EP0660965A1

EP0660965A1 - Push-button actuated safety switch.

Info

Publication number: EP0660965A1
Application number: EP93919012A
Authority: EP
Inventors: Konrad Heydner; Oswald Onderka
Original assignee: Ellenberger and Poensgen GmbH
Current assignee: Ellenberger and Poensgen GmbH
Priority date: 1992-09-19
Filing date: 1993-09-17
Publication date: 1995-07-05
Anticipated expiration: 2013-09-17
Also published as: EP0660965B1; JP2904928B2; DE59306131D1; US5558211A; WO1994007255A1; ATE151565T1; DE9321289U1; JPH07507656A

Abstract

A protective switch having an actuation side. The protective switch includes a base having walls, a pivot shaft connected to the walls of the base, and a switching rocker pivotal on the pivot shaft to be pivotally seated on the base. The switching rocker includes two lever arms for switching the protective switch on and off. A housing is placed on the base and protectively surrounds the switching rocker. A housing cover is located on the actuation side of the protective switch and protectively covers the switching rocker. The housing cover includes an opening therethrough. A plurality of hinges are each disposed on a respective lever arm of the switching rocker. An actuation attachment extends through the opening of the housing cover and is modularly connected to the switching rocker by the hinges for pivoting the switching rocker. The actuation attachment is selected from a kit composed of at least one switch button longitudinally displaceable in the housing cover and pivotally connected with one of the lever arms, and a switch cap rotatably movable relative to the pivot shaft and rigidly connected with the two lever arms of the switching rocker. The at least one switch member and the switch cap are interchangeable.

Description

Push button operated circuit breaker

The invention relates to a circuit breaker with the features of the preamble of claim 1.

Such circuit breakers are known from US 4083027 and from GB 745744. The circuit breakers have a bimetallic switching mechanism to switch off the circuit breaker in the event of overcurrent. The switching mechanism is articulated to a rocker switch. It is designed as a two-armed lever. Each of the two lever arms is articulated with a separate button. The switching mechanism can be controlled via the rocker switch by pressurizing the switch buttons. As a result, the circuit breaker can be switched on or off manually as required.

For safety reasons, however, it may be necessary to only equip the rocker switch with a single switch button so that the circuit breaker can only be switched on manually, but not switched off.

In addition, it may be necessary in the event of a changed customer request not to equip the rocker switch with two switch buttons, but rather to be able to actuate it directly as a one-piece part for switching the circuit breaker on and off. Circuit breakers with such a rocker switch are known from DE 29 28277 C2 (= US 4329 669) and from DE 2721 162 C2. The bimetallic circuit breakers known there can be switched on and off manually by means of the one-piece rocker switch protruding from the housing cover.

It is disadvantageous, however, that if the customer wishes to change the design and actuation of the rocker switch, the entire circuit breaker must be replaced, since all known circuit breakers either have only a one-piece rocker switch or a rocker switch with two separate switch buttons. As a result, components of the circuit breaker that could actually be retained are also replaced, e.g. the entire switching mechanism. Replacing the rocker switch is therefore very expensive.

Based on these disadvantages, the invention has for its object to provide a circuit breaker of the type mentioned so that it is simple and can be adapted to the various options for manual actuation of the rocker switch.

This object is achieved by the combination of features of claim 1. According to this solution, the entire rocker switch is constructed in several parts. The two-armed lever forming the actual rocker switch is not actuated directly. It is completely covered by the switch housing and therefore protected against mechanical damage. Depending on individual needs, a switch hood or a switch button is placed on this lever. Only the housing cover has to be adapted to the outline shape of the respective attachment part for its switching movement with a corresponding housing opening. The number of components to be replaced for changing the manual actuation of the rocker switch is therefore greatly reduced. Different shift paddle assemblies can therefore be implemented with one and the same circuit breaker assembly. This saves material and is inexpensive.

It is conceivable that the housing cover is made in one piece with the rest of the housing. In this case, the housing is replaced when the shift paddle actuation is changed.

The switching hood acts as a spatial extension of the rocker switch beyond the opening in the housing cover. This two-part construction of the entire rocker switch acts mechanically like the conventional one-piece rocker switch. The switching rocker can be actuated by means of the switching hood, such as the switching rocker known from DE 29 28277 C2 (= US 4,329,669) and from DE 27 21 162 C2.

In order to prevent mistakes when operating the rocker switch, in which the circuit breaker is accidentally switched over, the switching hood can be replaced if necessary with a switch button. Equipping the rocker switch with just a single button is an advantage for certain safety applications. It is conceivable that the circuit must not be interrupted by manually operating the circuit breaker. In this case, the circuit breaker only has a switch button for switching it on manually.

Since only the components mentioned are replaced when the entire rocker switch is modified, the switching mechanism is retained with its characteristic tripping time for interrupting a circuit. The bimetal, once adjusted, therefore needs to be replaced after the replacement, in contrast to the conventional one Replacement of the entire circuit breaker cannot be set again. This also reduces the overall assembly and setting effort of the circuit breaker.

