DE2333310C2 - Electronic clock - Google Patents

Description

3 4

F i g. 4 shows a block diagram of the drive circuit for a time signal from the signal of the crystal oscillator

a clock and the circuits for the time setting device 20, which are connected to the frequency divider circuit 21

tung; ne drive circuit 22 for the time display and the

F i g. 5 is a circuit diagram for the time reset device; Time display device 23. Between the frequency parts F i g. 6 is a timing chart for explaining the s lerschaliung 21 and the drive circuit 22 is a Reset process; Correction circuit for the time display inserted, the 7 shows a circuit diagram for the time advance device, the positive correction gate circuit 24 with the assigned

and arranged control circuit 25, which by the switch

F i g. 8 a pulse diagram to explain the time S _{1 is} actuated, as well as the negative correction gate

introductory process. io circuit 26 with the associated control circuit 27,

In the case of the FIG. 1 to 3 shown switching mechanism, which is operated by the switch S ₂ , contains When remus a time setting device according to the invention is gular mode of operation of the clock, the switches Si and & the switching element 1, which opens the winding shaft of a mechanical switching mechanism described, wherein see clock, the correction gate lock 26 is permeable in both directions of rotation and the cord rotatable and adjustable in lengthwise direction 15 rektur gate lock 24 is locked Via the front-acting drive circuit 22 via the negative correction gate coupling wheel 2, which is fed via a square hole to the circuit 26 one-piece design, the two ratchet wheels 4 and 20 to correct the time display by a constant period of time. 5 Made of insulating material, the teeth of which are opposite to one another, come into a position in which, for example, the opposite orientation in the one shown in FIG. 3 each for switch S ₂ for the negative time correction closed a ratchet wheel are formed in an evident manner. The is and the control circuit 27 is actuated, the contact spring 6 is attached to its one end, while the correcting gate circuit 26 for the negative time correct its other end is locked between the teeth of the switching door, and therefore the output pulse of the wheel 4 protrudes The contact spring 7 is also attached to its frequency divider circuit 21 not to the drive circuit at one end while its other end reaches between 22, so that no impulses are supplied. The teeth of the ratchet wheel 5 protrude Timers 6 and 7 alternately come into contact with show by a constant period of time corresponding to one of the contact pins 10 or U, if the sound ad 30 pulse spacing of the pulses are carried out from output 5 either in one or the other direction 21a of the frequency divider circuit 21 released, is twisted. Therefore, if the switch Si is closed for the positive time correction together with the contact pin 10, the control is

51 and the contact spring 7 with the contact pin 11 a circuit 25 is actuated so that the correction gate salt widths Switch S3. The actuation of switches Si and 3s device 24 sends an output signal to the input terminal

5 ₂ enables an electrical correction of the time display 26a of the drive circuit 22 emits in combination. with the regular pulse coming from the output 21a of the

If in the position shown (time correction position) frequency divider circuit 21 is output, so that the winding pinion 3 in the direction of arrow A 'in FIG. 1 (in a positive time correction by a period corresponding to the pulse spacing dependent on the rotation of the switching element 1 in 40 speaking.
Is rotated in the direction of arrow A), the contact die in FIG. 5 shown negative correction circuit spring 6 because of the engagement with the teeth 4a of the consists of the correction gate circuit 26, the control switching wheel 4 bent and comes into contact with circuit 27 and the switch S ₂ . F i g. 6 shows an Imdem contact pin 10. The switch Si is thus closed in a pulse diagram to explain the mode of operation of this when the switching element 1 is switched in the same direction. In this example, if the one to be corrected is to be rotated further, the contact spring 6 of the tooth time unit will be one second, and in FIG. 5 is there-4a released urid returns to the starting position. There is no frequency divider circuit for a further frequency divider, but the ratchet wheel 5, which is integrally formed with the pull-up slot 3 frequency division of the output signal of the frequency divider, is also provided in the same circuit 21. However, since the teeth 5a of the indexing wheel 5 have a time pulse 1 S - Φ ats output every second in the opposite orientation compared to the signal of the frequency divider circuit 21. This signal has teeth of the indexing wheel 4, the con - the phase Φ. The correction gate circuit 26 is normally pressed against the pin 9, so that it is also permeable, so that the output 26a always gives no connection to the contact pin 11, the signal of the input 21a. If that is available now. This keeps switch S2 open. 55 Switch S2 is closed, the gate circuit G «If, on the other hand, the switching element 1 is blocked in the opposite direction, so that there is no pulse at output 26a! S— (If the print is turned in the direction of rotation, the switch Si is unlocked for the period corresponding to a pulse interval, while the switch S \ is kept open

