DE1185703B - Bounce-free contact device - Google Patents

Description

Bounce-free contact device The invention relates to a Contact device, which in addition to the effect of contact compression springs when current flows is under the effect of contact pressure-intensifying electrodynamic forces.

There is already an arrangement for contact devices of the aforementioned artist proposed with two parallel contact bridges encompassing the fixed contact pieces been, between which, with current flow, contact pressure-boosting electrodynamic Forces occur.

Furthermore, a contact device with one-sided is preferred Coaxial fixed contacts arranged contact bridges have been proposed, those arranged at a short distance from the contact bridge when current flows from one ferromagnetic body, e.g. B. an iron plate, are attracted.

Such contact devices are higher in particular for switches Current carrying capacity, e.g. B. switch-disconnector, suitable because the overcurrent resp. Short-circuit occurring electrodynamic forces to a contact pressure gain contribute and therefore welding the contacts is safely avoided. The bounce-free However, switching on the described contact devices causes difficulties because the contact pressure-intensifying electrodynamic forces with respect to the contact bridges or contact levers only reach their full value when the moving Contact carrier has built up a chained magnetic field. That up to that point Any bouncing impacts occurring during the switch-on process can therefore be caused by the electrodynamic Forces are not compensated or reduced to harmless values.

Additional masses for preventing contact bruises are known per se. In a known contact arrangement, the movable contact piece has for this purpose a hollow body closed on all sides, in which one in the direction of movement of the contact piece movable relative to the hollow body, e.g. B. from small metal balls or a liquid existing mass through which a strong, the Internal damping that consumes bounce energy is to be generated. For the mobile Switching pieces are relatively complex custom-made products from other power lines involved cages required for the damping mass, which is particularly in view must be felt to be disadvantageous for larger switching capacities. In contrast, wants the invention manage with standard contact pieces or contact pads. It is also a contact piece for electrical switching devices known per se the one designed as a leaf spring contact piece carrier with a mass Spring is coupled. With this arrangement, the one that becomes free when switching on Bounce energy converted into vibrations of the leaf spring that are harmless for making contact are in such a way that the contact or switching points are the nodes for the vibrations the leaf spring form. However, such a contact device is not in the Able to carry an appreciable current because of the required ability to oscillate the contact bridge, the cross-section and thus the mass of the contact bridge is kept small Need to become.

In contrast, the present invention is intended to be a bounce-free Contact device of the type mentioned above are created, the current-carrying capacity is not limited, but in which, despite considerable masses to be moved, contact bruises are practically to be avoided. According to the invention, the task set is thereby achieved solved that with the movable contact piece of a contact piece carrier an additional mass is coupled in such a way that when switching on after contact has been made, the movable Contact piece against the fixed contact piece as long as a result of the inertia of the Additional mass is pressed until the electrodynamic forces have a sufficient contact pressure reinforcing Have achieved an effect. It is particularly advantageous if the additional mass corresponds to the on free end of a pivotably mounted contact bridge arranged contact piece is assigned, wherein the pivotably mounted end of the contact bridge with a Contact surface spring-loaded against a fixed contact piece forming the pivot axis is held. The additional mass can with the carrier of the movable Contact piece firmly connected or with the interposition of elastic members be coupled. If the additional mass is firmly connected to the contact piece carrier, then it is advantageous to connect the free end of a contact bridge to the additional mass in this way to be connected or to be extended by the mass beyond the contact piece, that the contact piece has a rolling motion on the associated Fixed contact piece executes against the force of contact compression springs.

In the event that the additional mass with the free end of the contact bridge is elastically coupled, it is advantageous to place the mass on the contact piece remote side also with a serving as an abutment with the contact bridge firmly connected arm, extension or the like. To be elastically coupled.

The size of the additional mass and the spring constant are useful the coupling springs for the additional mass or the contact compression springs are selected so that the additional mass does not swing back after contact has been made, when the contact pressure-intensifying electrodynamic forces reach a maximum or almost have reached a maximum. In this case, the additional mass can swing back do not have an effect in the form of a bruise, but at most it will be a rolling motion take place between the fixed and the movable contact piece.

Exemplary embodiments of the invention are described with reference to the drawing and how it works.