Such a construction of the rocker switch with an attachment part is suitable for single-pole and also for multi-pole circuit breakers.

A housing opening designed according to claim 2 enables problem-free guidance of the switch button in its longitudinal direction. As a result, the switch button can be designed in a simple manner as a push button and operated by an operator. The longitudinal displacement of the switch button enables effective power transmission to the associated lever arm of the rocker switch. Complicated connections between the switch button and rocker switch for power transmission can therefore be avoided.

Claim 3 relates to a preferred embodiment of the mechanical coupling between the switch button and the rocker switch. The articulated connection causes the power transmission between the two parts. At the same time, the joint also acts as a captive device for the switch button, so that the switching mechanism of the circuit breaker is of compact and mechanically stable design without any significant outlay.

Due to the position of the axes of rotation according to claim 4, the switch button and rocker switch are arranged to save space. All axes of rotation of the switching mechanism are arranged parallel to each other. The lever-like components therefore have the same level of movement as the shift button and rocker switch. This ensures a narrow design of the circuit breaker.

The fulcrum of the lever arm is identical to the shift paddle axis. The hinge axis of the switch button is therefore not shifted exactly in the direction of its longitudinal axis, but on a circular path with a radius corresponding to the length of the lever arm. The deviation of this movement path from the exact longitudinal displacement is reduced to a minimum by the arrangement of the lever arm in its central position. This is a prerequisite for the space-saving construction of the switching mechanism and for the use of the switching button as a push button that can be displaced in its longitudinal axis.

According to claim 5, the switching state of the circuit breaker is well visualized. This also makes it easy to see the switch positions of the switch button be improved that its surface is provided with a particularly striking warning color.

Claim 6 relates to an additional function of the housing cover. A limited swiveling of the rocker switch is useful in order to ensure two defined switch positions of the switch button. The limited pivotability also prevents individual components of the switching mechanism from being damaged or destroyed by an accidentally too large pivoting in their plane of movement. Thus, in addition to its general protective function for the switching mechanism against external influences, the housing cover also has a protective function against excessive force loads on the switching mechanism by an operator.

Claim 7 relates to an expedient embodiment of the rocker switch for an effective limitation of its pivoting mobility. The cover surface of a lever arm that is in full contact with the housing cover during a switching position of the switching rocker causes a good surface pressure of the housing cover on the switching rocker. Such an area-effective limit stop protects the rocker switch from damage or destruction in the event of an excessive force introduced into the rocker switch in the direction of the longitudinal axis of the switch button. The limited swiveling of the switching rocker also relieves the other swiveling parts of the switching mechanism from excessive mechanical stress.

Claim 8 relates to a preferred embodiment of the shaft. Since the switch button and the rocker switch are coupled to one another in an articulated manner, the projections of the shaft additionally cause the rocker switch not to be able to be pivoted further after the switch button has reached the switch position. The entire switching mechanism is therefore protected from excessive mechanical stress by means of the projections. In addition, the projections limit the longitudinal displacement of the switch button so that it always has a clear switching position.

Claims 9 and 10 relate to preferred embodiments of the switch button for good mobility between the switch button and the rocker switch.

Claims 11 and 12 relate to preferred embodiments of the rocker switch for good guidance of the switch button during its switching movements and for its limited pivotability. According to claim 13, the switch button is optionally connectable to one of the two lever arms of the rocker switch. This allows the switch button to be used to manually switch the circuit breaker on or off as required.

The symmetrical structure of the rocker switch according to claim 14 is a prerequisite for a likewise symmetrical structure of the housing or the housing cover. As a result, one and the same housing cover can be used for covering the rocker switch and guiding the movement of the switch button, regardless of the selection of the lever arm assigned to the switch button. Furthermore, the symmetrical design of the rocker switch enables the simple placement of one and the same switch button on one of the two lever arms of the rocker switch.

According to claims 15 to 19, the switching hood is constructed in such a way that it can be assembled with the rocker switch used for the switch button in such a way that the rocker switch and the switching hood are effective together as a one-piece rocker switch. When constructing the shift hood, all structural characteristics of the rocker switch suitable for fixing the shift button are taken into account in such a way that the shift hood is mechanically stably fixed to the shift rocker.

According to claim 15, the rocker switch and the interior of the circuit breaker are well protected against mechanical damage. The immobile fixation is e.g. realized by latching the rocker switch on the switching hood and ensures the joint effect of the rocker switch and switching hood as a one-piece component.

According to claim 17, the two articulated axes of a symmetrically constructed rocker switch, which are already provided for the pivotable mounting of the switch button, are used in a further function as bearing axes for the switching hood. In this way, the immobile mounting of the switch hood is achieved without additional component expenditure.

