EP0242664A1 - Manually-operated electrical switch - Google Patents

Abstract

The invention relates to a manually-operated circuit breaker (1) having a two-armed switch lever (9) supported such that it can pivot on the switch housing. Its drive arm (24) together with a push rod (11) form the guide of a bell crank (25) in kinematic drive terms. A contact link (13) connects two fixed contacts (14, 15). The pivoting movement of the switch lever produces a follow-through movement of the bell crank (25) through its extended position against a contact spring pressure, which allows the contact link (13) to be transferred into a contact open position, and vice versa. The push rod (11) is inserted such that it can pivot with an end remote from the contact (guide end 26) in a guide slot (27) running in its pivoting direction on the unsupported end of the drive arm (24) of the switch lever (9), and such that it can move in the slot direction. Between its ends, the push rod is provided with a latching tab (34) which, after a follow- through movement of the push rod (11) in the contact open direction, through the bell crank extended position under the contact spring force of the contact link (13) in the open position, is located in a stop position on a latch projection (35) fixed to the housing and holds the contact link (13) in the contact open position. <IMAGE>

Description

The invention relates to a manually operated electrical switch with the features specified in the preamble of claim 1.

Such switches are known for example from EP-A-0127784. They have a two-armed switching lever, which is rotatably mounted on the switch housing, and by pivoting between a closed and open position, a contact bridge is opened or closed. The contact bridge is moved kinematically via a toggle lever, which is formed from a drive arm connected to the shift lever and a pressure tappet mounted in a rotary-slide joint on the latter. The pressure tappet serves as a pressure transmission part and acts with its free end on the contact bridge.

When the shift lever is moved from the on position to the off position, the toggle lever is pushed through its extended position. The articulated axis of the toggle lever moves downwards towards the contact bridge. The contact bridge is opened downwards via the pressure tappet. The toggle lever is then in an overstretched end position in which it is held by the contact spring pressure.

Due to the opposite rotation of the shift lever, the toggle lever moves from its extended position into the normal kink area. Since the pressure plunger can move freely in the rotary sliding joint of the drive arm of the shift lever, the toggle lever is moved by the contact Spring suddenly moved to its kink position and the contact bridge closed.

The disadvantage of such a switch is the large number of individual parts and articulated connections required. When switching on the torque, these parts must also be accelerated, which reduces the switch-on speed. The object of the invention is therefore to provide a manually operated switch of the type mentioned with a switch-on actuation that cannot be influenced by a lever actuation, which is structurally simple.

This object is achieved in accordance with the characterizing part of claim 1. Due to the housing-side latching of the pressure plunger in the contact opening position, in the contact opening position it is merely a spacer which holds the contact bridge in a position spaced apart from the fixed contacts.

The locking lug is disengaged from the locking projection by pivoting the switching lever. After exceeding the toggle lever extended position in the contact closing direction, the pressure tappet in the shift lever can move freely. Due to the contact spring pressure, it is suddenly moved into the contact closing position together with the contact bridge. This ensures operator-independent activation of the torque. This cannot be prevented by stopping the shift lever in an undefined middle position. A defined switch-on behavior is thus guaranteed at all times. The moment switching on can also take place even faster than with switches according to the prior art, since the masses to be accelerated are lower. This allows higher switching speeds and thus performance be achieved. This effect is further supported by the lower internal frictional forces between the moving parts of the switching mechanism due to the absence of axle connections.

In the latched open position of the switch, the movement of the shift lever is possible over a limited angular range of approximately 60 ° due to the rotary-joint-like connection between the pressure tappet and the drive arm. In a structurally advantageous embodiment, the switch according to the invention requires only a single component, namely the pressure plunger, in addition to the switching lever for the contact bridge actuation. This means a significant simplification in terms of construction and manufacturing technology. The cost of materials for the switching mechanism is also reduced, as is a narrow design of such switches. The switching mechanical movements are all carried out on one level.

