This avoids contact lifting within a large current area.

The spring force of the contact compression springs can be kept lower than normal. As a result, contactors can be used to select a smaller size of the control magnet, which in addition to cost savings entails less wear and thus a long mechanical life.

Because the core in the magnetic circuit is fixed to the contact driver, the contact driver is attracted to the contact, whereby the switch-off is facilitated. A distinct contact separation occurs, which gives shorter breaking time and thus lower arc energy. The spring force in a contactor's spring-up springs can be minimized for the same reason as in point c. V The coordination between the electrical switch and with this series-connected devices such as fuses, current-limiting 'A »I switches, motor protection switches, etc. is radically improved.

The energy development when the current exceeds the lifting current and arc occurs (eg in the event of a short circuit) becomes lower, which means lower pressure and thus lower requirements for holding. The risk of anchor bounce on a contactor's actuating magnet when the engine starting current is switched on is reduced by the attractive force. ~ .... mw - .. 1 ... s ...._., .-. ~ »~ vnnumv ~ mnwww-v ........ ~. ~ .m ..... . ,, _ _ ________, __________ 7 i 460 812 g A 'f 1 ï | 1 l I h) Since the contact burn-off gradually reduces the air gap between the core and the armature in the magnetic circuit, the circuit is activated at lower currents the older the electrical switch becomes.

This reduces the requirements for post-suspension, surface finish of the contacts, etc.

DESCRIPTION OF THE DRAWINGS The invention will be explained in more detail by describing exemplary embodiments with reference to the accompanying drawing, in which Fig. 1 shows a contactor made according to the invention in longitudinal section, Fig. 2 shows half of the same contactor in cross section I along the line II-II in Fig. 1, Fig. 3 shows the contactor contact system in perspective, Figs. 4 and 5 show on a larger scale the central part of the É movable contact system in cross section and longitudinal section, Fig. 6 schematically shows a magnetic circuit arranged around the contactor's movable contact and the associated magnetic field image, Fig. 7 shows curves over the forces acting on the movable contact system É as a function of the current, and - Fig. 8 shows a tripping curve for a fuse connected in series with the contactor. f 4150 8'12 .Q DESCRIPTION OF EMBODIMENT The contactor shown in Figs. 1 and 2 is three-pole and has a rated voltage of eg 660 V. The contact current of the contactor can, for example, be in the range 100 - 1000 A. The contactor is built on a stand 1 of die-cast light metal. The stand supports a holder 2 made of plastic with connection rails 3, 4 for connecting the contactor in an external main circuit.

The contactor's contact device, which is shown in the drawing in the off position, is enclosed by an arc shield 5 made of plastic provided with extinguishing plates 6. The contact device comprises in each pole two electrically connected switching points arranged in separate switching chambers 7, 8. has a fixed contact 9 and 10, respectively, which is attached to the connection rail 3 and 4, respectively.

In the closed contact position, the fixed contacts are connected to each other by a contact bridge consisting of a movable contact 11 "and an iron fitting 12 lying on top of the movable contact for mechanical stiffening of the contact.

The contact bridge is fixed in an opening 13 in a contact guide 14 which is connected to the armature 15 of the contactor actuating magnet, whose magnetic core and coil are denoted by 16 and 17, respectively. The armature 15 is actuated by disconnecting springs 18, only one of which is shown.

When the coil 17 is de-energized, these springs push the armature 15 into the position shown in Figs. 1 and 2. The contact bridge 11, 12 passes between the legs 19 of a U-shaped bracket 20 arranged in the contact guide 14 (Fig. 3). The free ends of the stirrup 19 in the legs 19 are connected by a pin 21. Between this pin 1 and the movable contact bridge 11, 12 there is a leaf spring 22. In the stirrup 20 a contact compression spring 23 is arranged. The movable contact 11 is enclosed by a magnetic circuit consisting of a magnetic core 25, which is rigidly connected to the contact guide 14, and a magnetic anchor 26 which is fixedly attached to the movable contact. As best seen in Figs. 4 and 5, the fixation of the magnetic core 25 is accomplished by holding it by the contact compression spring 23 against a shoulder 24 in the contact guide 14. The jumper 20 is axially movable in the contact guide 14 against the action of the springs 22 and 23.