According to claims 18 and 19, the shift hood is structurally designed at its rocker-side end such that the rocker switch serves as a fixing aid during the mounting process of the shift hood. In addition, the flank protrusions, which are already effective compared to the control knobs, support the immobile mounting of the shift hood. The subject matter of the invention is explained in more detail with reference to the exemplary embodiments shown in the drawings. Show it:

1 is a perspective view of a circuit breaker with two push button-type switch buttons, FIG. 2 is the perspective view of the circuit breaker with a push button type switch button, FIG. 3 is a sectional side view of the circuit breaker according to FIG. 1 in its

4, a sectional side view of the circuit breaker according to FIG. 2 in its

Switch-on position, FIG. 5 is a partial representation of the one in its switch-off position

Circuit breaker according to Fig. 3, Fig. 6 is a partial view of the one in its off position

Circuit breaker according to FIG. 4. FIG. 7 shows the circuit breaker according to FIG. 5, but with a

Switch hood instead of the buttons and adapted to the switch hood

Housing cover.

The known circuit breaker 1 has a housing 2 with a housing cover 3 integrally molded thereon. The housing 2 is made of plastic. When viewed in a height direction 4, the housing 2 has a rectangular outer contour. The narrow sides of the housing 2 run in a transverse direction 5 arranged perpendicularly to the height direction 4. On the two side surfaces of the housing 2 lying in the plane formed by the height direction 4 and transverse direction 5 there are two resilient hooks 6 connected in one piece to the housing 2 for fastening the Circuit breaker 1 molded into a front panel, not shown.

Viewed in the vertical direction 4, the housing cover 3 projects beyond the rectangular outer contour of the housing 2. The vertical housing 4 also has a rectangular outer contour in the vertical direction 4 and lies in a plane formed by the transverse direction 5 and a longitudinal direction 7. Here, the longitudinal direction 7 is arranged perpendicular to the height direction 4 and perpendicular to the transverse direction 5.

A shaft 8 with its shaft height in the height direction 4 is integrally formed on the housing cover 3 for receiving two push buttons 9, 109 which can be actuated in the manner of a push button. The shaft 8 is located in the central area of the housing cover 3. When viewed in the vertical direction 4, it has a rectangular outer contour. It has the shape of a cuboid penetrated in the height direction 4 by two shaft interiors 10, 110. The shaft interiors 10, 110 also have a rectangular outer contour in the height direction 4. Both shaft interiors 10, 110 are dimensioned identically. The two shaft interiors 10, 110 are separated from one another by a dividing web 11 running in the transverse direction 5 and forming a one-piece part of the shaft 8. The separating web 11 bisects the shaft 8 in the longitudinal direction 7.

The shaft interiors 10, 110 each form-fit surround a correspondingly cuboid-shaped actuating end 12, 112 of the switching buttons 9, 109. The height of the actuating ends 12, 112 in the height direction 4 roughly corresponds to the corresponding height of the shaft interior 10, 110 (FIG. 3)

While the actuating end 12 of the switch button 9 projects outward from the shaft interior 10 with the greatest part of its constructional height 4, the actuating end 112 of the switch button 109 is completely covered by the shaft 8 in the height direction 4. The position of the switch button 9 signals the off position of the circuit breaker 1 (Fig. 5). The design of both buttons 9, 109 is identical. For better differentiation of the switching state of the circuit breaker 1, the surfaces of the two switching buttons 9, 109 can be different in color.

1 shows connection contacts 13, 113 and 14, 114 for one circuit each. The circuit breaker 1 is therefore designed as a 2-pole overcurrent protection switch. The connection contacts 13, 113 and 14, 114 can be bridged by the switching mechanism (FIG. 3) arranged inside the housing 2.

With the exception of the shaft 8 and the housing cover 3, the circuit breaker 1 shown in FIG. 2 is identical to the circuit breaker 1 shown in FIG. 1. Only the shaft interior 10 is provided on the shaft 8, so that it only receives the switch button 9. In the area of the shaft 8 receiving the switch button 109 according to FIG. 1, no opening for the shaft interior 110 (FIG. 1) is provided on the housing cover 3 in FIG. 2. At this point, the housing cover 3 is closed by a rectangular shaft closure 15 designed in accordance with the cross section of the shaft interior 110. It is an integral part of the housing cover 3. Since the circuit breaker 1 has only a single switch button 9, it can only be switched on manually (FIG. 4, FIG. 6). In Fig. 2 and in Fig. 6, the circuit breaker 1 is in its off state.

In Fig. 3 the switching mechanism arranged inside the housing 2 can be seen. The individual components of the switching mechanism are carried or supported on a base 16. The design and mode of operation of the switching mechanism are described in detail in DE 2721 162 C2 and in DE 29 28 277.

A rocker switch 17 is rotatably mounted on the base 16 by a rocker switch axis 18. The shift rocker axis 18 extends in the transverse direction 5. The plane of movement of the shift rocker 17 is formed by the height direction 4 and the longitudinal direction 7. The rocker switch 17 is the closest component to the shaft 8 of the known switching mechanism.