According to claim 2, the shift lever is completely relieved of the contact spring pressure by the locking of the pressure plunger in the contact opening position. The gear lever thus falls into the switch-off end position due to its own weight when the device is installed vertically.

According to the characterizing feature of claim 3, the contact bridge rests under the contact spring pressure on the contact-side end of the pressure tappet. Here, too, no further structural elements are necessary in order to ensure a defined position of the pressure ram in relation to the contact bridge.

The design feature specified in claim 4 prevents lateral evasion of the contact side towards the end of the pressure plunger and thus improves the pressure transmission between it and the contact bridge. The relative position of the two components is thereby fixed to one another; during the contact movement, the contact-side end of the pressure plunger only rolls on the contact bridge in a narrowly limited area.

At the same end of the pressure plunger there is a blind bore running in its longitudinal direction, in which a compression spring lies (claim 5). This serves as a lash adjuster in the event that its contact with the contact bridge, in particular in the closed position of the switch, is not always guaranteed due to length tolerances of the pressure plunger. Due to the backlash compensation spring, a pressure transfer between these components is still possible insofar as the shift lever is pressed into its end position (stop position). This results in the same alignment of the actuating arms of the shift levers and thus an aesthetically advantageous overall impression being achieved when a plurality of switches according to the invention are strung together.

Claims 7 to 9 relate to advantageous developments of the particularly simple embodiment of the rotary sliding joint between the drive arm and the pressure tappet. The guide groove extends over an angular range of approximately 90 °, which corresponds to the pivoting angle of the shift lever and is limited by stop surfaces arranged in or against the rotary closing direction at its end. The stop surfaces are referred to below as the switch-on or switch-on edge. The meaning of these designations is clear from the description of the figures. The angular range the guide groove is diametrically opposite the actuating arm of the shift lever. Since the pivot axis of the shift lever lies approximately in the same plane as the outer wall surrounding the shift lever, this arrangement ensures that the guide groove lies in the interior of the switch housing in every operating position of the shift lever. So that no foreign objects, dirt or the like. penetrate into the guide groove and impede the switch function. The inner moving parts of the switching mechanism are also covered in every position of the shift lever and are protected against manipulation, contamination or the like. protected.

According to claim 10, the force of the contact spring acts in the switch-on position via the pressure plunger on the shift lever, whereby it is fixed in its defined switch-on pivot position. This also prevents the leading end of the pressure plunger from slipping out of the guide groove and thus causing the switch to malfunction. A somewhat shorter length of the pressure plunger than the distance between the center of the contact bridge and the switch-off flank in the contact closing position is particularly advantageous, as described in the characterizing part of claim 11. With a construction of this type, it is ensured at all times that, despite the existing manufacturing tolerances in the length of the pressure ram, the contact bridge is always supported on the two fixed contacts in the closed position. If the length of the pressure ram were to be greater than this distance, the contact bridge would not come into proper contact with its counter contact in the closed position. The play compensation is taken over by the play compensation spring at the contact-side end of the pressure tappet.

According to claim 12, the shift lever is movable relative to the pressure tappet without a force being exerted on it. The pressure tappet itself remains in its latched open position, which is advantageously not canceled by volatile or inadequate turning of the shift lever. Maloperation of the manually operated safety switch is thus effectively avoided.

Claims 13 and 14 describe measures that reduce wear within the switching mechanism and thus ensure defined switching kinematics even over a longer period of use of the switch. The abutment surfaces of the guide groove, that is to say the switch-on and switch-in flanks, are designed in the manner of a bearing socket, and the guide end of the pressure tappet has a correspondingly convex shape. The contact surfaces between the guide end of the pressure ram and the guide groove are thus large. There are no points of contact where high forces and therefore high abrasion occur.

