EP3061109A1 - Electric circuit breaker - Google Patents

Abstract

The invention relates to an electric circuit breaker comprising a spring energy store drive (20) having a spring (21) and a manual winding device (11) suitable for manually tensioning the spring (21). In accordance with the invention, provision is made for the manual winding device (11) to have a rotatable latching disk (18), a latching pawl (15) arranged next to the latching disk (18), in particular on the end side of the latching disk (18), and a manual actuating device (11) connected to the latching pawl (15) for moving the latching pawl (15), for the latching pawl (15) to be guided or guidable into a latching toothed portion of the latching disk (18) and for the latching pawl (15) to be capable of moving owing to an actuation of the actuating device (11) and, as a result, for the latching disk (18) to be capable of rotating along a preset desired rotation direction (S) for tensioning the spring (21), and for the latching toothed portion to be asymmetrical such that a force transmission from the latching pawl (15) onto the latching disk (18) is only possible along the desired rotation direction (S) and the latching disk (18) slides along the latching pawl (15) when the latching disk (18) rotates along the desired rotation direction (S) more quickly than the latching pawl (15).

Description

description

The invention relates to electrical circuit breakers having the features according to the preamble of patent claim 1.

Such circuit breakers are sold by Siemens AG under the product names Siemens 3AH and 3AE circuit-breakers. The previously known circuit breaker have a spring-loaded drive and a manual-winding device with which the spring-loaded drive can be tensioned. The manual winding device comprises in these prior art power switches a hand crank and a two-stage worm gear.

The invention has for its object to provide an electric circuit breaker with a manually tensioned spring drive, which has a particularly simple structural design, but still precludes a hazard to operators in the event of malfunction or incorrect operation of the circuit breaker. This object is achieved by an electrical circuit breaker with the features of claim 1. Advantageous embodiments of the circuit breaker according to the invention are specified in subclaims. Thereafter, the invention provides that the manual winding device comprises a rotatable locking disk, a next to the locking disc, in particular on the end face of the locking disc, arranged latch and a standing with the latch in connection manual actuating device for moving the latch, the latch is controlled in a locking toothing of the locking disc or einsteuerbar and move by actuation of the actuating device, the latching pawl and thereby the locking disk along a predetermined NEN desired direction of rotation for tensioning the spring can rotate, and the locking teeth is asymmetrical so that a power transmission from the latch to the locking disc only along the desired direction of rotation is possible and slipping of the locking disc on the latch takes place when the locking disc along the set direction faster than the pawl turns.

A significant advantage of the power switch according to the invention is to be seen in the fact that in this a feedback or feedback on the manual winding device and thus on a hand-lifting device operator is excluded, even if it should come to a malfunction or malfunction of the circuit breaker. Due to the asymmetry of the latching toothing provided according to the invention, it is ensured that the latching disc can ratchet along the latching latch when, in the event of a malfunction or malfunction of the circuit breaker, the latching disc rotates faster along the desired rotational direction than the latching pawl. A force transmission from the latching pawl to the locking disk is thus possible only along the desired direction of rotation, and only if the latching pawl moves faster than the latching disk when actuated by the manual winding device, ie during a user-side clamping or clamping action of the user

Spring drive. In the case of a malfunction or incorrect operation of the circuit breaker or in the event that the locking disc - for whatever reason - automatically rotates along the desired direction of rotation, there is no transmission of power between the latch and locking disc, so that an operator can not be compromised.

It is considered to be particularly advantageous if the latching toothing of the locking disk is a circular arc-shaped external toothing. In this embodiment of the locking disk can be achieved that the locking disk only cooperates with the latch when the spring of the spring drive by turning the locking disc along the Solldrehrich- tense. During the relaxation phase of the spring can - be ensured due to the circular arc of the external teeth - that the locking disc is mechanically separated from the latch and a power transmission between see see these two components omitted.

Preferably, the circular arc angle has an angle value between (inclusive) 160 ° and (including) 200 °. In a structurally simple and thus advantageous embodiment of the circuit breaker is provided that the locking disc is rotatably connected to a switching shaft of the circuit breaker, the spring of the spring drive is a closing spring and a first rotation angle range of the switching shaft - when turning along the desired direction of rotation - for tensioning the spring and a second rotation angle range of the switching shaft - when turning along the desired direction of rotation - to relax the spring and to turn on the circuit breaker is used.

Preferably, the circular arc-shaped external toothing of the locking disc and the latching pawl are arranged to each other such that the latching pawl engages or can engage in the circular arc-shaped external toothing, when the switching shaft is in the first rotation angle range.

Accordingly, it is considered advantageous if the circular arc-shaped external toothing of the locking disc and the latch are arranged to each other such that the latching pawl is out of engagement with the circular arc-shaped external toothing, when the switching shaft is in the second rotation angle range.