In its area facing the connecting contacts 13, 113, an actuating pin 19 extending in the transverse direction 5 is arranged on the switching rocker 17. The rocker switch 17 acts on the latching lever 20 in the manner of a link guide by means of the actuating pin 19. The latching lever 20 acts with a lever end on a contact spring 21 arranged with its longer leg in the longitudinal direction 7. By means of a contact end 22 attached to the free end of the contact spring 21 the former is electrically conductively connected to the terminal contact 113. Since the contact spring 21 is fixed with its fastening end to the connection contact 13, the two connection contacts 13, 113 are also connected to one another in an electrically conductive manner. The circuit breaker 1 is therefore in its on state.

In the event of overcurrent, a bimetallic strip 23 with a movable leg in the longitudinal direction 7 acts on a lever arm of a release lever 24, which also extends approximately in the longitudinal direction 7. The release lever 24 is rotatably supported by a lever axis running in the transverse direction 5. The plane of movement of all levers of the switching mechanism is formed by the height direction 4 and the longitudinal direction 7. In the event of an overcurrent, the bimetallic strip 23 acts on the release lever 24 in such a way that it is rotated counterclockwise in the vertical direction 4. The latching lever 20, which is in the switched-on state of the circuit breaker 1 on the shorter lever arm of the release lever 24, which extends approximately in the vertical direction 4, is unlatched from the latter due to the rotation of the release lever 24 in the counterclockwise direction. The The rocker switch 17 is thereby rotated clockwise about its rocker switch axis 18. The circuit breaker 1 is in its off state (Fig. 5, Fig. 6).

A contact plug 25 is arranged on the area of the base 16 facing away from the switching rocker 17 in the vertical direction 4. The contact plug 25, like the two connection contacts 13, 113, extends in the height direction 4 out of the housing 2. The contact plug 25 is used to connect a control unit, not shown here, as a second protective element for a circuit. This is described in detail in DE 29 28 277 C2.

In the direction of the transverse direction 5, the rocker switch 17 has an approximately trapezoidal outer contour. The trapezoidal side surface of the rocker switch 17 forms a bracket 26. Viewed in the transverse direction 5, a further bracket 26 is arranged behind the base 16. The arms 26 are congruent. Viewed in the longitudinal direction 7, they form the U legs of the U-shaped rocker switch 17. The arms 26 lie in the plane formed by the height direction 4 and the longitudinal direction 7. The inner surfaces of the arms 26 facing each other in the transverse direction 5 flank a side surface of the base 16.

The trapezoidal outer surface of the rocker switch 17 contains an imaginary shorter and longer diagonal. The shift rocker axis 18 running in the transverse direction 5 is arranged approximately at the intersection of these two diagonals. The two switch buttons 9, 109 are each pivotally mounted on the rocker switch 17 via an articulated axis 27 or 127. The hinge axes 27, 127 and the shift rocker axis 18 run parallel to one another. The centers of the three axes mentioned above lie on a common connecting line. This connecting line lies approximately on the longer imaginary diagonal of the trapezoidal outer surface of the rocker switch 17. With regard to a symmetrical axis arranged perpendicular to this connecting line, bisecting and imagining the connecting line, the rocker switch 17 is constructed symmetrically in its areas essential for accommodating the switch button 9, 109 or the switching hood 41 . For this reason, both joint axes 27, 127 are at the same distance from the shift rocker axis 18.

The actuating end 12 of the switch button 9 is extended along the height direction 4 in the direction of the rocker switch 17 by a fork arm 28. A total of two fork arms 28 are integrally formed on the actuation end 12. In the viewing direction of the transverse direction 5, they are arranged congruently to one another. The fork arms 28 have a conically tapering in the direction of the hinge axis 27 Outer contour on. In the area of the imaginary cone tip, the fork arm 28 is rounded off approximately semicircularly. This region of the fork arm 28 forms a bearing end 29 of the switch button 9. The fork arm 28 has a smaller extension in the longitudinal direction 7 than the actuating end 12.

The two fork arms 28 encompass the rocker switch 17 in a fork-like manner and flank it on both sides parallel to the lever arm thereof. The hinge axis 27 extends through the two bearing ends 29 and the rocker switch 17. In this way, the switch knob 9 is pivotable and at the same time captively secured on the rocker switch 17.

With regard to an axis of symmetry running parallel to the height direction 4 and intersecting the joint axis 27, the fork arm 28 is configured symmetrically. This imaginary axis of symmetry is arranged offset in the longitudinal direction 7 with respect to a longitudinal axis 30 of the switch button 9 which also extends in the vertical direction 4, the distance between the imaginary axis of symmetry and the separating web 11 being greater than the distance between the longitudinal axis 30 and the dividing web 11. The rectangular outer contour of the actuating end is shown by the longitudinal axis 30 halved.

With regard to the design of the switch button 109 and its arrangement on the rocker switch 17 by means of the articulated axis 127, the aforementioned statements regarding the switch button 9 apply.

The transition regions between the side edges of the actuating ends 12, 112 running in the height direction 4 and the longitudinal direction 7 are rounded in a quarter circle. The transitions between the actuating end 12 and fork arm 28 are also rounded. The same applies to the switch button 109.

