EP0279363A2 - Circuit breaker for fault current protection - Google Patents

Abstract

In known circuit breakers for fault current protection, a great deal of space is taken up by the arrangement of the switching contacts on the base plate and their operation by means of a switching slide provided with bridging contacts. The transmission elements of the switchgear required for operating the switching slide result in an increased force being required to release the switch lock, because of the friction forces occurring in this case. By means of the design with contacts 36, 37 arranged side-by-side, the space requirement for the circuit breaker for fault current protection is reduced. A newly designed switchgear with a support 14 on the latching lever 10 for a supporting lever 12 reduces the forces required for release; in addition, a switching cam 47 prevents overloading of the test current circuit provided for testing the release function. The new type of circuit breaker for fault current protection is advantageously suitable for use in domestic meter installations. <IMAGE>

Description

The invention relates to a residual current circuit breaker according to the preamble of protection claim 1.

Residual current circuit breakers are widely used today and are used to deenergize consumer systems when fault currents occur on the electrical conductors.

A residual current circuit breaker has become known from DE-AS 25 08 428, in which the switching contacts are arranged in a plane at the rear and are actuated via a switching slide provided with contact bridges. The arrangement of the switching contacts on the switch base takes up considerable space, since the switching paths of the contact bridge are correspondingly large in view of the required distance from the fixed contacts.

Based on this prior art, it is an object of the invention to provide a residual current circuit breaker of the type mentioned, which is simple in construction, requires little space, is inexpensive to manufacture and is reliable in operation.

The object is achieved by the characterizing features of the protection claim 1. Further advantageous refinements and improvements of the invention are specified in the subclaims.

The residual current circuit breaker designed according to the invention has four contact points arranged next to one another in a common switching plane in the base of the housing, which are each formed by a fixed and a movable contact. The movable contacts are guided in a switching shaft made of insulating material in the form of a flying bearing and each acted upon by a contact spring, which ensures that the movable contacts are always in contact with the fixed contact and thus possible switching path differences of the contacts, e.g. B. due to contact wear due to erosion or wear.

The floating mounting of the movable contact in conjunction with the contact spring enables each individual movable contact to adjust itself automatically. It is advantageous to arrange the point of contact of the contact spring on the lever arm of the movable contact opposite the contact point, so that the contact spring is always tensioned in the switched-on state and is always relaxed in the switched-off state. According to a special embodiment of the residual current circuit breaker, the contact springs are designed as tension springs, which are each supported on the rear walls of switching chambers provided with arc extinguishing plates.

Another characteristic feature of the invention relates to the configuration of the test device for functional testing of the residual current release. A test circuit, which has a resistor, is used in a known manner for this purpose as a test load. A test button, which has a tongue contact, which contacts one of the movable contacts when actuated, is used to activate the trigger.

In order to protect the test circuit and in particular the resistor from overloading and thus from damage, a switching cam is formed on the selector shaft which, when the selector shaft rotates - as a result of the triggering of the switching mechanism - swivels into the contact plane of the contacts, presses against the tongue contact and thereby prevents him from contacting the assigned counter contact.

Depending on the arrangement of the tongue contact, it may be advantageous to provide the switch cam with a roof-shaped projection which slides between the contacts when the triggering has taken place and the switch shaft has been pivoted so far that the movable contacts have assumed the switch-off position.

According to the invention, the switching mechanism has a support which reduces the triggering force and which absorbs the switching force required to act on the movable contacts or the switching shaft from a carrying lever. This support is provided on the ratchet lever, which forms the latching point with a release lever.

The support is arranged in such a way that the pawl lever is latched to the release lever with much less force than without such a support because of its large lever arm. As a result, less force is required to actuate the release lever and to open the latch, ie the residual current release required for triggering can be made smaller and thus more sensitive.

When the latch is opened, the latch lever releases the carrying lever that was previously held by the support.

The invention, advantageous refinements and improvements of the invention are to be explained and described in more detail with reference to the drawing, in which an exemplary embodiment of the invention is shown.