Fig. 1 shows a schematic representation in elevation of a bridge contact device with additional mass elastically coupled to the contact bridge; F i g. 2 shows in one of the F i g. 1 corresponding representation with a bridge contact device an additional ground firmly connected to the contact bridge; in Fig. 3 to 5 is qualitatively the curve of the inrush current plotted against time, namely shows Fig. 3 the current curve of a bridge contact device without additional ground, F i g. 4 shows the course of the current with additional mass, but without the contact pressure reinforcing electrodynamic forces and finally F i g. 5 the course of the current with additional ground and with contact pressure-intensifying electrodynamic forces; in Fig. 6 is also qualitatively the course of the contact pressure-intensifying electrodynamic forces and the course of the current is plotted after the switch-on process.

The contact device contains two coaxially opposite fixed contact piece carriers T1 and T "which are bridged by the contact bridge T3. Between the contact piece K arranged on the fixed contact piece carrier T1 and the contact piece K3 arranged on the contact bridge T3, the switching path is formed, while the contact piece K .., des Fixed contact piece carrier T, forms a pivot point or a pivot axis with respect to the contact piece K4 of the bridge T, Y. The bridge T3 is pressed with its contact piece K4 against the fixed contact piece K. by the contact pressure spring F2 fixed to the housing. The bridge T3 is connected to the fixed contact piece carrier T, also connected via a flexible current band S. The contact bridge T3 is driven via a suitable drive lever 1, which is hinged to the bolt 3 of the bridge T3 with an elongated hole 2. A contact compression spring F1 is connected between the drive lever 1 and the bolt 3 .

To increase the contact pressure when current flows, is between the fixed contact piece carriers T1 and T2 in the immediate vicinity of the contact bridge T3 is a ferromagnetic body arranged in the form of an iron plate E. Instead of this iron plate E could be also another suitable arrangement for increasing the contact pressure when current is flowing, z. B. attach another parallel contact bridge within the contact device.

The contact pieces K1 and K3, between which the cut-off arc is drawn, current loops can be used in a manner known per se for the better Assign arc behavior. In the illustrated embodiment, the fixed contact piece is a carrier T1 bent into a current loop, and the free end of the contact bridge is accordingly T .; executed bent. Suitable, Assign arc extinguishing devices, not shown.

With the free end 4 of the contact bridge T3, ie in the area of the movable contact piece K3, an additional mass M is connected with the interposition of the springs F3, F4 and F; elastically coupled.

The coupling of the mass M on the side facing the contact piece K3 take over the springs F4 and F "while the spring F3 on the contact piece K3 facing away from the mass M on a serving as an abutment with the contact bridge T3 firmly connected arm 5 is attached. The coupling springs F3, F4 and F5 are expediently designed as tension-compression springs. The additional mass is preferably made made of non-magnetic material so that there is a magnetic coupling with the contact bridge T3 and the iron plate E is avoided.

If the contact bridge T3 is moved from the illustrated switch-off position to the Switch-on position is moved, then after contact has been made with the contact piece K .; with the contact piece K, the contact piece K3 so long as a result of the inertial force the additional mass M pressed against the contact piece K1 until the resulting when current flows electrodynamic forces achieve a sufficient contact pressure reinforcing effect to have. The following processes take place here in detail.

During the pivoting movement of the contact bridge T.3 in the direction of the fixed contact piece K1, the spring F3 is initially tensioned due to the inertia of the mass M. Only in the further course of the movement is the mass accelerated, and when the contact piece K3 hits the contact piece Ki, the mass continues to oscillate in the direction of the contact piece K1, so that the spring F3 is elongated and the springs F4 and F; be squeezed. Here, a slight rolling movement can occur between the contact pieces K1 and K3, against the force of the contact compression springs F1 and F2, whereby the contact piece K4 can move a little away from the contact piece K2, but this is irrelevant since the contact piece K4 with the contact piece bone is also connected via the current band S. The spring constant of the springs F2 to F3 and the size of the mass M are expediently chosen so that the mass M does not swing back after successful contact closure until the magnetic field has built up around the contact bridge T3 and in cooperation with the iron plate E. a sufficient contact pressure-amplifying electrodynamic force results. This fact is from Fig. 6 can be seen in more detail, where P denotes the course of the contact pressure-intensifying forces and 1 denotes the course of the current over time after the switch-on process. The course of the current obeys an exponential function according to the relationship. , The forces that increase the contact pressure are proportional to the square of the current intensity, corresponding to the relationship P = 12 - const. Therefore, a curve results for curve P which can be determined by squaring curve 1 and multiplying by a constant value. At time t2, the electrodynamic forces P have reached a size at which a swinging back of the additional mass M can no longer have a disadvantageous effect on the contact.