When viewed in the longitudinal direction 7, the two joint axes 27, 127 are at a greater distance from one another than the two longitudinal axes 30, 130.

The actuation end 12 lies in a form-fitting manner in the interior 10 of the shaft. In the height direction 4, the actuating end 12 is completely covered by the shaft 8 or by the separating web 11. The overall height of the shaft interior 10 viewed in the height direction 4 is somewhat larger than the corresponding extension of the actuating end 12. However, the outer surface of the actuating end 12 facing away from the rocker switch 17 is flush with the shaft 8. For this purpose, a nose-shaped end stop 31 is arranged on the inner end of the shaft interior 10 facing the rocker switch 17. The end stop 31 is in one piece on the the dividing web 11 formed in the longitudinal direction 7 opposite inner wall of the shaft 8. It protrudes somewhat into the interior 10 of the shaft and reduces its cross-sectional area. In this way, the longitudinal displacement of the switch button 9 along its longitudinal axis 30 in the direction of the rocker switch 17 is limited. The extent of the end stop 31 in the height direction 4 corresponds to the difference between the height of the shaft interior 10 and the height of the actuating end 12.

In the interior of the shaft 110, an end stop 131 for the switch button 109 is formed in the same way.

The housing cover 3 together with its shaft 8 formed thereon is constructed symmetrically with respect to a switch axis 32 that runs parallel to the height direction 4 and intersects the separating web 11. In Figure 3, the housing cover 3 and the shaft 8 together form approximately the shape of a hat. When viewed in the longitudinal direction 7, the end regions of the housing cover 3 form the brim of the hat which projects beyond the shaft 8. These brims are effective as lid ends 33, 133. The cover ends 33, 133, viewed in the longitudinal direction 7, extend into the area of the hooks 6. The surface of the lid ends 33, 133 facing the hook 6 runs exactly in the longitudinal direction 7. The surface facing away from it in the vertical direction 4 is slightly inclined with respect to the longitudinal direction 7, so that the lid ends 33, 133 taper in the direction of the hook 6.

A side wall 34 of the housing 2 extending in the vertical direction 4 adjoins the shaft 8 facing away from the cover end 33. It is integrally formed on the innermost region of the lid end 33, viewed in the longitudinal direction 7. The side wall 34 is provided with a bevel 35 approximately at the level of the hinge axis 27. Another part of the side wall 34 extending in the height direction 4 adjoins the bevel 35. The distance from this part of the side wall 34 to the switch axis 32 is somewhat larger than the same distance from the part of the side wall 34 directly adjoining the cover end 33. The interior of the housing 2 is thereby enlarged in its area facing away from the shaft 8 in the height direction 4.

With regard to the lid end 133, a side wall 134 and a bevel 135, the analogous versions apply. The side walls 34, 134 are arranged and configured symmetrically to one another with respect to the switch axis 32. It is only in the area which is the most distant from the cover end 133 in the height direction 4 that Side wall 134 is shorter than the side wall 34. This asymmetry of the side walls 34, 134 is due to the structure of the base 16.

The base 16 is pushed in the height direction 4 into the interior of the housing 2. The parts of the side walls 34, 134, starting from the bevels 35, 135 facing away from the lid ends 33, 33, surround the base 16 in a form-fitting manner. The inner walls of the bevels 35, 135 form latching stops for the base 16 for fixing it within the housing 2.

In the area of the bevel 35, a wedge-shaped flank extension 36 rests on the base 16 with its wedge tip. The flank extension 36 is part of a flank 37 integrally formed on the rocker switch 17 and extending along the longitudinal direction 7.

Following the flank extension 36, the flank 37 is designed as a hollow cylinder segment in the region of the bearing end 29 and is effective as a trough 38. The trough 38 lies directly against the bearing end 29 of the switch button 9 which is designed as a cylinder jacket segment. The fork arm 28 is therefore guided by the trough 38 as in a bearing pan during the pivoting movements of the switch button 9. The trough 38 is widened in the direction of the switch axis 32 such that part of the surface of the fork arm 28 which adjoins the bearing end 29 and faces the switch axis 32 bears against the trough 38. This extension of the trough 38 forms a swivel stop for the fork arm 28. At the end of the trough 38, the flank 37 is angled as a flank web 39 in the direction of the shift rocker axis 18.

The flank 37 is constructed symmetrically with respect to an axis of symmetry which is arranged perpendicular to the connecting line of the joint axes 27, 127 and which intersects the rocker switch 18. The switch button 109 is therefore guided in the same way as the switch button 9 by a recess 138. The two flank webs 39, 139 are arranged at an obtuse angle to one another. They meet in an area between the shaft 8 and the shift paddle axis 18.

The lever arms geometrically formed by the connecting line between the rocker switch axis 18 and the joint axis 27 or 127 are structurally limited by the cover surfaces 40, 140 facing the shaft 8. In FIG. 3, the cover surfaces 40, 140 form two sides of the approximately trapezoidal rocker switch 17 arranged at an obtuse angle to one another. In a central position of the rocker switch 17 between the input and In the off position, the switch axis 32 passes through the apex of the obtuse angle. In this middle position, the connecting line between the two hinge axes 27, 127 is arranged perpendicular to the switch axis 32.