• Figur 1 Das mechanische System im Zustand: eingeschal­tet
• Figur 2 das mechanische System im Zustand: ausgelöst
• Figur 3 das mechanische System im Zustand: ausgeschal­tet
• Figur 4 eine Kontaktanordnung mit Kontaktfeder im Zu­stand: eingeschaltet
• Figur 5 eine Kontaktanordnung mit Kontaktfeder im Zu­stand: ausgeschaltet
• Figur 6 einen Querschnitt durch eine Schaltwelle mit beweglichem Kontakt und Zungenkontakt im Zu­stand: eingeschaltet
• Figur 7 einen Querschnitt durch eine Schaltwelle mit beweglichem Kontakt und Zungenkontakt im Zu­stand: ausgeschaltet
• Figur 8 einen Fehlerstromschutzschalter in Seitenan­sicht (geschnitten)

Show it:

• Figure 1 The mechanical system in the state: switched on
• Figure 2 shows the mechanical system in the state: triggered
• Figure 3 shows the mechanical system in the state: switched off
• Figure 4 shows a contact arrangement with a contact spring in the state: switched on
• Figure 5 shows a contact arrangement with a contact spring in the state: switched off
• Figure 6 shows a cross section through a control shaft with movable contact and tongue contact in the state: switched on
• 7 shows a cross section through a control shaft with movable contact and tongue contact in the state: switched off
• Figure 8 shows a residual current circuit breaker in side view (cut)

The mechanical system of the switching mechanism of the residual current circuit breaker according to the invention shown in FIG. 1 has a ratchet lever 10 which is pivotably mounted in a rotary bearing 20 and forms a latching point 18 with a release lever 16. The release lever 16 in turn has a pivot bearing 22 which, like the pivot bearing 20, is designed as a fixed bearing.

A support lever 12, which is pivotably mounted in a pivot bearing 24 and is connected to a support lever 30 via a swivel joint 25, is supported on the ratchet lever on a support 14 and thereby transmits the switching force introduced via a support lever 30 from a knee joint 28 of a knee joint lever 32 Actuation of the switch.

The knee joint lever 32 is connected above the knee joint 28 to a manual control element (not shown in more detail - this lever arm was only indicated for reasons of clarity), while the lower part of the knee joint lever 32 is guided to a joint 29 which belongs to a movable contact 36 which is pivotally mounted in a pivot bearing 26. The movable contact 36 has at its free end a contact piece 38, which consists of an arc-resistant material and acts on a fixed contact 37, which is also equipped with an arc-resistant contact piece 39.

The movable contact 36 is connected to a connecting terminal 46 via a preferably flexible conductor 44, while a conductor 43 designed as a rail is guided from the fixed contact 37 to a connecting terminal 42.

With the exception of the already mentioned rotary bearings 20, 22, 24, 26, which are arranged in a stationary manner in the housing, the remaining rotary joints 25, 28, 29 are each arranged in a variable position on pivoting levers 30, 32, 36.

The arrangement shown in Figure 1 shows the switching mechanism in the "switched on" state. For a better understanding of the function of this switching mechanism, the relevant forces are shown by arrows. In the switched-on state of the switching mechanism, both the movable contact 36 is acted upon by a force F1 and the toggle lever 32 is acted upon by a force F2, which is initiated by the manual actuation element, not shown. This results in a force F which acts in the knee joint 28 and thereby tries to pull the knee joint lever 32 upwards, which is initially prevented by the support lever 30, which in turn acts on the support lever 12, which in turn is supported on the support 14. The resulting force F is directed towards the support lever and tries to pull the knee joint 28 outwards and to bend the knee joint lever 32.

Furthermore, it can be clearly seen in the illustration shown in FIG. 1 that in the switched-on state the connection of the joints 24, 25, 28 almost form a straight line, so that the torque about the fulcrum 24 via the carrying lever 12 is comparatively high due to the effective lever arm is low. However, this means that a force transmission has already been achieved here, so that the supporting force which the carrying lever 12 in the support 14 transmits to the ratchet lever is already smaller than the switching force F required to actuate the switching mechanism.

Figure 1 also shows that the support 14 is arranged at a short distance from the pivot joint 20 of the ratchet lever 10 and that the lever arm from the pivot joint 20 to the latching point 18 is a multiple of this distance. The result of this is that the force held in the latching point is in turn significantly lower due to this lever arm than the supporting force which is introduced into the support 14 by the carrying lever 12.

The aforementioned forces are preferably applied with the aid of springs which are designed both as compression or tension springs and as torsion springs, in particular the torsion springs enable space-saving use.

The representation of the switching mechanism shown in FIG. 2 shows the switching state "triggered", i. H. an intermediate position, in which the contact point formed from the contacts 36, 37 is open, as is the latching point 18. After the release lever 16 is actuated and releases the latching, the latching lever 10 pivots under the influence of those introduced from the carrying lever 12 into the support 14, Force upwards and releases the support lever 12 almost instantaneously, so that the knee joint 28, as already explained in the explanations for FIG. 1, deflects from its position and thereby releases the movable contact 36 from the fixed contact 37. The further details have already been explained in FIG. 1, so that their further description can be omitted here.

