DE692142C - Power reserve for synchronous clocks - Google Patents

Description

Power reserve for synchronous clocks The invention relates to synchronous clocks with auxiliary gear, in which both drives are connected by an overhaul gear are and so work on a common display gear that the faster gear drives the pointer.

From the known devices with revolving locking couplings the subject of the invention differs in that the common display drive wheel each with one on compliant parts, e.g. B. pivot levers, in brackets or slots Pivoting gear of the synchronous mechanism and the aid organization meshes and the toothing and storage is designed so that the faster running of the two gear wheels the common gear wheel takes along, while the other Gear at times, to skip a tooth, is pivoted ver. Through this Pivoting movements or resulting changes in position and pressure of the flexible Driving wheels or their bearings can have the following effects, individually. or combined, are made possible: r. An acceleration of the auxiliary clock during auxiliary operation; 2. a pushing of the pointer, which was then moved too slowly by the aid organization; 3. Contraception an overhaul of the pointer driven by the synchronous mechanism due to the somewhat undesirable advancing aid organization; q .. notification of the beginning, continuation or end of a synchronous clock fault; 5. Reduction in the number of overtaking jumps.

In contrast to a well-known suggestion that arises during auxiliary operation Compensate for minus errors by using the synchronous The auxiliary clock speed is reduced by the synchronous motor, acts according to the present Invention of the motor not on the regulator of the auxiliary clock. The auxiliary clock is running constantly too slow, then (according to number z) your regulator becomes during the auxiliary operation accelerated or (according to item a) the pointer then moved too slowly by the aid organization additionally accelerated. Both types of acceleration are not made by the motor, but by the pivoting movements of the flexible ge = bearing parts of the synchronous engine, d. 1i :; by the aid organization itself. On the other hand, the pointer cannot be overhauled by continuously running and unaffected aiicl @ slightly leading aid organization while the engine is running (number 3) Pressure redistribution at the flexible meshing of the drive wheels are prevented, by displacing the synchronous drive wheel from the position of engagement during control gear prevented and benefited in the event of a power failure, on the other hand that of the auxiliary clock drive wheel, vice versa, is made easier in normal operation and more difficult in auxiliary operation.

Thanks to the flexible bearings, detectors can also be activated. which malfunctions are looking for or audible or by means of writing or counting arrangements Show. Such, particularly audible alarms make the use of simple and cheap starting motors, because the clock warns you to start the motor.

As a further advance, a locking device should be mentioned, which the flexible storage for a certain period of time in a crowded position and by reducing it the number of overhaul jumps reduce the overhaul work of the auxiliary watch or can improve the control effect.

According to Fig. I, the pointer wheel z is in constant engagement with the drive wheels 3- of the synchronous work and 4 of the aid organization. In the normal course, the wheel 3 drives the with the wheel 2 connected pointer i synchronously in the direction of the arrow. The auxiliary clock wheel 4 is constantly being overtaken because it runs more slowly; thereby his bearing block 6, at every change of teeth, in the direction of its arrow, pivoting around point 6a, against the Spring 8 pushed out of the engagement position of the gears. These are climbing jumps seldom with a small minus error in the auxiliary clock.

When the synchronous wheel 3 is at a standstill, the wheel 4 drives the wheel 2 with it somewhat sub-synchronous speed; the 5a pivotable bearing block 5 makes each Tooth of wheel 2 made a climbing jump. With each stroke, the spring 14 presses on the Boom on pendulum I i and accelerates its oscillations during auxiliary operation. By pushing the locking lever 9 upwards by 911, the bearing block 5 is deflected in the Position held until the lever 9 is moved down by a pin on the pointer wheel 2 and the lock is removed. The duration of the pendulum acceleration through the spring 14 can be controlled by selecting the number of pins on wheel 2, as well as the number of Message strikes of the clapper. on the bell-32. By reducing the number of climbing jumps the overhaul work, the auxiliary clock is reduced.