In FIG. 3, the top surface 140 runs exactly in the longitudinal direction 7 and lies against the inner end of the shaft interior 110. The top surface 140 and the longitudinal axis 130 form a right angle. The cover surface 40 and the longitudinal axis 30, however, form an acute angle.

As a result of the cover surface 140 lying against the inner end of the shaft interior 110, the actuating end 112 of the switch button 109 projects beyond the shaft 8 from the outside. The part of the actuating end 112 that is visible from the outside signals the switched-on state of the circuit breaker 1.

In Figure 4, the circuit breaker 1 is shown with only one switch button 9. No switch button 109 is mounted on the rocker switch axis 127. The inner end of the shaft interior 110 (FIG. 3) is covered by the shaft lock 15. The shaft closure 15, running in the longitudinal direction 7, forms an integral connection between the shaft 108 and the cover end 133.

The circuit breaker 1 in Figure 4 is in its on state. The top surface 140 and the shaft closure 15 rest against one another with their mutually facing surfaces.

The circuit breaker 1 which is only equipped with a switch button 9 in FIG. 4 can only be switched on manually (FIG. 4, FIG. 6).

In the area of the inner end of the shaft interior 10, the shaft 108 has an end stop 31 which is arranged and designed in the same way as the shaft 8 (FIG. 3). In addition, a second end stop 31 is formed on the shaft 8 opposite the first end stop 31 in the longitudinal direction 7. It is arranged on the inner wall of the shaft 108 facing the shaft closure 15. With respect to the longitudinal axis 30, they are symmetrical to each other.

The operation of the circuit breaker 1 is explained with reference to Fig.3 to Fig.6.

In FIG. 3, the switch button 109 protruding beyond the shaft 8 indicates the on state of the circuit breaker 1. The switching mechanism is activated by the counterclockwise curved free end of the bimetallic strip 23 triggered. The rocker switch 17 is thereby pivoted clockwise about its rocker rocker axis 18. During this pivoting, the buttons 9, 109 are moved in the vertical direction 4. The actuating end 112, which is visible from the outside when the circuit breaker 1 is switched on, plunges into the shaft interior 110 during the pivoting. At the same time, the actuating end 12 of the switch button 9 is visible to the outside (FIG. 5). The switch button 9 thereby signals the switch-off state of the circuit breaker 1. The electrical contact between the contact end 22 and the connection contact 113 is interrupted.

The pivotability of the rocker switch 17 is limited by its shape. For this purpose, the flank extension 36 strikes when the circuit breaker 1 is transferred from its switched-on state (FIG. 3) to its switched-off state (FIG. 5) at the inner end of the shaft interior 10 in the region of the end stop 31. At the same time, the flank extension 136 bears against the base 16 in the region of the bevel 135. A defined switch-on position of the rocker switch 17 is thereby achieved.

The above statements apply to the transfer of the circuit breaker 1 which can be seen in FIGS. 4 and 6 from its switch-on state to its switch-off state. There is no switch button 109 to signal that the circuit breaker 1 is switched on. The switch-on state of the circuit breaker 1 is signaled here by the switch button 9 which does not protrude beyond the shaft 8 (FIG. 4). However, the switch-off state of the circuit breaker 1 is signaled in FIG. 6 in the same way as in FIG. 4 by the switch button 9 protruding beyond the shaft interior 10.

Starting from its switched-off state (FIG. 5, FIG. 6), the circuit breaker 1 can be switched on again by manually actuating the switch button 9. The actuating end 12 of the switch button 9 is pushed into the shaft interior 10. During the longitudinal displacement of the switching buttons 9, 109 in the height direction 4, the actuating ends 12, 112 are affected by side walls of the shaft 8 or by the separating web 11. As a result, the switch buttons 9, 109 can be actuated in a simple manner like a push button, whereby they are displaced in the direction of their longitudinal axis 30, 130.

The switch button 9 is pressurized in the direction of the rocker switch 17 until its actuating end 12 bears against the end stop 31 (FIG. 3) or the two end stops 31 (FIG. 4). The rocker switch 17 is turned counterclockwise pivoted. As soon as the actuating end 12 abuts the end stop 31, the flank extension 36 strikes the base 16 in the region of the bevel 35. In addition, the top surface 140 bears against the inner end of the shaft interior 110 (FIG. 3) or against the shaft closure 15 (FIG. 4). The longitudinal displacement of the switch button 9 and the pivoting of the rocker switch 17 are limited so that a clear switch-on position of the rocker switch 17 is achieved. In addition, the large number of limit stops prevents damage or destruction of the switch button 9, 109, the rocker switch 17 or other components of the switching mechanism caused by excessive forces.

