DE905594C - Procedure for testing watches - Google Patents

Description

Method for testing watches In the previously known methods to check the accuracy of clocks (timing machines) are for the normal clock (N-clock) and the displaying or registering device requires two components. Using a quartz watch as the time standard are the electrical oscillations generated by the quartz transferred to a synchronous motor and with this a registering timing machine operated. In other methods, clocks of ordinary design are used as the time standard used, which is then used to control B.raunschen via microphone and amplifier Tubes or can be used for registration systemsa Also the use of vibrating tongues, similar to tuning forks, is known as the time standard. There too the oscillations of the N clock must be converted into electrical impulses and can then only be used to control the actual timing machine.

In your new procedure to be protected, the detour between time normal and timing machine avoided.

On a vibrating body (pendulum, balance wheel or similar) with a certain Oscillation number is attached to an inertia-free light source G (glow tube, Fig. I). This light source is powered by impulses of electricity generated by the noise of the device under test Clock (X clock) generated by means of microphone M and then amplified in h to light up brought. If the light flashes in both directions of oscillation (from L to R and R to L) this vibrating body is visible, one could deviate of the X-clock from the time normal given by the vibrating body -bad determine. But if the flashes of light are only visible in one direction of oscillation, so one can quickly find a gear difference between Determine the N o'clock and X o'clock.

A pendulum or a balance wheel is best used as a vibrating body Use. Since it is difficult to find such, vibrating bodies with the number of vibrations normal pocket and wrist watches (five individual oscillations per second) in sufficient To produce precision, a slower swinging pendulum or balance will be useful used. This also ensures that the light source covers a greater distance can and also small rate deviations are quickly visible.

When using a vibrating body, the two simple vibrations per second, with one oscillation there are usually two: flashes of light, triggered by two beats of the X-clock, in a short time interval (11s second), but spatially far from each other (at least half of a simple oscillation) visible. When the vibrating body swings back, the light source remains dark, and with the next oscillation, both light flashes will come on when the X-clock is exactly going same; place appear. Should the drop of the X clock be unequal, then step in this case a lateral shift of the flashes of light, and only at the In the next visible oscillation, the lightning bolts appear again in the same place. This phenomenon occurs because the ratio of X o'clock to N o'clock in this Trap 5: z is and the flashes of light caused by input and output decay of the gear wheel on the armature or cylinder of the X-clock, alternately in the same place appear.

If an elongated glow tube is used as the light source, leave it alone the background noises of the X clock, such as stripes of the balance wheel or spiral, recognize well, since even the weakest noises with sufficient amplification still can be made clearly visible and the covering of the electrodes in the glow tube in length and strength at: different strong current surges fluctuates. It then arises a sound image similar to that produced by an oscilloscope.

To make the flashes of light only visible in one direction of oscillation to let, a contact can be actuated by the vibrating body, which the Turns off the light source in one direction of oscillation: Even with a small movable one Diaphragm, which is in one direction of oscillation in front of the light source, can serve this purpose can be achieved. (Dept. i, aperture B).

If two light sources GI and G2 (Dept. q.) Are attached to the vibrating body, one can be switched on in direction RL and the other in direction LR. An inaccuracy of the X clock will then become visible in one direction of oscillation due to the light flashes migrating to the left, in the other direction to the right. A diaphragm that allows half of the light source to be seen in one direction and the other half in the other direction of vibration can also be used to observe the movement of the flashes of light to both sides (Section a).

In another construction of this type of timing machine, one or several fixed light sources can also be used. The ones from these light sources The emitted flashes of light are then passed through one or more slits that are in a vibrating body moving in front of the light sources, observed will. Is this slot S (Abt, 3) wholly or partially in one direction of oscillation closed or the light sources switched off in one direction, then in In this case, a gear difference can be easily determined. With fixed light sources these must be stronger because they have to illuminate a larger area and through the slits used, only part of its light is effective. Therefore, the current impulses originating from the X clock also have to be amplified more. The pendulum or balance wheel can be driven electrically or according to known methods be done mechanically. These can also be used as the regulator of a clock at the same time -will.

Since when using a pendulum or balance wheel with relatively simple Can achieve a high accuracy means, the present method is likely to Economic efficiency surpass the previous timing machines.

Claims (1)

PATENT CLAIMS: i. Method for checking the rate of clocks, marked by using a light source, which is generated by the current pulses emitted by the Noises from a watch to be tested are generated by means of a microphone and then amplified, is made to light up; this light source eats on a swinging back and forth Body with a certain number of vibrations and is secured with a switching device, which is actuated by the vibrating body, switched off in one direction of vibration. a. Method according to claim i, characterized in that two light sources have are attached to the vibrating body; of which one in the one and the other is switched off in the other direction of oscillation. 3. The method according to claim i, characterized in that the light source is not switched off, but is covered in one direction of oscillation by a screen. Method according to claim i and 3, characterized in that the light source is in one direction of oscillation is partially covered and covered in the other direction to the other part. 5. Method for testing watches according to Claim i, characterized by the use of fixed light sources behind a body swinging back and forth certain number of vibrations, which are their light through a small opening throw, which is attached to the vibration body. 6. The method according to claim 5, characterized characterized in that the light sources are not switched off and the opening in Vibration body is closed in one direction of vibration. 7. Procedure according to Claims 5 and 6, characterized in that the attached to the vibrating body Opening partially closed in one direction of oscillation and in the other direction of oscillation to the other part is closed. B. The method according to claim 5, characterized in that that one or more light sources in one direction of oscillation and others in the other vibration direction are switched off. G. Method according to claims i to 8, characterized in that a pendulum is used as the body oscillating back and forth will. ok Method according to claims i to 8, characterized in that as back and forth a balance wheel is used for the vibrating body. i i. Method according to claim i to io, characterized in that the oscillation time of the oscillating back and forth Body one or more times the normal oscillation time of the clocks to be tested can be.