With respect to the embodiment of the manual winding device, it is considered advantageous if this has a rocker pivotable about a fixed rocker axis on which the latch is pivotally supported about a pivot axis, wherein the

Pivot axis is parallel to the rocker axis and in the case of nes pivoting of the rocker about the rocker axis, the pivot axis of the latch is also rotated about the rocker axis.

Preferably, the pivoting range of the latching pawl is limited in the direction of the latching disc (or in the direction of the switching shaft) by means of a stop.

In order to ensure a defined position of the latch, it is considered advantageous if the manual lifting device comprises a positioning spring which generates a spring force on the latch in the direction of the locking disc.

The spring of the spring-loaded drive can be tensioned particularly simply and thus advantageously during rotation of the selector shaft if a spring end of the spring of the spring-loaded drive is mounted eccentrically on the selector shaft relative to the shaft axis and the axis of rotation of the detent disk and the axis of the selector shaft are identical , Preferably, the circuit breaker on a backstop, which prevents rotation of the locking disc against the desired direction of rotation.

The backstop preferably comprises a toothed wheel which is arranged coaxially with the latching disk in a manner fixed against rotation on the switching shaft of the circuit breaker.

The invention will be explained in more detail with reference to embodiments; thereby show by way of example

Figure 1 shows an embodiment of an electrical

Circuit breaker having a spring-loaded spring drive and a manual-winding device for manually tensioning the spring, wherein FIG. 1 shows the relaxed state of the spring, FIGS. 2-3 show the tensioning of the spring according to FIG. 1 on the basis of different spring tension states,

Figure 4 shows the tensioned state of the spring according to Figure 1 and

Figure 5 shows the circuit breaker according to Figure 4, ie in the tensioned state of the spring, in a different view.

For the sake of clarity, the same reference numbers are always used in the figures for identical or comparable components. FIG. 1 shows a manual winding device 10 which is intended for

Clamping of a spring drive 20 of a detail not shown in detail electrical circuit breaker is suitable. The spring-loaded drive 20 comprises a spring 21 whose bottom end 21a in FIG. 1 is fastened eccentrically to a switching shaft 30 of the circuit breaker by means of a fastening bolt 22 and an eccentric element 23. The upper end of the spring 21b in FIG. 1 is immovable or

mounted on the housing. The spring 21 may be, for example, a switch-on spring whose spring energy is used to switch on the circuit breaker.

For tensioning the spring 21 of the spring-loaded drive 20, the lower spring end 21a is pivoted downward from the position shown in FIG. 1 along a desired rotational direction S, by rotating the switching shaft 30 along the desired rotational direction S. To a manual tensioning of the spring 20 and a rotation of the

Shift shaft 30 to enable the target rotational direction S manually, the manual winding device 10, a manual actuator 11 in the form of a rod. The operating Generating device 11 is attached to a first rocker end of a rocker 12 which is pivotable about a rocker axis 13. In the region of a second rocker end of the rocker 12, a pivot axis 14 is arranged, which holds a latch 15 pivotally. The detent pawl 15 is pressed by means of a positioning spring 16 on a circular arc-shaped external toothing 17 of a locking disk 18. A torsion spring 13a serves to rotate the rocker 12 to a predetermined starting position when no manual operation is performed.

The pivot axis 14 is preferably parallel to the rocker axis 13, so that in the case of pivoting the rocker 12 about the rocker axis 13, the pivot axis 14, which holds the latch 15 is also rotated about the rocker axis 13.

The circular arc-shaped external toothing 17 is asymmetrical, so that a power transmission from the detent pawl 15 to the locking disc 18 only along the desired direction of rotation S is possible and slipping of the locking disc 18 takes place on the latch 15, when the locking disc 18 along the desired direction of rotation S faster than the Locking pawl 15 turns. Such a "faster" rotation of the locking disc 18 relative to the latch 15 may occur, for example, when a not shown in the figure 1 motor drive of the power switch is activated and the spring 21 of the spring drive 20 is additionally tensioned by the motor drive.

In the embodiment according to FIG. 1, the circular arc angle of the circular arc-shaped external toothing 17 has a value of approximately 180 °. Such a circular arc angle ensures that the detent pawl 15 is engaged with the locking disc 18 only when a tensioning of the spring 21 from the untensioned state shown in Figure 1 by rotation of the switching shaft 30 along the target rotational direction S should take place. Is the spring 21 in its tensioned state, they - starting from the representation of Figure 1 - by turning the switching shaft 30 and by turning the Detent disc 18 is reached by 180 °, the detent pawl 15 loses its engagement with the external toothing 17 or with the locking disc 18, so that the manual winding device 10 is automatically separated from the spring-loaded drive 20.