Only the circuit breaker 1 with the two buttons 9, 109 can be manually switched off again (Fig. 3). For this purpose, the switch button 109 is pushed into the shaft interior 110 with its actuating end 112. The longitudinal displacement of the switch button 109 is limited by the end stop 131. At the same time, the pivoting of the rocker switch 17 in the clockwise direction is limited by the flank extensions 36, 136 which abut the shaft 8 or the base 16 (FIG. 5). As soon as the switch button 109 abuts the end stop 131 with its actuating end 112 after manual actuation, the former is no longer visible in the direction of view in the transverse direction 5. Instead, the switch button 9 with its actuating end 12 projects outward beyond the shaft 8 and signals the switched-off state of the circuit breaker 1.

The visual recognizability of the switching state of the circuit breaker 1 can additionally be improved by designing the surfaces of the switching buttons 9, 109 in different colors or by providing them with a special warning color.

Because of the special shape of the rocker switch 17, the geometric lever arms are arranged parallel to the housing cover 3 and perpendicular to the longitudinal axes 30, 130 in a central position of the rocker switch 17 lying between the on and off position. Starting from this middle position, the same displacement path results for the switching buttons 9, 109 in the height direction 4 in order to achieve the switching rocker 17 on or off position. This favors the symmetrical and thus space-saving structure of the circuit breaker 1. This special arrangement of the geometric lever arms is also very useful in order to approximate the actual displacement of the articulated axes 27, 127 in the plane of movement of the rocker switch 17 as closely as possible to a longitudinal displacement in the vertical direction 4 to be able to. This is a prerequisite for the simple functioning of the switch buttons 9, 109 and the narrow design of the circuit breaker 1. The guidance of the control buttons 9, 109 during their longitudinal displacement is further improved by the troughs 38, 138 resting on the bearing ends 29, 129. They also limit the pivotability of the switch buttons 9, 109 in the plane of movement of the rocker switch 17.

In Fig. 7 it can be seen that a switching hood 41 is placed on the rocker switch 17 and fixed thereon. The housing 2 of the circuit breaker 1 is shown only schematically in broken lines. The switching rocker 17 that fixes the switching hood 41 is identical to the switching rocker 17 that fixes the switching buttons 9, 109. The cover 3 with its cover ends 33, 133 and the side walls 34, 134 connected to the rest of the housing 2 are structurally identical to the exemplary embodiments in FIGS. 1 to FIG. 6. The housing cover 3 in FIG. 7 differs from the other exemplary embodiments essentially only in the design of a shaft for receiving the switching hood 41. The shaft also surrounds the switching hood 42 as a hood shaft 45 in the plane spanned by the transverse direction 5 and the longitudinal direction 7 short distance for free mobility of the switching hood 42 corresponding to the switching movements of the rocker switch 17. The hood shaft 45 protrudes the surface of the cover 3 in the height direction 4 only slightly, in contrast to the shaft 8. The top of the hood shaft 45 is flush with the portion of the hood top 42 which runs parallel to the longitudinal direction 7, depending on the switching position of the rocker switch 17. Both sub-areas are separated from one another by the trough-shaped depression of the hood top 42, which is convex with respect to the rocker switch 17, and are functionally comparable to the actuating ends 12, 112 of the switch buttons 9, 109.

The switching hood 41 is symmetrical with respect to the switch axis 32, provided that the connecting line between the articulated axis 27 and the switching rocker axis 18 runs parallel to the longitudinal direction 7. The hood top 42 is connected to two congruent hood fork arms 43, of which only one hood fork arm 43 is visible in FIG. 7. The hood boom arms 43 lie in a plane spanned by the height direction 4 and the longitudinal direction 7. They overlap the rocker switch 17 and lie with their mutually facing surfaces on an outer side of the rocker switch 17. The edge edge of the hood fork arm 43 facing the troughs 38, 138 and the flank webs 39, 39 and oriented in the longitudinal direction 7 is widened in a V-shape. The two V-legs are arranged at an obtuse angle to one another and run parallel to the flank webs 39, 139. The two V-legs are each extended by a hood bearing end 44,144. The two hood overlying 44,144 face the flanks 37,137 approximately in the vertical direction 4 and positively abut the troughs 38,138. The hood bearing ends 44, 144 each contain a bore through which the joint axis 27 and 127 pass. The switching hood 41 is fixed immovably on the switching rocker by means of the articulated axes 27, 127.

With regard to the mode of operation of the rocker switch 17, the description for FIGS. 1 to 6 applies analogously.

The structure of the circuit breaker 1 shown here is suitable for single-pole and multi-pole circuit breakers, which can also be provided with further attachments or protective elements.

