DE3609042C2 - Multipole, electromagnetically controlled interrupter with staggered partitions - Google Patents

Description

The invention relates to a multipole electromagnetic controlled interrupter of the type of a contactor with egg nem housing, which is equipped with an electromagnet, the has an anchor connected to a contact carrier is that for each pole with a movable contact bridge is provided, the contact bridges by contact pressure springs are loaded and in the contact carrier with the help are guided by interacting guide elements, the Housing for each pole with a pair of fixed cones clocking is equipped and the housing and the contact carrier ger between two adjacent interruption chambers Iso Show partition walls that increase the Iso lation between two neighboring poles.

The term isolation is used here in a broader sense and means:

• - A dielectric strength between those in each other doors adjacent to the interruption chambers contact zones,
• - a flashover resistance in the air between two parts len under voltage with opposite polarities,
• - a resistance to rollover on crawl paths along the Isolation between two parts under voltage with opposite set polarities,
• - Throttling the gases between two neighboring intermediate walls that are arranged as deflection elements.

A contactor of the type described in the introduction French Patent 2,519,186 is known by three adjacent partition walls, and one fixed partition and two movable ones Partitions that have a strong order in the arc zone steering or obstacle effect, an excellent Iso lation property between interruption chambers. As a result the thickness of the partitions and the work required This solution has clearance between the partition walls  quite a wide range.

On the other hand, in patent application DE-OS 14 65 227 suggested that between the adjacent interruption Parts of the contact carrier located in the chamber are H-shaped form, with two diagonally opposite legs of the H's longer than the other two legs. The leadership of the Contact bridge in the contact carrier is only on a small NEN leg of the H's instead; taking into account the leadership function changes the insulation and the width dimension the shooter only a little.

The big disadvantage of this solution is that the Iso lation quality remains secondary; it only has a single insulation partition in the arcing zone, what the great danger of double-sided damage and such perforation of this partition.

The aim of the invention is in particular to overcome these disadvantages eliminate and a multi-pole breaker of the type of a contactor who has good insulation properties th of the interruption chambers and in particular one sufficient dielectric strength of the insulation between has walls, this contactor at the same time a low Retains latitude and longitude.  

According to the invention are in a multi-pole breaker Type of contactor, relay described in the introduction or the like in adjacent interruption chambers contact separation zones by a double partition separated from each other, each from two to about the middle te of the contact bridges reaching fixed intermediate walls the and from two Z-shaped interconnected moveable Chen partition walls of the contact carrier, each fixed (movable) partition a first on the Area located on the side of the contact separation zone and a second area on the side of the movable partition possesses and the direct effects of the arc is set, and being between two neighboring sub Refraction chambers arranged against each other are offset that each fixed partition essentially lichen in the extension of the opposite movable Partition wall.  

In this way you get excellent insulation quality and at the same time a small size. The ge ring width of the contactor thus allows its execution with module dimensions.

In the following an embodiment of the invention will be wrote that shown on the attached drawing is. Show it:

Figure 1 is a perspective view of the housing of a four-pole contactor according to the invention.

Figure 2 is an exploded view of the components of the contactor with the cover removed.

Figure 3 is a front view of the base of the housing in which the fixed power contacts and connections are housed, the profile of the contact carrier is drawn in broken lines.

Fig. 4 is a side view of the contact carrier;

Figures 5 and 6 are a bottom view of the contact carrier or a section along the line VI-VI through the contact carrier.

Fig. 7 is an enlarged view of a double partition according to the invention between two adjacent interruption chambers.

The contactor shown in FIG. 1 has four poles and has a module housing 10 with a base 11 and a cover 12 , which are cast from plastic and can snap into one another.

Fig. 2 shows the removed components 12 of the contactor, namely a cast contact carrier 13 , a cage 14 , which holds the movable contact bridges P1-P4 ent and has a pin 15 on which the E-shaped armature 16 of the Electromagnet is attached. This also has a fixed E-shaped yoke 17 , which is arranged in the nose 12 a of the cover 12 , and a coil 18 , which is wound on a cast body 19 , which can snap onto the base 11 and on which the contact parts for the control connections A5 and B5 are attached.

The power connections A1-A4 and B1-B4, which are firmly connected to fixed contact pieces 21 and are separated from one another by transverse walls 22 of the base, and the control connections A5 and B5 have screw terminals 20 . A return spring 23 is mounted between the armature and the body 19 .