The manual winding device 10 is operated to tension the spring 21 as follows:

The manual actuating device 11 is set into an oscillating movement, by means of which the rocker 12 is pivoted about the rocker axis 13. The pivoting of the rocker 12 about the rocker axis 13 leads to a pivoting of the pivot axis 14 and thus to a movement of the detent pawl 15 tangentially along the external teeth 17 of the locking disk 18. During the movement phase in which the latching pawl 15 is moved along the desired direction of rotation S is engage the detent pawl 15 in the outer toothing 17 force-transmitting and rotate the locking disc 18 along the desired direction of rotation S, whereby the shift shaft 30 is rotated about the desired direction of rotation S and the spring 21 is tensioned.

In the backward movement of the detent pawl 15 is due to the asymmetry of the teeth of the outer teeth 17 no power transmission between the detent pawl 15 and the outer teeth 17 and the locking disc 18 done so that the detent ratchet 15 is ratchet on the outer teeth 17 without turning back the locking disc 18 ,

In order to reliably prevent the locking disk 18 from turning back counter to the setpoint direction S, the circuit breaker according to FIG. 1 is equipped with a backstop 40 which comprises a gearwheel 41. The gear 41 is in communication with a not shown latch mechanism, which is a rotation of the gear 41 and thus a rotation of the

Switching shaft 30 only allowed in the desired direction of rotation S and otherwise prevented. FIG. 2 shows the rotation of the detent disk 18 along the desired direction of rotation S as soon as the manual actuating device 11 is actuated and with this, the detent pawl 15 is pushed forward by pivoting the rocker 12. It can be seen that the spring end 21a has already been moved slightly downwards due to the eccentric attachment to the control shaft 30 by the rotation of the control shaft 30. FIG. 3 shows a further state of the spring-loaded drive 20 during the clamping operation in greater detail. It can be seen that the latching pawl 15 engages in a middle region of the external toothing 17 of the latching disc 18 and that the spring 21 of the spring latching device 20 is already partially tensioned by approximately half.

FIG. 4 shows the spring 21 or the spring-loaded drive

20 in the fully tensioned state. It can be seen that the latching pawl 15 has reached the last tooth of the circular arc-shaped outer toothing 17 of the locking disk 18 and a further oscillating movement of the manual actuating device 11 no further tensioning of the spring 21 or no further rotation of the switching shaft 30 along the desired direction of rotation S. can cause.

Summarized Figures 1 to 4 thus show that a first rotation angle range of the switching shaft 30 - when rotating along the desired direction of rotation S - for tensioning the spring

21 and a second rotational angle range of the switching shaft 30 for releasing the spring and for switching on the circuit breaker is used. The first rotation angle range is defined in the exemplary embodiment according to FIGS. 1 to 4 by the upper position of the spring end 21a of the spring 21 according to FIG. 1 and the lower position of the spring end 21a of the spring 21 according to FIG.

In the first rotation angle range of the switching shaft 30, the external teeth 17 of the locking disc 18, whereby in The first rotational angle range of the switching shaft 30, a tensioning of the spring 21 can be effected by means of the actuating device 11. The second rotational angle range of the switching shaft 30 lies between the state according to FIG. 4 and the state according to FIG. 1, when the switching shaft 30 is further rotated along the desired rotational direction S. In the second rotational angle range of the switching shaft 30, there is no external toothing on the detent disk 18, so that the detent pawl 15 can not engage in the detent disk 18 in the second rotational angle range of the switching shaft 30.

In order to prevent the latching pawl 15 from pivoting too far in the direction of the switching shaft 30 in the second rotation angle range of the switching shaft 30, the manual winding device 10 is preferably equipped with a stop 19 which limits the pivotability of the latching pawl 15 about the pivot axis 14. The stop 19 may be formed, for example, by a slot 19a and a bolt 19b (cf., FIG. 1). 5 shows the circuit breaker according to Figures 1 and 4 again in a different view in the tensioned state of the spring 21. The figure 5 thus shows the same state of the spring 21 and the spring drive 20 as the figure 4. Summarized by the circular arc of the External teeth 17 ensures that the manual actuator 11 is mechanically coupled exclusively to the switching shaft 30 in the first rotation angle range of the switching shaft 30, ie during the clamping phase, and a tensioning of the spring 21 during further rotation of the switching shaft 30 along the desired direction of rotation S, starting from the tensioned state , as shown in Figure 4, can not oppose. The asymmetry of the external teeth 17 ensures that rotation of the control shaft 30 along the target rotational direction S is possible independently of operation of the manual winding device 10, whether by a motor drive of the circuit breaker or other engagement; a feedback to the actuator 11 in the case of Maloperation of the circuit breaker is thus reliably prevented.