In claim 15, a design feature is given, which serves an improved locking of the pressure ram in its open position. The opposite latching surfaces of the latching lug or the latching projection run at an acute angle with respect to the longitudinal axis of the pressure ram, which opens in the contact closing direction. The latching lug of the pressure tappet thus engages behind the latching projection lying on an inner part of the housing. The locking cannot be released by a simple lateral movement, but the pressure tappet must perform a combined movement in the axial and lateral directions.

• Fig. 1 eine seitliche Ansicht eines Sicherungsschalters bei geöffnetem Gehäuse in geschlossener Stellung,
• Fig. 2 eine seitliche Ansicht gemäß Fig. 1 in Offen­stellung und
• Fig. 3 eine vergrößerte, schematische Darstellung der Schaltmechanik in verschiedenen Schaltstel­lungen.

The invention is explained in more detail in an exemplary embodiment with reference to the attached figures. Show it:

• 1 is a side view of a fuse switch with the housing open in the closed position,
• Fig. 2 is a side view of FIG. 1 in the open position and
• Fig. 3 is an enlarged, schematic representation of the switching mechanism in different switching positions.

Figures 1 and 2 show the switching mechanism of the fuse switch 1, the plastic housing is essentially cuboid and is constructed from two housing half-shells 2. Two terminals 3 are arranged opposite each other on both sides of the housing. The connecting lines are brought through housing openings 4 to the connecting terminals 3 and fixed by the clamping screws 5.

The space between the two connecting terminals is divided by the shaft 6 for the fuse link 7 which can be used from above and the switching mechanism for the manual operation of the fuse switch 1. The directions of connection of the connecting terminals 3, shaft 6 and switching mechanism 8 lie approximately parallel in one plane next to one another, the one according to the invention Switch is therefore very narrow.

The switching mechanism 8 consists of the switching lever 9, which is mounted on a housing projection 10 integrally formed on the upper side of the fuse switch 1 so as to be pivotable about the pivot axis 42, the pressure plunger 11, which runs approximately perpendicular to the upper side of the housing, and the contact bridge 13, which acts against it in the opposite direction to the closing direction 12. Through the contact bridge 13, the current path leading through the fuse switch 1 can be interrupted manually. The current path runs between the first lateral terminal 3 via the first fixed contact 14, the contact bridge 13, the second fixed contact 15, the foot contact 16 for the fuse link 7, over the fuse link 7 itself and finally via its head contact 17 to the second terminal 3ʹ.

Between the shaft 6 for the fuse link 7 and the switching mechanism 8 there is also a locking mechanism 18 which prevents the contact bridge 13 from closing when the fuse link 7 is not inserted. Their mode of operation is described in EP-A-0184652.

The structure and the kinematics of the switching mechanism 8 are explained below with reference to FIG. 3. The switching lever 9, which is pivotably mounted on the housing projection 10 in the main extension plane of the safety switch 1, is designed with two arms. The outer actuating arm 19 serves as a handle and, in the closed position (FIG. 1), covers the screw cap 20 for the fuse link 7. The actuating arm 19 is approximately L-shaped, its pivot bearing leg 21 merging into the cylindrical roller 22 serving as the shift lever bearing body. A spring-loaded predetermined articulated joint 23 is additionally installed in the pivot bearing leg 21 and is intended to protect the switch from forcible closure when the fuse link 7 is not inserted and the shift lever 9 is thus locked. Their structure and function is also described in EP-A-0184652.

The part of the cylindrical roller 22 facing away from the actuating arm 19 is the drive arm 24 for the pressure tappet 11. These two parts form the kinematics of the handlebars of a toggle lever 25, by means of the kinking or stretching movement of which the contact bridge 13 is moved into its closed or open position. The knee joint of the knee lever 25 is a rotary sliding joint. It is formed by the fact that the knee-joint-side guide end 26 of the pressure plunger 11 lies in a guide groove 27 which, at the free, unsupported end of the drive arm 24 of the shift lever 9, extends in a circular arc around the pivot axis 42 in its pivoting direction 36. The guide end 26 of the pressure ram 11 is thus rotatably and displaceably mounted on the drive arm 24 in the longitudinal direction of the groove.