Therefore, either a positive or a negative can be determined from FIG. 6 should explain this working method in more detail Correction of the time can be clarified by optionally pressing the switch bo. When the switch S ₂ for the negative Si and Si take place. Furthermore, if the switching element 1 is briefly closed from the time correction, the Time correction positions by one or two levels Flip-hop circuits FFi and FF2 to the state »1«

is pulled out, the clutch wheel 2 is adjusted from the. From the frequency divider circuit 21 in

Winding pinion 3 is decoupled and comes into engagement with F i g. 4 is the entrance 30 of the now permeable gate

a dial for the pointer setting or for the b5 circuit G ₂ the signal 1 S - π supplied, its phase

Day and date correction. by λ-compared to the phase of the signal 1 S-0-phase The schallung shown in Fig.4 contains the quartz is shifted. This creates the flip-flop circuit

oscillator 20, the frequency divider circuit 21 for deriving FFje adjusted.

As a result, the negative correction gate circuit 26 is blocked, so that the next pulse 1 S - Φ which arrives at input 21 * after half a second, and in FIG. 6 is marked with "A" can no longer be forwarded. Therefore, the drive circuit 22 for the time display 23 in FIG. 4 one less pulse is supplied, so that the second hand remains there for another second and the time display is thus reduced by one second. At the same time, the gate circuit G _{3 is} controlled to be permeable

The pulse A therefore occurs at the output thereof and causes the flip-flop circuits FF ₂ and FF _{3 to} reset. The flip-flop circuit FFj is a JK circuit and is reset by the trailing edge of the pulse A , as shown in FIG. 6 is indicated by the arrows 5. The reset flip-flop circuit FF ₂ opens the gate circuit Gi.

The flip-flop circuit FFi is reset by the output signal of the gate circuit Gi. The input signals of the gate circuit Gi are the output signals of the connection Q of the flip-flop circuit FF ₂ and the reset pulses fed to the input S \; At the output there is therefore the pulse train C. Since there is a difficulty that the actuation of the switch S _{2 is} not always terminated before the end of the time correction process because the switch S ₂ in the embodiment according to FIG. 1 and 2 is actuated mechanically, the reset pulses are fed to the gate circuit Gi so that the flip-flop circuit FFi is reset exactly in the grid of the reset pulses C , i.e. regardless of the length of the switching duration.

In the circuit shown in FIG. 7 and the associated pulse diagram in FIG. 8, a pulse 1 S— π with a phase π occurs at input 216, in contrast to the time pulse 1 S— Φ with phase Φ in FIG. 5, The correction gate circuit 24 is normally blocked so that normally no signal occurs at its output 24a.

When the switch Si is operated, the flip-flop circuits FFi 'and FFi are set and the gate circuit G _{2 is} permeable. Thus, the flip-flop circuit FF3 'is activated by a pulse! S— Φ which is fed to input 32 of gate circuit G _2. The gate circuit G «'is thus permeable. As a result, a pulse 1S-λτ applied after half a second via the terminal 216 occurs at the output of the correction gate circuit 24 after this half second, which causes an additional time adjustment of the second hand by 1 second.

The mode of operation described in connection with FIGS. 5 and 6 is the same as that in FIG. 7 and 8 with the exception that the pulses 1 S-π fed to the terminal 2 \ b have a different phase than the pulses 1 S- Φ at the terminal 21a and that the gate circuit Gt in the normal state is in the opposite state to that Gate circuit G «in Fig. 5.

The drive circuit 22 in FIG. 4 can be designed so that in one case it contains some stages of the frequency divider circuit and in the other case it does not contain these if the time display mechanism contains a stepping motor, a cooperating gear train and pointer For example, the stages of the frequency divider circuit for driving the second hand are not every one second included in the drive circuit 22 because the time correction in the unit of 1 second is appropriate for practical purposes. However, those stages of the frequency divider circuit may be included in the drive circuit 22 which drive the hour hand and the minute hand, because the time correction corresponding to a fraction (n: integer) of a minute,

for example 30 or 15 seconds, practically appropriate is

That derived from the frequency divider circuit for drive 10 or for controlling the correction circuit Signal can also be a signal other than signal 1 S-λ ·.