In Figure 3, the switching mechanism is shown in the "switched off" state. The pawl lever 10 is latched in the latching point 18 on the release lever 16. The other parts of the switching mechanism, on the other hand, are unstressed, ie the movable contact 36 is open and the support lever 12 is lifted off the support 14.

When the manual control element, which is not shown in more detail in this illustration, and which adjoins the upper part of the toggle lever 32, which is shown only in sections in this illustration and also in FIG. 2, is moved, the knee joint 28 moves in the direction of the contact point 40, pulling over the Support lever 30 the support lever 12 to the support 14 and finally reaches the lever position known from Figure 1.

FIG. 4 serves for a more detailed explanation of the flying bearing 31 of the movable contact pieces 36, which are guided in a switching shaft 35 which can be pivoted about a pivot point 26 under the action of the toggle lever 32 acting in the swivel joint 29. In the arrangement shown in FIG. 4, the flying bearing 31 is formed from two opposite tips, between which the movable contact 36 is arranged. The lower part of the movable contact 36 belongs to the contact point 40; the upper part of the movable contact 36 is acted upon by a spring 33. As Figure 4 shows, the spring 33 is tensioned, i. H. a force acts on the upper lever arm of the movable contact 36, which ensures that the lower part of the movable contact is pressed against the fixed contact 37 due to the support in the fly bearing 31.

In this example, the control shaft 35 is provided with an L-shaped formation in which the floating bearing 31 for the movable contact 36 is placed.

Figure 5 shows the same arrangement as in Figure 4 but in the open position of the movable contact 36, in which the contact spring 33 is relaxed.

The arrangement shown in FIG. 6 shows the selector shaft 35 with the movable contact 36 guided therein, which is contacted at its upper end by a tongue contact 48. The tongue contact 48, the rest position of which is shown in dashed lines, is designed as a leaf spring and belongs to a test button, not shown in detail.

The control shaft 35, which is shown in cross-section in this illustration as a circular cylindrical body, has a control cam 47 which, as shown in FIG. 6, is positioned laterally next to the upper end of the movable contact 36 in the switched-on position of the movable contact 36. The selector shaft 35 is arranged rotatably about a fulcrum 26, the toggle lever 32 engaging in a further swivel joint 29, which leads to the switching mechanism.

FIG. 7 shows the arrangement known from FIG. 6 in the switched-off position, the switching shaft 35 being rotated about the swivel joint 26, so that the switching cam 47 comes directly under the contact point of the tongue contact 48 and thereby prevents contacting of the movable contact 36. With the selector shaft 35, the movable contact 36 is also pivoted, but due to the floating bearing 31 at a different angle than the selector shaft 35. The further details provided with reference numerals correspond to the features known from the previous figures and therefore do not need to be explained in more detail here .

FIG. 8 shows a somewhat schematic side view of a residual current circuit breaker according to the invention in section, details which are not important for the invention being omitted.

The residual current circuit breaker according to the invention is arranged in a housing 51 which is formed from a base 50 and a cover 52. In the base 50, connecting terminals 42, 46 are arranged on both sides, which are connected to the contacts 36, 37 via electrical conductors 43, 44. The contacts 36, 37 are arranged side by side in specially assigned switching chambers which are sealed off from one another by chamber walls 53, so that only one pair of contacts 36, 37 can be seen in this illustration. The contact arrangement shown in this illustration consists of a movable contact 36, which is guided in a switching shaft 35 and is equipped with a contact piece 38 made of arc-resistant material, and a fixed contact 37, which leads via a conductor rail 43 to the connecting terminal 42 and on it free end also has a contact piece 39 made of arc-resistant material.

The selector shaft 35, which rotates about the rotary bearing 25, has cylindrical extensions for each movable contact 36, in which the movable contact 36 is guided and which have recesses on the side facing away from the fixed contact 37, through which the contacts with the movable contact 36 connected flexible conductor 44 and the contact spring 33 are guided. The design of the control shaft 35 also uses a floating bearing for the movable contact 36. The function of the contact spring 33 has already been explained, so that it is not necessary to go into this here. The conductors 44 lead from the movable contact 36 via a housing intermediate wall 55 forming the rear wall of the switching chamber into a main chamber 57 of the housing 51.

The main chamber 57 in the housing 51 essentially serves to accommodate a summation current transformer 54, through which the conductors 44 are led to the connection terminals 46.

The summation current transformer 54 is designed in a known manner and is connected via an electrical double conductor 59 to a tripping unit 56 which is arranged in the cover 52 of the housing 51. The release unit 56 can be a magnetic release of a known type, which may additionally include an electronic amplification or Has delay circuit. The tongue contact 48 is also connected to the trigger unit 56 and can be acted upon by means of a test button 49 which is guided through the cover 52 from the outside. As can be seen from FIG. 8, the switch is in the “switched off” state, in which contacting of the tongue contact 48 with the movable contact 36 assigned to it is prevented due to the protruding position of the switching cam 47.