The guide groove 27 running in the shape of a circular arc in the swivel plane of the shift lever 9 sweeps over an angular range of approximately 90 °, which corresponds approximately to the swivel angle of the shift lever 9, and is delimited at both ends by two stop faces - the switch-off flank 37 and the switch-on flank 40. The guide groove 27 is diametrically opposite the actuating arm 19 of the shift lever 9. Running in the groove direction, the guide groove 27 is roughly trough-shaped.

The plunger 11 extends from the drive arm 24 of the shift lever 9 approximately in the contact closing direction 12 into the interior of the switch. Its contact-side end 28 runs between the two fixed contacts 14, 15 of the contact point and acts on the contact bridge 13 against the contact closing direction 12. The contact bridge 13 is under constant spring action in the contact closing direction 12 by the two contact springs 30 supported on the housing base 29 , mutual contact of the contact-side end 28 of the pressure ram 11 and the central area of the contact bridge 13 guaranteed. At the contact-side end 28 of the pressure plunger 11, two guide pins 31 are formed approximately at right angles from the plane of articulation of the toggle lever 25, each of which engages in a guide recess 33 which is opposite in the housing inner wall 32 and runs in the contact closing direction 12 of the contact bridge 13. The contact-side end 28 is thus laterally fixed and its movement in the housing is only possible in the contact closing direction 12.

Between its two ends, the pressure plunger 11 has a latching lug 34 arranged laterally approximately in the toggle lever plane, which after the pressure plunger 11 has been passed through in the contact opening direction through the toggle lever extended position under the contact spring pressure of the contact bridge 13 in the open position in a stop position on a latching projection 35 fixed to the housing . The opposing locking surfaces of locking lug 34 and locking projection 35 extend with respect to the longitudinal axis of the pressure ram at an acute angle 41 that opens in the contact closing direction 12. This ensures that the pressure ram 11 is locked securely.

The switching kinematic sequence is shown in FIG. 3. In the closed position of the switch 1 (FIG. 3A), the toggle lever 25 formed from the drive arm 24 and pressure tappet 11 is in its extreme kink position. In this position, the guide end 26 of the pressure tappet lies in the guide groove 27 on the switch-off flank 37 which delimits it in the pivoting closing direction 36 of the switching lever 9. The switching contact via fixed contact 14, contact bridge 13 and fixed contact 15 is reliably closed by the spring action by means of the contact springs 30. Since the Length of the pressure plunger 11 must not exceed the distance between the stop surface 37 and the center of the contact bridge, the length is chosen to be somewhat smaller than this critical distance to protect against manufacturing tolerances. In order to compensate for the play associated therewith, a blind bore 38 is provided in the contact-side end 28 of the pressure ram 11, in which the play compensation spring 39 lies. In the closed position shown in FIG. 3A, this play compensation spring 39 is supported on the contact bridge 13, presses the pressure plunger 11 upward and thus brings the shift lever 9 into the defined closed position end position shown. For reliable contacting, the spring force exerted by the play compensation spring 39 must be less than that of the contact springs 30.

The switch is opened by turning the shift lever 9 clockwise. Through the switch-off flank 37 - so named because it acts on the pressure plunger 11 during the switch-off movement - the leading end 26 of the pressure plunger 11 and thus the latter itself are moved downward against the contact closing direction 12, which separates the contact bridge 13 from the fixed contacts 14, 15 causes. This movement is carried out until the toggle lever 25 has reached the extended position (FIG. 3B, shift lever 9 shown as solid). After the dead center of the toggle lever 25 is exceeded, the pressure plunger 11 slides in the guide groove 27 by the spring action on the part of the contact springs 30 in the contact closing direction. Due to the simultaneous lateral movement, however, the locking lug 34 engages behind the locking projection 35 on the housing, as a result of which the pressure plunger 11 and thus the contact bridge 13 are fixed in the open position (FIG. 3C). The leading end 26 of the pressure ram 11 is now approximately in the central region of the guide groove 27. As a result, the shift lever 9 is freely movable between the extreme open position shown in FIG. 3C and approximately the middle position shown in FIG. 3B, without the locking between the pressure tappet and the locking projection 35 being released.