In addition 6 sheets of drawings

Claims (2)

1 2 be switched; but therefore always the electrical Claims: Function of the clock until the actuation is released facility to be stopped. After that, some- t. Electronic clock with one oscillator and one dependent on the skill of the user ner frequency divider circuit for generating a point in time the function of the clock resumed. Drive pulse train for actuation of a time display, however, there is an unregulated phase position, as well as with a resumption of the clock function which is precise to the time correction Setting device for actuating the significant disadvantage of the known clock represents two switches to selectively over a control switch- By DE-OS 2115 685 another clock is the- A positive or negative time correction of this kind is known, in which between that as frequency norm to perform a predetermined time interval serving the oscillator and the downstream, characterized in that the frequency divider circuit has a gate circuit the frequency divider circuit is a device that arranges the supply of normal incremental pulses Generation of an opposite to the drive lens when a changeover switch is actuated by the actuating pulse train (1 sec-tfMpulszug) phase-shifted li device prevents such clocks are by no means Pulse train (1 sec- ^ r-pulse train) has, d?, 3 by user-friendly, dsnn it is difficult the position each time an actuation of a switch to actuate a direction just at such a point in time two pulse trains of derived additional genes after the time has expired at which the clock Drive pulse of the time display device to which it had proceeded. Continuation can be supplied, and that by each 20 through US-PS 32 62 259 are further such an actuation of the other switch known the supply measures with which the switching of a normal drive pulse by using pointers or digital display means, however, likewise connection of the two pulse trains must be interrupted in order to generate a positive or negative 2. Electronic clock according to claim 1, characterized to perform tive time adjustment, wherein the sub-denotes that the adjusting device a switching 2s break takes a full minute member (1) which can be rotated in such a way and between At least two layers of longitudinally displaceable clocks are an adjustment of the time net that in one position, when rotating in the measuring device, represents within one second because the one direction actuates the first switch (S 1) bar must be carried out in order to carry out the positive time correction, 30 position without this interruption and when the position of the time measuring device consisting of oscillator and frequency switch (S2) can be operated in the other direction, in order to make the negative qucnzteiler, these known clocks must be time corrected . no longer to be regarded as adequate if they were previously went exactly. 35 The subject of patent 22 56 540 is an electronic wristwatch with a pointer mechanism driving Stepper motor and the other usual parts The invention relates to an electronic watch which is provided with a switch with which through according to the preamble of claim 1, briefly actuating the stepper motor an additional limit an oscillator and a frequency divider circuit 40 Ches alternating drive signal thereby supplied to generate a drive pulse train for Bctäti- is that its part with the one polarity after the supply of a time display device as well as an output of the counter circuit and its part Adjustment device enabling time correction to operate with the other polarity by switching on the tooth actuation by two switches to selectively generated via a lers, and with which switch by ent control circuit a positive or negative time correction is switchable according to a predetermined time interval. perform. The invention is based on the object to Such clocks are required by DE-OS 21 07 433 all-implementation of time corrections common knowledge. Thereby the digital displays will simplify measures and the incremental accuracy of Hours with a 1000 Hz signal and therefore the clock cannot be changed by the correction in approx. 50. 3.6 s per hour division, the minutes with a This task is by the in claim 1 £ 60 Hz signal and thus resolved the measures marked in approx. 60s per minute division. and those of seconds with a 2 Hz signal! and thus an advantageous further development of the patent application in V ₂ s per second division in the positive direction (measures marked in preamble 1 is the subject matter -!; _i move the time display) and with the switching off of claim 2. || drive signal in the negative direction (reset the details and those achieved with the invention Time display) changed. With the impression of a beta advantages are indicated in the following description a switching device will be effective. sam, which is optionally the lead of an hour, minute, based on the drawings, the invention is intended as an example The time or seconds display is initiated or the way of feeding is explained in more detail. It shows tion of incremental pulses prevented, and with the F i g. 1 is a plan view of an expediently designed Letting go of the actuating device starts the clock switching mechanism, which is used in the invention can be wci · gcsel / .l again with its normal function; tcr / .run. Thus, in the case of a positive expression, l ^; i g. FIG. 2 is a cross-sectional view of the FIG. I presented len the seconds display the 1-second increment im- μ set switching mechanism; pulse switched off by the display device and there- F i g. 3 is a side view of the ratchet wheels of the in for the '^ -second incremental pulses from any switching mechanism shown in FIGS. 1 and 2 to the Place of the frequency generating device her pulling face of the relevant ratchet wheel seen;