When, in the contactor's current, current flows through the movable contact 11, the magnetic circuit 25, 26 (Fig. 6) is magnetized, an attractive force Fa appearing between the magnetic core 25 and the contact bridge 11, 12. This attractive force is composed of a relatively large force Fa1 between the core 25 and the armature 26 and a smaller force Paz between the core 25 and the contact 11.

The attractive force Fa cooperates with the static spring force FS exerted by the springs 22 and 23. At the same time, the contact bridge is affected by an electrodynamic repulsive force Fr.

In order to achieve a higher saturation value for the magnetic circuit 25, 26 without having to increase the dimensions of the electrical coupler, as shown in Fig. 4, the magnetic core 25 has a larger cross-sectional area in the bottom part 25a than in the legs 25b. In this way, Paz increases with the current.

Fig. 7 shows how the above-mentioned forces Fa, FS and Fr acting on contact bridge vary as a function of the instantaneous value of the current i. In the diagram the "lifting current" in the contact system has been marked, ie the current value at which contact separation takes place. As can be seen, this value is significantly higher than the lifting current ice for a corresponding contact system without the magnetic circuit 25, 26.

Fig. 8 shows the tripping curve for a fuse intended for series connection with the contactor, ie the tripping time t as a function of the current effective value I. The current scale in Fig. 8 is then directly comparable to the current scale in Fig. 7. With a contact system without the described magnetic circuit, contact separation takes place at the current IS. At this current, the fuse has a tripping time ts- during which burns on the contacts and any contact welding can take place before the current is interrupted. With a contact system provided with a magnetic circuit 25, 26 according to the present invention, the lifting current Im is considerably higher, and

Claims (5)

7 460 812 at this current, the tripping time of the fuse tm is so short, (<50 ms), that if a contact separation takes place at all before the current is interrupted, no melting of the material in the contact surfaces occurs or is severely limited. PATENT REQUIREMENTS Electrical coupler with at least one pair of contacts comprising a fixed (9) and a movable contact (11), of which the movable contact (11) is under the influence of a contact compression spring (23) and is displaceable between two positions by means of a 1- .111 a menu driver (15, 16, 17) coupled contact driver (IQ). which carries the movable contact, which is movable relative to the contact guide (1 fi) against the action of the contact compression spring (23). wherein, in order to amplify the contact pressure at high currents, a magnetic circuit magnetized by the current through the contacts (9, 11) is arranged, comprising two parts (25, 26) of ferromagnetic material. of which one part (26) is attached to the movable contact (11) and the other part (25) is supported by the contact driver (14). characterized in that said second magnetic circuit part (25) is arranged to be held by the contact compression spring (23) against a stop (24) arranged on the contact guide (14). Electrical coupler according to claim 1, characterized in that the movable contact (11) consists of a contact bridge for connecting two fixed contacts (9, 10) arranged at a distance from each other, wherein the contact bridge is connected to said contact driver via an anchor (15) on a control magnet (16. 17). Electrical switch according to Claim 2, characterized in that the contact pressure spring (23) is arranged on the side of the contact bridge (11) which faces the operating magnet (15. 16. 17). whereby the spring force is transmitted to the contact bridge via a drawbar (20). 4. An electrical switch according to claim 3, characterized in that said second nanget circuit part (25) is U-shaped, the bottom part (25a) of the U having a larger cross-sectional area than the legs of the U (25b). _ W WW »H H \“ wlww VIAWÛWVYWNW 'WIN "H- fl ww WWW' Å v '' Whwr“ wlrw fl wwyuwwq fl n I 460 812 Electrical switch according to Claim 2, 3 or Ä, characterized in that the contact bridge comprises a current-carrying part (11) of material with good electrical conductivity, and a mechanically stiffening part (12) extending along the entire current-carrying part ferromagnetic material, which is arranged on the side of the contact bridge projecting from the fixed contacts (9, 10), said one magnetic circuit part (26) being wholly or partly constituted by said mechanically stiffening part (12). É.