DE922576C - Power locking device for signal clocks, master clocks, time switches, etc. like - Google Patents

Description

Power locking device for signal clocks, master clocks, time switches, etc. Similar current locking devices should, if possible, meet the following conditions: They should be operationally reliable, electrically resilient as high as possible and safe to touch be, respond with the smallest effort in the smallest way, a large contact distance have, can be switched on and off quickly and allow an adjustable contact duration, for example with signal clocks.

The current closing devices on signal clocks, master clocks, Time switches and d g1. generally compromise between the above The points that appear to be particularly important will be realized at the expense of other points.

For example, it is required of signal clocks that their signal and thus their contact duration can be set as desired. Furthermore, these Contacts from the current closing device closed abruptly and after a certain amount of time Opened jerkily again, firstly in order to protect the contacts (avoidance the spark formation over a longer period of time), and secondly, to the beginning of the signal and End of signal not to be blurred. These conditions are admittedly by the so-called Double lever touch contacts met. (These double lever touch contacts will be used almost exclusively in signal clocks today.) However, there is the contact pressure has to be applied by the movement of the clock, experience has shown that its accuracy suffers. In order to maximize the effort required to operate this current closing device To keep it small, the contact pressure as well as the cross section of the contact springs will increase limited to a minimum, the contact spacing is also chosen to be small, because what is saved in travel can be gained in strength. This increases the mechanical security and accuracy of the movement, however the operational safety of the signaling device is worsened in electrical terms; therefore, with the contacts of such a current closing device can only relatively _ small currents with low voltages (not safe to touch) can be switched. For this reason, the signals are actuated via relays. The system becomes more complicated and more expensive. Although with ock silver interrupters the possibility is given to all these demands placed on a current closing device in electrical terms use is not made of it because it is mechanical too great difficulties, the same in short time intervals with relatively slow movements with any adjustable contact duration, both jerky and as well as turn off.

Mercury interrupters have only been used until now if the switching frequency is relatively small, e.g. 72 switchings in 24 hours for time switches, and where the possibility exists. with a mostly designed as a tube carrier Lever or slider to both close and open the contact. The duration of contact can only be set at will if the angle of inclination of the mercury interrupter or the speed of the gearshift lever or the path of the operator who actuates the gearshift lever Drive organ is changed. The current closing device according to the present invention now combines in the simplest way the advantages of the double lever contact contacts with those of the mercury interrupter tubes, so all of a good current closing device the required points. This is achieved in that the carrier has one or several mercury interrupter tubes by two movable support members, for example raised by two levers, roughly parallel to the rest position of the mercury interrupter (s) or shifted laterally and by changing the position of one support member in the switched-on position of the mercury interrupter (s) and by changing the position of the other support member in the switch-off position is brought. She experiences an essential improvement Current closing device according to the present invention, characterized in that the contact duration is changed if the for the time of the fall of the wearer of the mercury interrupter (s) relevant points of the supporting organs are adjusted in their position to one another.

Fig. I shows the current closing device according to the invention as Fine contact of a signal clock; Fig. 2 shows the current closing device according to of the invention on a master clock with follow-up device for switching on every minute the elevator motor; Fig. 3 also shows a current closing device according to the Invention on a master clock with tracking device.

Fig. I: The two levers i and 2 are easy at points A and B. rotatably mounted and slide with their cusps 3 designed as a sliding surface and ¢ on the circumference of the eccentric which rotates once in a certain time unit 5. The support 6 (the mercury interrupter tube i r) is at its left end the left end of the lever i also rotatably mounted in point C and rests with it its right end on pin 7 of lever 2.

With lever 8 the bearing of the lever: 2 can be moved sideways and thereby the contact duration can be set variably. Levers i and 2 will be the most beneficial balanced with counterweights 9 and io so that they are still securely in the eccentric 5 occur, the mercury interrupter i i and its support 6, however, approximately keep your balance. Eccentric 5 lifts the two levers i and 2 and thus the Carrier 6 of the mercury interrupter i i approximately parallel to its original position evenly. If the eccentric 5 has reached the switch-on position, it falls first Lever i into the eccentric 5, the carrier 6 tilts with the mercury interrupter i i to the left. The contact remains closed until eccentric 5 has expired the set signal duration has reached the switch-off position. Lever 2 tilts now also to the left. The carrier 6 with the mercury interrupter i i rotates jerks to the right and reaches its original switch-off position again.

Fig. 2: The two angle levers i and 2 are mounted in points A and B, tube carrier 3 on the free end of the right leg of the angle lever i in point C so that they can be easily rotated. Eccentric q. sits on the gear shaft. Disk 5 represents a control disk, which is slowly rotated to the left by the movement of the master clock in a known manner via a differential gear and, when it is wound up, to the right again in a relatively short time by the same amount. The increases in the curve of the eccentric q. and the control disk 5 in connection with the lever arm ratios of the levers i and 2 are dimensioned so that the free ends of the lever are pivoted to the left by the same amount when the movement is running. The tube carrier 3 is pressed by the weight of the mercury interrupter 6 with its lower free end, designed as a sliding surface, against the pin 7 of the angle lever 2. Does the eccentric q. When the switch-on position is reached, lever i falls into eccentric q. on, so turns jerkily to the left, and tube support 3 with its mercury interrupter 6 swings jerkily to the right. The contact is closed, the motor is switched on. The movement of the master clock is wound up until the winding motor rotates the control disk 5 in a known manner via a differential gear into its rest position, pin 7 on the free end of the vertical leg of the angle lever 2 swiveled the tube carrier 3 to the right and thereby interrupted the contact again Has.

Fig. 3 is basically the same as Fig. 2, but replaces the Tube support i of Fig. 3 the two angle levers 3 and q. of Fig. 2.

Tube support i is guided in an elongated hole by screw 2 and slides with his angled forward left end on the control disk 3, with its forward angled right end on eccentric .4. Has eccentric q. reaches its switched-on position, the tube carrier i tilts due to its gravity jerks to the right and thereby brings the mercury interrupter 5 into the on position. Disk 3 now rotates to the right, driven by the elevator motor, so that the tube carrier slide back into its rest position, i.e. into its switched-off position can. The switch-on process is repeated after 1 minute. Disk 3 turns again slowly to the left, eccentric, 4 to the right. The mercury interrupter 5 becomes parallel raised to its rest position until tube carrier i then again to the right tilts when the eccentric 4. has reached its drop position.

Claims (2)

PATENT CLAIMS: i. Power locking device for signal clocks, master clocks, Time switches and the like, characterized in that the carrier (6, Fig. I; 3, Fig. 2; 1, Fig. 3) one or more mercury interrupter (s) (ii, Fig. 1; 6, Fig.2; 5, Fig. 3) by two movable support members, for example by two levers (1, 2, Fig. I), roughly parallel to the rest position of the mercury interrupter (s) (i i, Fig. i) raised or shifted to the side and by changing the position of one support member (i, Fig. i; i, Fig. 2; q., Fig. 3) in the switched-on position of the mercury interrupter (s) ii, fig. i; 6, Fig. 2; 5, Fig. 3), by changing the position of the other supporting organ (2, Fig.1; 2, Fig.2; 3, Fig.3) is brought into the switch-off position. 2. Power closing device according to claim i, characterized in that the contact duration is adjusted the parts that determine the time of the switch-on and switch-off position (3 and q., Fig. I) of the supporting organs (i and 2, Fig. I) to each other.