While the invention has been illustrated and described in detail by way of preferred embodiments, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

10 manual winding device

11 actuator

12 seesaw

 13 rocker axis

 13a torsion spring

 14 pivot axis

 15 latch

 16 positioning spring

17 external toothing

 18 locking disc

 19 stop

 19a slot

 19b bolt

 20 spring accumulator drive

21 spring

 21a lower end of the spring

21b upper spring end

22 fastening bolts

23 eccentric element

 30 shift shaft

 40 backstop

 41 gear

S target direction of rotation

Claims

claims

Electric circuit breaker having a spring drive (20) having a spring (21) and a manual winding device (11) suitable for manually tensioning the spring (21),

d a d u r c h e c e n c i n e s that

 the manual-winding device (11) has a rotatable detent disk (18), a detent pawl (15) arranged next to the detent disk (18), in particular on the end face of the detent disk (18), and a manual actuating device (11) which is in communication with the detent pawl (15) ) for moving the latch (15),

 the detent pawl (15) is controlled or can be activated in a latching toothing of the detent disk (18) and the detent pawl (15) moves by actuation of the actuating device (11) and thereby the detent disk (18) along a predetermined desired rotational direction (S) Tensioning the spring (21), and

- The ratchet teeth is asymmetrical such that a

 Power transmission from the detent pawl (15) on the locking disc (18) only along the desired rotational direction (S) is possible and slipping of the locking disc (18) on the latch (15) takes place when the locking disc (18) along the desired direction of rotation (S ) faster than the latch (15) rotates.

2. Circuit breaker according to claim 1,

d a d u r c h e c e n c i n e s that

the latching toothing of the locking disk (18) is a circular arc-shaped external toothing (17).

3. Circuit breaker according to claim 2,

d a d u r c h e c e n c i n e s that

the arc angle has an angle between 160 ° inclusive and 200 ° inclusive.

4. Circuit breaker according to one of the preceding claims 2-3,

d a d u r c h e c e n c i n e s that

 the latching disc (18) is non-rotatably connected to a switching shaft (30) of the circuit breaker,

 the spring (21) of the spring-loaded drive (20) forms a switch-on spring and

 a first rotational angle range of the switching shaft (30) - when rotating along the desired direction of rotation (S) - for tensioning the spring (21) and a second rotation angle range of the switching shaft (30) - when rotating along the desired direction of rotation (S) - to relax the spring (21 ) and to switch on the circuit breaker.

5. Circuit breaker according to claim 4,

d a d u r c h e c e n c i n e s that

the circular arc-shaped external toothing (17) of the latching disc (18) and the latching pawl (15) are arranged relative to one another such that the latching pawl (15) can engage or engage in the circular arcuate outer toothing (17) when the switching shaft (30) engages in is the first rotation angle range.

6. Circuit breaker according to one of the preceding claims 4-5,

d a d u r c h e c e n c i n e s that

the circular arc-shaped external toothing (17) of the latching disc (18) and the latching pawl (15) are arranged relative to one another such that the latching pawl (15) is out of engagement with the circular arcuate outer toothing (17) when the

 Shift shaft (30) is located in the second rotation angle range.

7. The circuit breaker according to claim 1, wherein:

- The manual winding device (11) has a fixed rocker axis (13) pivotable rocker (12) on which the latching pawl (15) about a pivot axis (14) is pivotally supported, wherein the pivot axis (14) is parallel to the rocker axis (13) and in the case of pivoting the rocker (12) about the rocker axis (13), the pivot axis (14) of the latch (15) is also rotated about the rocker axis (13).

8. Circuit breaker according to claim 7,

d a d u r c h e c e n c i n e s that

the pivoting range of the latching pawl (15) in the direction of the latching disc (18) is limited by means of a stop.

9. Circuit breaker according to one of the preceding claims 5-6,

d a d u r c h e c e n c i n e s that

the manual winding device (11) comprises a positioning spring (16) which generates a spring force on the latching pawl (15) in the direction of the latching disk (18).

10. Circuit breaker according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

 a spring end of the spring (21) of the spring-loaded drive (20) on the switching shaft (30) - is mounted eccentrically relative to the shaft axis - and

 the axis of rotation of the locking disc (18) and the axis of the switching shaft (30) are identical.

11. Circuit breaker according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

the circuit breaker has a backstop (40) which prevents rotation of the locking disc (18) against the desired direction of rotation (S).

12. A circuit breaker according to claim 11,

d a d u r c h e c e n c i n e s that

the backstop (40) comprises a toothed wheel (41) which is arranged coaxially with the latching disc (18) in a rotationally fixed manner on the switching shaft (30) of the circuit breaker.