As shown in FIG. 3, the base 11 has fixed insulation partition walls F1-F6 arranged in pairs, which contribute to the insulation of the interrupting chambers C1-C4, the partition walls of a pair being offset in the transverse direction by a distance d from one another.

The contact carrier 13 has an upper wall 25 and a lower wall 26 which are stiffened by insulating partition walls M1-M6 ( FIGS. 4-7). Each partition wall unit Fi, Mi is inserted between separation zones A, A 'of the contacts of two adjacent interruption chambers C.

Each fixed insulation partition F1-F6 has a first surface 27 on the side of the associated contact separation zone A, A 'which is exposed to the direct effects of the arc, and a second surface on the side of the associated movable insulation partition M1-M6. Likewise, each movable insulation partition M1-M6 has a first on the side of the associated contact separation zone A, A 'located surface 29 which is exposed to the direct effects of the arc, and a second surface on the side of the associated fixed partition F1-F6 30th

As Fig. 6 and 7, which are the Kon clock 31, 32; 37 , 38 of the partition walls associated with adjacent contact bridges P offset by a distance + j +, eF being the mean thickness of the stationary partition wall F, j the clearance between the stationary partition wall and the movable partition wall and eM being the average thickness of the movable partition wall M. The insulation system thus has only a width of eF + j + eM, since each fixed partition F is located in the extension of the opposite movable partition M, and ensures good insulation between zones A, A ', with the distance L between neighboring Poland remains small.

The lamellar space 33 with the thickness j and the length l, which is almost or approximately equal to half the length of a contact bridge P, allows the throttling and cooling of an arc that may occur. The room 33 remains clean since it is not exposed to the direct effects of the arcs in the chambers C.

At a part of the height of the movable insulation walls M guide slats 34 are provided, which lead with their edge guide projections 35 of the contact bridges P in the contact carrier 13 Kon. These slats protrude across the width of the insulation system; they are symmetrical, but can also be asymmetrical, as in the aforementioned patent application DE-OS 14 65 227.

Claims (4)

1. A multi-pole, electromagnetically controlled interrupter of the contactor type with a housing which is equipped with an electromagnet which has an armature which is connected to a contact carrier which is provided with a movable contact bridge for each pole, the contact bridges are struck by contact pressure springs and are guided in the contact carrier with the aid of cooperating guide elements, the housing for each pole is equipped with a pair of fixed contacts, and the housing and the contact carrier between two adjacent interruption chambers have insulation partitions that have cooperate to increase the insulation between two neighboring poles,
characterized,
that the contact separation zones ( 31 , 32 ; 37 , 38 ) located in adjacent interruption chambers (C1, C2) are separated from one another by a double partition, each consisting of two fixed partition walls (F1, F4) reaching approximately to the center of the contact bridges and out two Z-shaped interconnected movable intermediate walls (M1, M4) of the contact carrier ( 13 ),
that each fixed partition (F) or movable partition (M) has a first surface ( 27 , 29 ) on the side of the contact separation zone ( 31 , 32 ; 37 , 38 ) and a second surface on the side of the movable partition (M) or the fixed partition (F) has a surface ( 28 , 30 ) and is only exposed to the direct effects of the arc on its first surface,
and that the between two adjacent interruption chambers (C1, C2) arranged partition walls are so offset against each other that each fixed partition wall (F) is located in the extension of the opposite movable partition wall (M). 2. Multi-pole breaker according to claim 1, characterized in that each double partition (F, M) extends over a distance ( 1 ) which is approximately equal to half the length of the contact bridge (P). 3. Multi-pole interrupter according to one of claims 1 and 2, characterized in that the contact carrier ( 13 ) in a manner known per se in its from the separation zones (A, A ') of the contacts ( 21 ; 31 , 32 ) remote central area Has slats ( 34 ) for guiding the contact bridges (P), the guiding slats being provided at a part of the height of the movable insulation intermediate walls (M). 4. Multi-pole breaker according to one of the preceding claims, characterized in that the Kontaktträ ger ( 13 ) forms a cage, the mutually ver set, movable insulating partitions (M) ensure the stiffening of the upper and lower surfaces ( 25 , 26 ).