CS212539B1 - Cam electrical switch control mechanism - Google Patents

Abstract

The aim of the invention is to significantly limit the dependence of the movement of the switch contacts on the action of an external force, to fully utilize the locking springs for the actual switching process, and to enable one control element to control two, or even more, cam electric switches simultaneously. The above purpose is achieved by the control mechanism of cam electric switches with a locking ratchet mounted on the shaft of the control element, wherein a locking member is pressed by a spring into at least one tooth gap of the locking ratchet, while the middle tooth of the trio of adjacent teeth of the cam star, mounted on the shaft of the electric switch, reaches into the other tooth gap of the locking ratchet, wherein the top of one tooth of the pair of locking ratchet teeth defining this other tooth gap abuts against the side of one extreme tooth of the trio of adjacent teeth of the cam star, wherein the top of the second tooth of the pair of locking ratchet teeth abuts against the side of the second extreme tooth of the trio of adjacent teeth of the cam star (Fig. 1).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an actuation mechanism for cam electrical switches.

Cam electric switches comprising a shaft ', one end of which is provided with cams for operating the movable contacts and the other end with an operating element, such as a knob or lever. A disadvantage of these cam electric floaters is that the switching speed of the electrical contacts is largely dependent on how the switch is operated and the external force exerted on the actuator.

These disadvantages make it possible to substantially reduce the actuation mechanism of the cam-electric splinters according to the invention, which is characterized in that the respective tooth gap of the detent ratchet reaches the middle tooth of three adjacent cam star teeth mounted on the electric switch shaft. the locking ratchet defining the respective tooth gap abuts the side of one extreme tooth of the three adjacent cam star teeth, the top of the other tooth of the pair of the locking ratchet teeth abutting the side of the other extreme tooth of the three adjacent cam star teeth.

An advantage of the actuator mechanism of the cam electric floaters according to the invention is that, in addition to limiting the above disadvantages, it allows one actuator to operate two or more cam electric floaters simultaneously. The angle of rotation of the cam electrical switch can be determined either greater or less than the angle of rotation of the actuator, whereby the number of switch positions can be changed in relation to the number of actuator positions. The hall is used to the full extent of the locking springs for the actual switching process.

An example of an actuator mechanism of cam electric floaters according to the invention is shown in the accompanying drawings, in which FIG. 1 is an exploded perspective view of the cam electrical switch; FIG. 2 alternatively shows a front view of the actuating mechanism.

A knob 2 is fastened at one end of the actuator shaft 6 (FIG. 1). A locking ratchet 6 is fastened to the other end of the actuator shaft 6. A detent member 6 in the form of a ball 6 is pressed by a spring 6 into the tooth gap 6 of the detent ratchet 6. A further detent member in the form of a ball 8 is pressed by a spring 6 into a further tooth detent 6 of the detent ratchet. In the next tooth gap 10 of the detent ratchet delimited by the pair of teeth £, 12 and rotated relative to the tooth gap zub and the tooth gap o by 90 °, the central tooth 14 extends from the three adjacent teeth 13, 14, fastened at one end of the shaft 17 of the electric switch 18. The tip of the tooth 11 of the locking ratchet 6 abuts the side of one end tooth 13 of the cam star 64, and the tip of the tooth 12 of the locking ratchet 6 abuts the flank

The electric cam switch 18 comprises a plurality of segments 19 arranged in sequence. 20, 21 dve Two pairs of fixed contacts 22, 25 and 26, 27 are provided on segment 19 and the corresponding contacts 26 and 27 are respectively. to the pair of fixed contacts 22, 23 pressed by spring 28, and the mating contact 27 is to a pair of fixed contacts 24. 25 pressed by spring 29. On the mating contact 26, a hoist 40 is provided, resting on the cam 34 mounted on the shaft 17 on the mating contact. 27, there is provided a hoist 52 abutting the cam 64. For the sake of simplicity, the arrangement of the contact system is not shown on other segments 20, 21. In the described example of the actuating mechanism, the locking ratchet 8 has eight teeth and the cam star 16 also has eight teeth. Thus, the transmission ratio is 1: 1.

In an example of an alternative embodiment of the actuating mechanism (FIG. 2), the locking ratchet 101 is mounted on the actuator shaft 102 with the two cam stars 103 and 104. The cam star 103 is mounted at one end of the shafts 105 of the unplugged electrical switch. The cam star 104 is mounted at one end of shaft 106 of a non-illustrated other electrical switch. The locking ratchets 111, 112, 113, 114 are pressed into the free tooth gaps of the locking ratchet 101 by springs 107, 108, 109, 110. The locking ratchet 101 has eight teeth, with cam stars 103, 104 for twelve teeth.

The transmission ratio is therefore 2: 3.