The locking consisting of locking lug 34 and projection 35 therefore has the task of alternately changing the function of the pressure plunger 11. During the contact opening movement of the switching mechanism, the pressure plunger 11 is the link of a toggle lever 25, which is formed by the drive arm 24, by its switch-off flank 37 on the guide groove 27 and the guide end 26 as a knee joint and the pressure plunger 11. In the contact opening position, the catch decouples the pressure plunger 11 from the drive arm 24, the plunger is virtually only a spacer.

When the switching lever 9 rotates in the opposite direction to close the safety switch 1, the switching lever 9 first measures the free travel mentioned. Thereafter, the switch lever 9 acts on the guide end 26 of the pressure plunger 11 with its switch-on flank 40 which delimits the guide groove 27 counter to the closing direction 36 of the switch lever 9. The interlocking movement between the latching lug 34 and the latching projection 35 is released by a superimposed movement in the axial and lateral directions. The plunger 11 is now again a link of the toggle lever 25. This has been varied, however, since the link on the switch lever side is formed by the drive arm 24 with the switch-on flank 40 as a knee joint part. The knee joint axis is no longer in the pan of the switch-off flank 37, but in the pan of the switch-on flank 40.

The extended position of the toggle lever is reached again shortly after the latching has been released (FIG. 3B, shift lever 9 shown in broken lines). After the bottom dead center of the drive arm 24 has been exceeded, the pressure plunger 11 is suddenly moved by the contact springs 30 in the contact closing direction 12 and the contact is closed in the process. Since the guide end 26 can slide freely in the guide groove 27 lying in front of it, only the contact bridge 13 and the pressure plunger 11 have to be accelerated to close the contact. This ensures a very fast activation of the torque, which moreover cannot be hindered by the shift lever 9.

To reduce wear, the abutment surfaces 37, 41 are designed in the manner of a bearing socket, and the leading end 26 of the pressure ram 11 is convexly curved.

Reference symbol list

• 1 switch
• 2 housing half-shell
• 3.3ʹ terminals
• 4 housing opening
• 5 clamping screws
• 6 shaft
• 7 Fuse link
• 8 switching mechanism
• 9 shift lever
• 10 housing protrusion
• 11 plungers
• 12 Contact closing direction
• 13 contact bridge
• 14 fixed contact
• 15 fixed contact
• 16 foot contact
• 17 head contact
• 18 locking mechanism
• 19 operating arm
• 20 screw cap
• 21 pivot bearing legs
• 22 cylindrical roller
• 23 predetermined articulation
• 24 drive arm
• 25 toggle levers
• 26 leaders
• 27 guide groove
• 28 contact-side end
• 29 case back
• 30 contact spring
• 31 guide pin
• 32 inner housing wall
• 33 guide recess
• 34 latch
• 35 locking projection
• 36 closing direction
• 37 switch-off edge
• 38 blind hole
• 39 Match compensation spring
• 40 switch-on edge
• 41 angles
• 42 gear lever pivot axis

Claims (15)