A switch toggle 58 serving as a manual actuating member 58 is arranged on the top of the housing 51 next to the test button 49 and engages with the switching mechanism hidden by the triggering unit 56 in this view. The only feature of the rear derailleur is the lower part of the toggle lever 32, which is connected to the selector shaft 35.

At the bottom of the housing 51, i. H. On the outside of the base 50, a recess 60 is provided, which is used for attachment to a holding rail, not shown here, preferably on a top-hat rail, and for this purpose has an oblique edge 64 and a locking slide 64 on the opposite side of the recess 60.

The residual current circuit breaker according to the invention is designed to be very space-saving compared to known designs due to the design with contact points 40 arranged next to one another in switching chambers and enables there good utilization of the often scarce space available in the meter spaces. The design of the new rear derailleur with multiple translation of the forces required for actuation via the support lever 12 to the support 14 on the ratchet lever 10 allows the use of smaller tripping units, the sensitivity of which is increased without additional effort insofar as even small fault currents generate the forces required for tripping . The equipment of the control shaft 35, in which the movable contact 36 is guided in a floating bearing 31, with the control cam 47 also helps to reduce the manufacturing costs, because this means that the load resistor switched into the test circuit, which would otherwise be required, is dimensioned to make it permanently current-proof to make, can be omitted, since the closing of the test circuit is prevented by the switching cam 47 when the residual current circuit breaker is switched off.

Claims (9)

1. Four-pole residual current circuit breaker in a housing formed from a base with a cover with a switching mechanism that has at least one latching point, each with a switch pole associated contact points, each having a fixed and a movable contact, with a residual current release and with a test button, which when actuated it closes a circuit for functional testing of the residual current release, characterized in that the contact points (40) are arranged side by side in a switching plane in the base (50) of the housing (51), that the movable contacts (36) in a switching shaft (35) guided in the form of a flying bearing and each acted upon by a contact spring (33) which ensures constant contact force that the switching mechanism has a support (14) which receives the switching force required to actuate the switch and via the lever arm of a ratchet lever (10 ) with the latching point ( 18) is coupled, whereby the release force for unlatching corresponding to the lever arm is smaller than the switching force, and that the test button (49) is arranged in the cover (52) of the housing (51) and has a tongue contact (48) which is connected to a the movable contact (36) works together. 2. Residual current circuit breaker according to claim 1, characterized in that the switching shaft (35) consists of insulating material and has a switching cam (47) which is pivoted with the switching shaft (35) in such a way that the movable shaft (35) is open so that the Tongue contact (48) is applied to the switching cam (47) and an electrical connection of the tongue contact (48) to the associated movable contact (36) is prevented. 3. Residual current circuit breaker according to one of the preceding claims, characterized in that the switching shaft (35) is rotatable about an axis of rotation (26) which is arranged above the bearing axis of the floating bearing (31) of the movable contacts (36). 4. Residual current circuit breaker according to one of the preceding claims, characterized in that the switching shaft (35) with one end in a recess of the switching mechanism and with its other end by a molding in the cover (52) of the housing (51) is adjustable. 5. Residual current circuit breaker according to one of the preceding claims, characterized in that the contact springs (33) engage above the bearing axis of the floating bearing (31) on the movable contacts and are tensioned when the contacts (36, 37) are closed. 6. Residual current circuit breaker according to one of the preceding claims, characterized in that the contacts (36, 37) are each provided with a contact piece (38, 39) made of arc-resistant material. 7. Residual current circuit breaker according to one of the preceding claims, characterized in that the switching mechanism has a carrying lever (12) which transmits the switching force required to actuate the switch to the support (14) which is pivotable about a pivot bearing (20) pawl lever ( 10) is formed, which forms the latching point (18) with a release lever (16) and that the lever arm between the pivot bearing (20) and the latching point (18) is a multiple of the distance of the support (14) from the pivot bearing (20). 8. Residual current circuit breaker according to claim 7, characterized in that the pivotable about a fixed bearing (24) support lever (12) via a support lever (30) with a knee joint (28) of a knee joint lever (32) formed from two levers is articulated to the Switching force is transmitted from a manual actuator (58) to the selector shaft (35). 9. Residual current circuit breaker according to claim 8, characterized in that when the switching mechanism is tensioned, the connecting line of the knee joint with the fixed bearing (24) and the swivel joint (25) is aligned almost rectilinearly, the support lever (30) not resting on the fixed bearing (24).

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