When the knob 2 is rotated in the direction S, the locking ratchet 2 (FIG. 1) is simultaneously rotated and energy is stored in the springs 6 and 6, while the position of the cam star 16 and the position of the cam 31 have not changed. Immediately before reaching the locking balls g, 8 of the top of the teeth of the detent ratchet 2, its tooth 12 will engage the center tooth 14 of the cam star 16a. rotate this one. The cam 31 is designed so that until the locking balls g, g reach the top of the teeth of the locking ratchet 2, there is no change in the stroke of the hoists 30. 32 and thus the accumulation of energy in the springs 28, gg. first part of the switching cycle.

In the second part of the switching cycle, springs g, 2 have already acted ^{on the} continuous movement of the ratchet ratchet 2 and on the stroke of the bridge contacts 26. 27. With sufficiently strong springs 6 and 2, the switching of the contacts can be converted separately. in the first part of the switching cycle. That is, in a normal continuous mode of operation of the switch, the movement speed of the bridged contacts 26, 27 will be essentially determined by the force of the springs 6 and 2 at the time of their maximum compression. In such a case, there is no presumption that in the second part of the switching cycle an external force, i.e. the hand force on the control knob 2, is opposite to the direction of rotation of the locking ratchet 2 due to springs 6 and 2 ^. Even in the normal mode of operation, they allow first of all to accelerate the movement of the bridge contacts 26, 27 and at the same time substantially reduce the dependence of the movement of the bridge contacts 26, 27 on the external force.

The same switching cycle takes place when the knob 2 is rotated against the direction of g as well as in an alternative embodiment (Fig. 2). In this embodiment, the rotation angle of the control ratchet 101 is greater than the rotation angle of the cam stars 103 and 104.

Claims (2)

212539 2 104. The cam star 103 is mounted at one end of the shaft 105 of the illustrated electrical switch. The cam star 104 is mounted at one end of the shaft and 106 of the other electrical switch (not shown). Locking balls 111, 112, 113 are pressed into the free tooth gaps of the arresting ratchet 101 by the springs 107, 108, 109, 110. 114. The arresting ratchet 101 has eight teeth, with the cam stars 103, 104 for twelve teeth. So the gear ratio is 2: 3. Turning knob 2 towards S simultaneously rotates the locking ratchet 2 (Fig. 1), and energy 6 accumulates in springs 6 and 2, while the position of the cam star 16 and with it the position of cam 31 is not changed. Just prior to reaching the locking spheres 8, 8 of the top of the teeth of the stopper 2, its tooth 12 begins to engage with the central tooth 14 of the cam star 16 and in this to rotate. The cam 31 is designed such that there is no change in the stroke of the hoists 30, 32 and the accumulation of energy in the springs 28 until the locking balls 6 reach the top of the teeth of the locking ratchet 2. the first part of the switch cycle. In the second part of the switching cycle, the spring g, 2 has already acted for a smooth movement of the locking ratchet 2 and on the stroke of the bridge contacts 26. 27. With sufficient strong springs 6 and 2, the contacts can be converted separately, using the potential energy of the springs £ a2 accumulated in the first part switching cycle. That is, with normal continuous adjustment of the switch, the speed of movement of the finger contacts 26, 27 will be substantially determined by the coils 6 and 2 at the time of their maximum compression. In such a case, it is assumed that in the second part of the switching cycle the external force is applied, that is, the force of the hand on the control knob2 opposite the direction of rotation of the locking ratchet 2 by the springs 6 and 2. The control methods allow the first row to accelerate the movement of the point contacts 26, 27 while substantially limiting the dependence of the motion of the square contacts 26, 27 on the application of the external force. The same switching cycle takes place when the knob 2 is turned in the opposite direction to the g direction, as well as in the alternate conversion (FIG. 2). In this embodiment, the angle of rotation of the ratchet actuator 101 is greater than the angle of rotation of the cam stars 103 and 104. OBJECT OF THE INVENTION An actuating mechanism of cam electric spoilers with a locking ratchet fastened by an actuator shaft, wherein a detent member is spring-pressed in at least one toothed ratchet gap, to the Salgej tooth gap (10) of the ratchet ratchet (3), the central tooth (14) engages from a trio of adjacent cam star teeth (13, 14, 15) mounted on the shaft of the electric switch (18), the top one tooth (11) of a pair of teeth (11, 12) of the arresting ratchet (3) defining this tooth tooth gap (10) abuts the side of one outer tooth (13) of the three adjacent teeth (13, 14, 15) of the cam star (16) ), wherein the top of the second tooth (12) of the pair of teeth (11, 12) of the arresting ratchet (3) abuts the side of the second outer tooth (15) of the three adjacent teeth (13, 14,15) of the cam stars (16). 2 sheets of drawings Severograíia, n. P., Race 7. Most