1. Manually operated electrical switch (1)
- With a two-armed switching lever (9) pivotally mounted on the switch housing,
- On the drive arm (24), the guide end (26) of a pressure ram (11) is mounted, namely
--- pivotable about an axis parallel to the gear lever pivot axis (42) and
--- limitedly displaceable in the swivel direction of the drive arm (24), and
- The drive arm (24) together with the pressure plunger (11) forms the drive linkage of a toggle lever (25), and
- With a contact bridge (13),
- As a result of a pivoting of the switching lever (9) leading the toggle lever (25) through its extended position from the pressure tappet (11) against the pressure of a contact spring (30) from a contact closing position (Fig. 1.3A) into a contact opening position (Fig 2; 3C) can be transferred back,
characterized,
that the pressure tappet (11)
- Between its ends (guide end 26, contact-side end 28) is provided with a locking lug (34)
- After the pressure tappet (11) has passed through the toggle lever extended position in the contact opening direction with the contact bridge (13) in the open position under the pressure of the contact spring (30), it engages behind a locking projection (35) fixed to the housing and in this latching position holds the contact bridge (13) in the contact opening position, and
- Is released from its locked position by pivoting the shift lever (9) in the closing direction (36), and
- After exceeding the toggle lever extended position in the closing direction (36) by the contact bridge (13) closing under the contact spring pressure without obstruction by the switching lever (9) is pushed back into its closed position (FIG. 3A). 2. Switch according to claim 1,
characterized,
that the switching lever (9) is relieved of the contact spring pressure by the locking of the pressure plunger (11) in the contact opening position. 3. Switch according to claim 1 or 2,
characterized,
that the contact bridge (13) bears under the contact spring pressure on the contact-side end (28) of the pressure plunger (11). 4. Switch according to claim 3,
characterized,
that on the contact-side end (28) of the pressure plunger (11) an approximately perpendicular from the plane of movement of the toggle lever (25) protruding guide pin (31) is formed on one or both sides, which is arranged in a in the opposite housing inner wall (32) in the contact closing direction (12) of the contact bridge (13) extending guide recess (33) in the contact closing direction (12). 5. Switch according to claim 4,
characterized,
that the pressure tappet (11) has at its contact-side end (28) a blind bore (38) running in its longitudinal direction, in which a compression spring (play compensation spring 39) lies. 6. Switch according to claim 1,
characterized,
that the pressure plunger (11) with its guide end (26) remote from the contact lies rotatably and displaceably in the groove direction in a guide groove (27) which extends in the pivoting direction of the drive arm (24) of the shift lever (9). 7. Switch according to claim 6,
characterized,
that the longitudinal axis of the guide groove (27) for the guide end (26) of the pressure plunger (11) extends in a circular arc around the pivot axis (42) of the shift lever (9) in its plane of rotation. 8. Switch according to claim 7,
characterized,
that the guide groove (27)
- Runs over an angular range that corresponds to the pivoting angle of the shift lever (9) and
- Is limited by stop surfaces arranged in or against the closing direction (36) (switch-off flank 37 or switch-on flank 40). 9. Switch according to claim 8,
characterized,
that the guide groove (27) opposite the actuating arm (19) of the shift lever (9) diametrically. 10. Switch according to one of the preceding claims,
characterized,
that in the closed position of the switching lever (9) the guide end (26) of the pressure plunger (11) bears against the switch-off flank (37) which delimits the guide groove (27) in the closing direction (36) of the switching lever (9). 11. Switch according to claim 10,
characterized,
that the pressure plunger (11) has a somewhat shorter length than the distance measured in the contact closing direction between the center of the contact bridge and the switching flank (37) delimiting the guide groove (27) in the rotational closing direction (36) of the switching lever (9). 12. Switch according to one of the preceding claims,
characterized,
that in the open position of the shift lever (9) the guide end (26) of the pressure plunger (11) assumes a position spaced from the switch-on flank (40) and the switch-off flank (37) of the guide groove (27). (Fig. 3C) 13. Switch according to one of claims 10 to 12,
characterized,
that the switch-off flank (37 ° and / or the switch-on flank (40) of the guide groove (27) are designed like a bearing socket. 14. Switch according to one of the preceding claims,
characterized,
that the leading end (26) of the pressure plunger (11) is convex. 15. Switch according to one of the preceding claims,
characterized,
that the opposite latching surfaces of the latching lug (34) and / or the latching projection (35) form an acute angle (41) which opens in the contact closing direction (12) with the longitudinal axis of the pressure ram.

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