"List of reference symbols 38

39 flank

40 deck area

41 switching hood

42 hood top

43 hood fork arm

44 hood bearing ends

45 hood shaft

109 switch button

110 shaft interior

112 end of actuation

113 connection contact

114 connection contact

127 joint axis

128 fork arm

129 end of stock

130 longitudinal axis

131 end stop

133 lid end

134 side wall

135 bevel

136 flank extension

137 flank

138 Depletion

139 flank

140 deck area

144 hood bearing ends

Claims

Expectations

1. Circuit breaker (1)

- With a rocker switch (17) pivotably mounted on a base (16) and forming a two-armed lever for switching on and off,

- With a housing (2) which can be placed on the base (16) and surrounds it in a touch-proof manner,

- With a on the actuating side of the circuit breaker (1) located housing cover (3) to cover the rocker switch (17) and

- With a housing opening arranged in the housing cover (3) for receiving a fitting part which penetrates it and thereby pressurizes a lever arm of the rocker switch (17),

- Which on the side of this lever arm in one of the two switching positions protrudes further out of the housing opening than in the other switching position and thus signals the switching state of the switch (1), characterized in that optionally

- Only one lever arm is movably connected with only one as a switch button (9) and in the housing cover (3) guided longitudinally displaceable attachment part, while the other lever arm is covered by the housing cover (3) or

- Both lever arms are rigidly connected to a common attachment part designed as a switching hood (41).

2. Circuit breaker according to claim 1, characterized in that the housing opening is the edge of a housing shaft (8,45) projecting beyond the housing cover (3).

3. Circuit breaker according to claim 1, characterized in that the rocker-side end of the switch button (9) as Geiekende (29) is connected to the lever arm of the rocker switch (17).

4. Circuit breaker according to one or more of the preceding claims, characterized in that

- That the hinge axis (27) of the switch button (9) runs parallel to the Schaltwip¬ penachse (18) and - That the lever arm containing both axes in its middle position between the on and off positions occupies an approximately parallel position to the housing opening containing the housing cover (3).

5. Circuit breaker according to one or more of the preceding claims, characterized in that the shaft height and the switch button length are coordinated so that the switch button (9) only in one of its two switching positions with its actuating end (12) is visible from the outside through the shaft opening .

6. Circuit breaker according to one or more of the preceding claims, characterized in that the switching rocker (17) strikes in its two switching positions with a lever arm on the inside of the housing cover (3) thereby forming a pivoting limit stop.

7. Circuit breaker according to one or more of the preceding claims, characterized in that the cover (3) facing the cover surfaces (40, 140) of the lever arms of the rocker switch (17) form an obtuse angle of such a size that they essentially in the two switch positions Fully touch the inner surface of the housing cover (3).

8. Circuit breaker according to one or more of the preceding claims, characterized by a protrusion in the area of the inner end of the shaft (8, 45) in its interior as an end stop (31, 131) for the actuating end (12, 42) of the attachment part (9, 41).

9. Circuit breaker according to one or more of the preceding claims, characterized in that

- That the switch button (9) lies in the plane of movement of the rocker switch (17) and

- That the hinge end (29) of the switch button (9) surrounds the associated lever arm of the rocker switch (17) in a fork-like manner such that both fork arms (28) lie on different sides of the plane of movement of the rocker switch (17).

10. Circuit breaker according to claim 9, characterized by a planar contact of the fork arms (28) on the flank of the rocker switch parallel to the movement plane [= arm (26)].

11. Circuit breaker according to one or more of the preceding claims, characterized in that the bearing ends (29) of the fork arms (28) are designed as cylinder jacket segments with the hinge axis (27) as the cylinder axis and on correspondingly hollowed out flank projections [= troughs (38)] of the The rocker switch (17) is guided in a bearing pan.

12. Circuit breaker according to claim 11, characterized in that the two troughs effective as bearing pans (38) extend so far in the direction of the actuating end (12) of the switch button (9) that they there lateral swivel stops for the two fork arms in both switching positions (28) form.

13. Circuit breaker according to one or more of the preceding claims, characterized in that each lever arm of the rocker switch (17) has an articulated axis (27, 127) for the articulated connection of the switch button (9).

14. Circuit breaker according to claim 13, characterized in that the rocker switch (17) is arranged symmetrically with respect to a perpendicular to the connecting line of the two hinge axes (27, 127) and this connecting line bisecting the axis of symmetry.

15. Circuit breaker according to one or more of the preceding claims, characterized in that the switching hood (41) covers the top surfaces (40, 140) of both lever arms of the switching rocker (17) with their hood top (42) forming the actuating end.

16. Circuit breaker according to one or more of the preceding claims, characterized in that the switching hood (41) with its rocker-side end, the switching rocker (17) grips like a fork in such a way that the two hood fork arms (43) lie flat against the shift rocker flanks [= extension arm (26)].

17. Circuit breaker according to claim 16, characterized in that the hood fork arms (43) by means of the articulated axes (27, 127) of the switch button (9) on the rocker switch flanks [= boom (26)] are immovably fixed.

18. Circuit breaker with a symmetrically constructed rocker switch, in particular according to claim 14, characterized in that each hood fork arm (43) has two hood bearing ends (44, 144) bearing against the two flank projections [= troughs (38, 138)] of a rocker switch flank [= arm (26)] has the articulated axes (27, 127) of the switch button (9) as bearing axes.

19. Circuit breaker according to claim 18, characterized in that the hood bearing ends (44, 144) bear positively on the flank projections [= recesses (38, 138)].