DE907880C - Wireless controlled clock - Google Patents

Description

Wireless controlled clock i. General For those known to this day Clocks are driven by spring mechanisms, weights or electrical ones Works (mains or battery). All clocks work as a result of their own Drive completely independent of each other and therefore show more or less different Time to.

In the case of the wirelessly operated clock described here, according to the invention the drive full several seconds come wirelessly through a central installed transmitters or by several distributed transmitters, but which then on the same Wave work and be controlled centrally, with the clocks themselves without their own Work with power or without your own drive and from your centrally located transmitter or one is sent out every minute by the several distributed transmitters, which all clocks by means of receiving circuit arrangements that are assigned to them and matched to the impulse and with these connected indexing mechanisms moved forward by i minute. at All stationary clocks can receive the high-frequency pulse before it is performed Work can be amplified by one or more electron tubes as in radio reception.

2. Mode of operation for stationary use (see Fig. 2) A central transmitter or several evenly distributed transmitters emit a high-frequency pulse lasting several seconds every minute. This high-frequency pulse arrives via the antenna ANT and the capacitor Cl to the resonant circuit, which is tuned to the transmitter frequency and consists of the coil L and the capacitor Ca (Ca is designed as a trimmer capacitor in order to be able to retune the resonant circuit). The incident high-frequency energy creates an increased negative bias voltage at the control grid of the tube h, which in this case works as an electron-coupled audio, and this in turn results in a decrease in the anode current. It follows that the iron core of the precision relay R, which is only shown in Fig. is moved forward by one tooth. This gear has oo teeth; So it will accomplish one revolution with Co impulses (= 60 minutes or i hour). By corresponding numbers of teeth on the other three gears it is achieved that the fourth gear, which is firmly connected to the hour hand, only makes 1/12 of a turn with 60 pulses. Rn, Rl, R2, R3 and Cg, C2, C3 and C4 are the common switching elements in an audio circuit with a pentode as a tube. In addition to the electron-coupled audio circuit, any other audio circuit with grid and anode rectification can also be used.

3. Ways of working in the case of a transportable type of use (see Alrb. I) The high-frequency pulses emitted by one or more transmitters (as under 2) get to the coil L, which also serves as an antenna and with the trimmer capacitor Ca forms an oscillating circuit which is tuned to the transmitter frequency. the incident high frequency energy is from detector D, which acts as a crystal detector or can be designed as a crystal diode, rectified and then flows through the coil of the fine relay R (same function as with the detector receiver, only is The fine relay R has been used instead of the headphones). The iron core of the fine relay This makes R magnetic and attracts armature A. This in turn has the consequence that the first gear with 60 teeth, which is firmly connected to the minute hand is moved forward by one tooth, i.e. z minute. The further consequence is as in Fig. 2. The capacitor C serves to calm the rectified high frequency and can be omitted under certain circumstances.

Regarding 2 and 3 The arrangement according to Fig. I can also be used for stationary Attachments are used; it is then only antenna, as shown in dashed lines and earth or counterweight connected. The reverse can also be done according to the arrangement Fig. 2 can be used for transportable systems. While in systems according to Fig. 2 the fine relay R can be designed to be less sensitive, this must be for systems According to Fig. i, the smallest currents in the order of magnitude from zO-B to 10 -12 amperes speak to.

The fine relay R works in Fig. I in operating current version, while it can work in open-circuit or closed-circuit current version in Fig. 2, depending on the use of the audion in grid or anode rectification.

Lead examples for types of use: Stationary: Railway clocks, church clocks, Wall clocks, car clocks il. like; transportable: pocket watches, wristwatches.

Advantages of the new invention: i. Uniform time everywhere; 2. no Movement required more, no winding of the clocks is required; 3. upon execution According to Fig. i, no mains or battery power is required.

Claims (1)

PATENT CLAIM: Remote-controlled L'hren drive, characterized in, that the drive is wireless via a centrally located transmitter or several distributed transmitters, which then work on the same shaft and are centrally controlled takes place, with the clocks themselves without their own power or without their own drive work, and from the transmitter or transmitters every minute a few seconds High-frequency pulse is sent, to which all clocks are assigned by them, receiving circuit arrangements adapted to the pulse and connected to them Progress mechanisms moved forward by 1 minute.