The invention relates to a switch unit that forms a circuit breaker, and which includes a contact slide unit comprising a contact slide, a fixed contact piece and a moveable contact piece, and a short-circuit release that, in the event of a short-circuit, acts upon the moveable contact piece by means of a tappet.
The functions of switch units, and more particularly those forming circuit breakers, include the provision of a safe breaking function for, in the event of a short-circuit, protecting both consumers and installations. Electrical or mechanical switch units are also suitable for the in-service manual switching of consumers, and for the safe isolation of an installation from the power grid for conduct of maintenance work or modifications to the installation. Electrical switch units are often electromagnetically operated.
Switch units of this type are accordingly highly-engineered electric switching devices with integrated protection for motors, cables, transformers and generators. They are employed in functional locations where a low frequency of switching is required. In addition to short-circuit protection, switch units of this type are also suitable for providing overload protection.
In the event of a short-circuit, an electrical switch unit safely disconnects an electrical installation. Fuse protection against overload is also thereby provided. Every conductor in which an electric current flows will heat up, to a greater or lesser extent. Such heating-up is dependent on the ratio of the current rating to the conductor cross-section, i.e., the “current density”. The current density must not be excessively high, or excessive heat-up would otherwise result in charring of the conductor insulation or the possible start of a fire. In order to protect electrical installations against these damaging effects, switch units are employed as overcurrent protection devices.
Circuit breakers are provided with two independently-acting release mechanisms for overload and short-circuit protection, connected in series. Short-circuit protection is assumed by a virtually instantaneously-acting electromagnetic release. In the event of a short-circuit, the electromagnetic release immediately releases a latching mechanism of the circuit breaker. A switching armature separates the contact piece before the short-circuit current can reach its maximum value.
Known switch units comprise a contact slide unit with a contact slide and a moveable contact piece. The moveable contact piece is furthermore provided with electrical contacts. Switch units of this type are additionally provided with first contacts to a current conductor. In its closed state, the electrical contacts of the moveable contact piece are in contact with the fixed contacts of the switch unit. In the event of a short-circuit, the electrical contacts of the moveable contact piece are released from the fixed contacts, thereby interrupting the flow of electric current. The moveable contact piece is thus released or disengaged from the fixed contacts. In the event of short-circuit tripping in a switch unit, however, the moveable contact piece may be caused to rotate about its longitudinal axis after the moveable contact piece is released. Where the moveable contact piece rotates about its longitudinal axis, it is designated a rotating bridge element. In other words, following its rotation, the moveable contact piece does not return to its original position, but instead remains in its rotated position.
In many cases, known contact slides of contact slide units are provided with two guide systems, namely, an internal guide system and an external guide system. The external guide system is employed where the switching process, i.e. the making or breaking operation, is executed by means of a latching mechanism of the switch unit. In this case, no rotating bridge element results. The internal guide system is employed in the event of a short-circuit, if the switching process is executed by means of a switching armature, generally a tappet, on the switch unit. This means that, in the event of disconnection in response to a short-circuit, the moveable contact piece precedes the contact slide along the internal guide system, rebounds against the impact surfaces provided in the lower part of the switch unit and is then propelled back along the internal guide system. Accordingly, it is propelled in the opposing direction relative to the switching armature or tappet of the switch unit. It is therefore possible that the moveable contact piece and the tappet engage outside their respective mid-lines, thereby resulting in the rotation of the moveable contact piece around its longitudinal axis.
Upon the next switching operation of the switch unit, if the moveable contact piece remains in its rotated position, the contacts, specifically silver contacts of the moveable contact piece, will no longer engage with the fixed contacts of the switch unit, thus resulting in malfunctions. This means that the contact piece remaining in a rotated position is disadvantageous, in that the switch unit will then no longer be serviceable. A non-functioning contact piece and a non-functioning switch unit are disadvantageous for both the electrical consumer and the installation in which the switch unit is installed.
A further problem arises where, in the event of a short-circuit, the circuit breaker does not sufficiently rapidly interrupt the short-circuit current. Three time-staggered contact-opening mechanisms are employed for this purpose. A short-term and transient opening of contacts in response to a current flow is effected, first, by the application of current loop forces on the contact position between the fixed and moveable contact pieces and, second, by means of a pin that is electromagnetically driven by the short-circuit release. The permanent opening of contacts is effected by a disengageable mechanical kinematic chain, in combination with a switching lever.
It is accordingly problematic that if such high short-circuit currents occur, the time sequence of the contact-opening mechanisms no longer functions. In this case, the very high current loop forces present result in correspondingly rapid acceleration of the moveable contact piece, which will then rebound so rapidly from the limit stop of the housing that the contact will be reclosed before the latching mechanism can be maintained in the permanently open position by means of the switching lever. The destruction of the device may then ensue.
Accordingly, it is an object of the present invention to provide a switch unit that, even in the event of high short-circuit currents, will ensure reliable execution of the desired chronological sequence of contact-opening mechanisms.
In accordance with the invention, this object is fulfilled by a switch unit, as in the form of a circuit breaker, that includes a contact slide unit comprising a contact slide, a fixed contact piece and a moveable contact piece, and a short-circuit release that acts in the event of a short-circuit upon the moveable contact piece by means of a tappet.
The invention is characterized in that the switch unit further includes a moveable brake or braking device that is designed such that, in the event of a short-circuit, the moveable braking device dampens the return motion or movement of the rebounding moveable contact piece.