In the embodiment according to Fig. 2, the run is too slow the auxiliary watch does not accelerate even in auxiliary mode, but rather through the climbing jumps of the stationary synchronous drive wheel 3 moves the oscillating bearing block 5 by means of the forward pawl 21 located on his arm 2o turns the wheel 22 counterclockwise. As a result, the pointer setting wheel, which can rotate with the pointer i, rubbing on the axis of the wheel 2 34. or the pointer i accelerates, so that the compensation of the minus error of the auxiliary clock by advancing the pointer, i.e. by level control. ' By means of the viewing window 23 or the contact 24 can with each climbing jump of the wheel 3 or his Bearing block 5 the malfunctions of the normal operation are searched for and or audibly reported. If a detector is connected to the network by means of contact 24, it can in itself as is known, the return of the voltage can be reported. These reporting options favor the use of starting motors, because starting can be called.

According to Fig. 3, a permanently correct or also slightly leading Aid organization are used. Its run remains unaffected in normal or auxiliary operation. On the other hand, with this arrangement, the auxiliary clock has an influence during the control cycle "on the pointer -prevented by, supported by a magnetic mains current effect, by means of the rocker 26, the holding pressure for the synchronous wheel engagement by the spring 29 reinforced, on the other hand, the holding pressure for the engagement of the auxiliary clock wheel 4 by the relaxed spring 28 is weakened, so that the approximately weakly leading auxiliary clock wheel 4 is unable to overtake the firmly engaged synchronous clock wheel 3, but must slide out of engagement with the wheel 2. In the event of a power failure, the Spring 27 the rocker 26 out of the position shown. Then the pressure is reversed Spring 28 on the arm of the bearing block 6 stronger and the .der spring 29 on the Bearing block 5 weaker, so that the now firmly held in engagement with the wheel 2 Auxiliary clock drive wheel 4 can move the pointer wheel 2 safely without any noticeable loss of accuracy and can overtake the stationary synchronous wheel 3. Because the wheel .I with friction on its axis is arranged, it is in the event of the auxiliary clock remaining from the Synchronous clock pulled through.

The locking lever 9 is rotatable about 911; he locks the bearing block 5 by means of the arm 3 1 and the rocker 26 on its arm 30 during the auxiliary operation, until after voltage return this latching of the pointer gear from z. B. solved by a pin on. Pointer wheel 2 and the incidence of parts 3o and 9 is released in the normal operating position.

Instead of pivoting bearings, the front journals of the wheels 3 and 4 also 'in another way, e.g. B. in radial direction to the wheel: 2 slotted bearings, yielding .be arranged.

Instead of the pendulum, you can use a riot, a spring pendulum or any other Flow regulators, such as braking means of any kind, can be used.

To re-tension the auxiliary clock drive force, the synchronous motor can be used in a known manner Way to be used.

Claims (3)

PATENT CLAIMS: i. Synchronous motor with power reserve, in which both Drives work simultaneously on a common gear wheel, characterized in that that the common gear wheel (2) _ as a gear with one on each flexible parts (5, 6) mounted gear of the synchronous mechanism (3) and the auxiliary mechanism (q.) Meshes and the toothing is designed so that the faster running of the two gears (3, 4.) the common gear wheel takes along, while the other gear wheel temporarily to skip a tooth is aggravated. The swivel movement is in the event of a power failure and standstill of the synchronous gear for pointer position, acceleration of the escapement regulator, for reporting and / or registration devices or to reduce the number of overtaking jumps used. 2. Synchronous motor with power reserve according to claim i, characterized in that .that the movements of the bearing block (5) of the synchronous gear during the engine standstill act on the regulator (i i) to accelerate by means of a spring (i4). 3rd synchronous motor with power reserve according to claim i, characterized in that a bearing block - (5) of the synchronous gear moving switching element (2o, 21) the pointer (i) during the engine standstill also drives forward. Synchronous motor with power reserve according to claim i with aid organization set to the correct course or to advance, characterized in that that an electromagnetically controlled part (26), e.g. B. by means of tension springs (2S, 29), with control elements the swiveling of the synchronous drive wheel (3) is prevented and that of the auxiliary gear (4) from the common gear (2) favored, however in the event of a power failure, the auxiliary gear wheel (4.) is prevented from swiveling and that of the synchronous gear (3) favors.