In Fig. 2 shows a contact device in which the free End 4 of the contact bridge T3 firmly connected to the additional ground M, d. H. through the Mass M is extended beyond the contact piece K3, that the contact piece K3 a rolling movement on the associated fixed contact piece during the switch-on process K1, against the force of the contact compression spring F2 and against the force of another between the drive lever 1 and the bolt 3 engaged spring F1 executes. The the F i g. 1 corresponding parts are provided with the same reference numerals. When switching on, the same processes take place as in the case of F i G. 1 shown embodiment, there is only the difference, that the inertial force of the additional mass in a pure rolling motion between the contact pieces K1 and K3 is implemented, the contact piece K4 from the contact piece KZ, in particular against the force of the springs F, .2, removed and after a certain Time swings back again. The time at which the contact piece swings back K4, d. H. in particular the impact of the contact piece K4 on the contact piece K2 is again selected so that the contact pressure-intensifying forces are sufficient Have reached strength, d. H. thus; - the time t2 from FIG. 6th

One or more of the springs F1 to F5 are expediently provided with damping devices provided in such a way that the oscillation process of the mass M after it has been switched on can be abbreviated.

The advantages of the contact device according to the invention are derived from F i g. 3 to 5 can be seen without further ado. F i g. 3 shows that in a contact device without additional mass, the known bounce vibrations occur during the switch-on process and therefore the current over time has roughly the course shown.

F i g. 4 shows that these bounce vibrations in a contact device with additional mass, but without electrodynamic forces that increase contact pressure, can be postponed. In Fig. 5 is the mode of operation of the invention Contact device visible, such that by the combined use of a Additional mass with contact pressure-intensifying electrodynamic forces practically none Bouncing strikes of the movable contact piece occur more and, accordingly, the Current I has the steady course shown over time.

Claims (7)

Claims: 1. Contact device which, in addition to the action of contact compression springs when current flows, is subject to the action of contact pressure-boosting electrodynamic forces, characterized in that an additional mass (M) is coupled to the movable contact piece (K3) of a contact piece carrier (4) that during the switch-on process after contact has been made, the movable contact piece (K3) is pressed against the fixed contact piece (K1) as a result of the inertial force of the additional mass (M) until the electrodynamic forces have achieved a sufficient contact pressure reinforcing effect. 2. Contact device according to claim 1, characterized in that the additional mass (M) the one at the free end (4) is assigned to pivotably mounted contact bridge (T3) arranged contact piece, wherein the pivotably mounted end of the contact bridge (T3) with a contact surface (K4) is spring-loaded against a fixed contact piece (K2) forming the pivot axis is. 3. Contact device according to claim 1 and 2, characterized in that the The free end (4) of the contact bridge (T3) is firmly connected to the additional mass (M) in such a way that in particular extended by the mass (M) beyond the contact piece (4) is that the contact piece (K3) makes a rolling motion on your when switching on associated fixed contact piece (K'1) against the force of contact compression springs (F1, F2) executes. 4. Contact device according to claim 1 and 2, characterized in that the mass (M) with the free end (4) of the contact bridge (T3) is elastic, for. B. is coupled with the interposition of springs (F3 to F5). 5. Contact facility according to claim 4, characterized in that the mass (M) on its the contact piece (K3) facing away from the side with one serving as an abutment with the contact bridge Fixed arm (5), extension od. The like. Is elastically coupled. 6. Contact facility according to claim 1 to 4, characterized in that the pivotably mounted end the contact bridge (T3) via a flexible current band (5) with the associated fixed contact piece (K2) is connected. 7. Contact device according to one or more of the aforementioned Claims, characterized in that one or more of the coupling springs and / or the contact pressure springs are provided with damping devices. Considered Publications: Swiss Patent No. 299 058.