To this end, the invention exploits the physical principle of the exchange of energy associated with the impact of two bodies. In the event of a collision between two bodies, the velocities thereof will change in accordance with their relative masses. The contact piece rebounding from the housing collides with a mass. Accordingly, the velocity of the contact piece is significantly slowed, and consequently the time interval to its return arrival at the circuit-reclosing fixed contact position is extended. This time delay is sufficient for the latching mechanism to complete the path required for the permanent achievement of the minimum contact breaking gap.
In a particularly advantageous embodiment, the moveable contact piece may be guided on a guide element, wherein the moveable brake device is arranged above the moveable contact piece and at the upper end of the guide element. In accordance with the invention, the guide element is preferably configured as a guiding pin, and comprises a zone of substantial mass. The center of gravity is arranged above the moveable contact piece. Further to the current-driven disengagement of the contact piece by the tappet of the short-circuit release, the mass is displaced into the rebound path of the contact piece. The inevitable collision with the contact piece that is present on the rebound path is sufficient to generate the requisite time delay. This embodiment is advantageous in that installation is straightforward, and a guide function for preventing rotation of the bridge is also provided.
The moveable brake device may also be configured as a mass in the form of a flat punched metal element produced by die-stamping. This specific form of construction is advantageous in that die-stamped components are more cost-effective. Moreover, the flat profile of the metal element reduces the isolating distance between the two switching poles, i.e. the conducting side and the isolating side, far more effectively than an asymmetrical rotary element of equal mass. The installation space required is, moreover, reduced accordingly.
In a further implementation of the above-described embodiment, a further moveable brake device may be arranged additionally at the lower end of the guide element. Thus, in addition to the first mass, a second mass is positioned below the moveable contact piece. The two masses are interconnected to form a double mass, preferably by means of an opening in the switching bridge, and are also arranged for axial displacement in the contact opening direction. In the event of a current-driven opening of the contact bridge, the switching bridge, in its opening movement against the action of the contact load spring, will initially collide with the mass arranged below it, thereby accelerating the latter and reducing its own speed.
The bridge and the double mass are propelled to the limit stops of the housing, which may be different, and rebound therefrom. Advantageously, the housing limit stop of the double mass is further removed from the contact point than that of the contact bridge. As a result, the bridge will already be on its return trajectory and will collide once more with the still outwardly-moving double mass, thereby giving up a further proportion of its kinetic energy and further decelerating the bridge. The pre-tensioned contact load spring moves both elements back in the direction of contact. The advantage of this implementation of the invention stems firstly from its large speed damping capability, and secondly from the guide function of the bridge which prevents rotation.
In a further advantageous embodiment, the moveable brake device is arranged on the tappet of the short-circuit release. This implementation of the invention is characterized by its extreme ease of installation.
The switch unit according to the invention comprises a contact slide unit, with a contact slide as well as a fixed contact piece and a moveable contact piece, which are arranged opposite each other. A tappet of a short-circuit release is arranged above the contact slide unit. In an advantageous embodiment, a tubular extension is formed on the end of the tappet that faces the contact slide, the extension being either integral with the tappet or molded onto the tappet as a separate component. The tubular extension corresponds to or forms a part of the mass which forms the braking device.
The moveable contact piece is provided with an opening, in which the guide element is positioned. The guide element preferably comprises, above the moveable contact piece, a braking device that is implemented in the form of a mass. Preferably, a further additional mass can also be arranged, as a braking device, below the moveable contact piece on the guide element. In the event of operative tripping, the tappet of the short-circuit release moves in the direction of the moveable contact piece.
The invention is characterized in that, by the positioning of at least one additional mass which acts as a braking device, an exchange of energy results from the collision of two bodies, thereby reducing the speed of the moveable contact piece. The additional masses for the brake device according to the invention, in at least in some embodiments, are arranged on the guide element that guides the moveable contact piece. By this arrangement, the guide element fulfills a dual function. Firstly, it acts as a braking device that reduces the speed of the rebounding moveable contact piece in the event of tripping. Secondly, the guide element guides the moveable contact piece so as to reliably prevent any unintended rotation of the moveable contact piece resulting from the delivery of a high impulse of motion. Accordingly, even in the event of high short-circuit currents, the switch unit of the invention permits reliable execution of the chronological sequence of contact-opening mechanisms.
Further advantages and embodiments of the invention are described in greater below with reference to exemplary embodiments and to the accompanying drawings.
In the drawings:
The center of gravity of the mass 8 lies above the moveable contact piece 3. Below moveable contact piece 3, the guide element 7 may be guided either in the housing 9 or in the contact slide 1, or in a combination of housing 9 and contact slide 1.
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The present invention is characterized in that, by the positioning of at least one additional mass that serves as braking device, an exchange of energy results from the collision of two bodies, thereby reducing the moving speed of the moveable contact piece. The additional masses for the braking device, in at least two embodiments herein disclosed, are arranged on the guide element that guides the moveable contact piece. By this arrangement, the guide element fulfills a dual function. Firstly, it acts as a braking device that reduces the speed of the rebounding moveable contact piece in the event of tripping. Secondly, the guide element guides the moveable contact piece such that any rotation of the latter due to the delivery of a high impulse of motion can be reliably prevented. Accordingly, even in the event of high short-circuit currents, a switch unit constructed in accordance with the present invention permits reliable execution of the chronological sequence of contact-opening mechanisms.
Number | Date | Country | Kind |
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13184489 | Sep 2013 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/064568 | 7/8/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/036143 | 3/19/2015 | WO | A |
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Number | Date | Country | |
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20160203921 A1 | Jul 2016 | US |