DE580959C - Clock system - Google Patents

Description

Clock system It is already known to drive clocks by synchronous motors, whose speed is proportional to the supplied frequency. The accuracy of the time depends on the accuracy of the frequency maintenance. Basically already two different modes of operation known, namely those systems in which the Operation of the clocks takes place independently of the power distribution network, and such systems, where the clocks are connected to the distribution network. With the first a special control frequency is generated and transmitted to the clocks. This can either be through a special line between the frequency generator and the clocks or through the power distribution network itself by adding a frequency deviating from the operating frequency is superimposed. Systems designed for The operation of the clocks require a special auxiliary network are generally very expensive and uneconomical and can therefore only be used in special cases Find. But also the systems in which the control frequency is superimposed over the alternating current network is transmitted, have significant disadvantages, since the generation and supply of the superimposition frequencies to the clocks not inconsiderable difficulties prepares. In particular, such arrangements have the disadvantage that through higher harmonics of the AC operating voltage and others on the transmission line occurring 'oscillation processes a wrong movement of the clocks can be brought about. For the reasons given, only clock systems have gained practical importance where the clocks are directly connected to the AC distribution network and in which by maintaining an average constant frequency of the generators, preferably by keeping the mains frequency constant, the correct time display is guaranteed. The operation of such clocks takes place in the known systems in such a way that a comparison clock is present, a synchronous clock and a Contains normal clock, and in the event of deviations of both on the drive element of the current-supplying one Generators acts. If the generator supplying electricity is temporarily running too low Frequency, the synchronous clock remains behind the normal clock, and you can restore the correct time display by using a correspondingly long Time lets the generator run at a higher speed of rotation. A Such a control method in which an intervention in the control of the electrical current-giving Machine is required, in particular then has different Difficulties when several machines work in parallel on the same network. In such a case, intervention in the control would only result in one machine changes the active and reactive load distribution of the network. To get from such changes to become free, it has also been suggested to simultaneously access the Generators working on the network to increase or decrease the frequency. Such processes are also encountered in various modern power plant operations operational difficulties.

According to the invention, the difficulties in the operation of the known clock systems with connected to an alternating current light network and with synchronous clocks fed or monitored by the mains below the normal frequency Use of a comparison clock common to the synchronous clocks, which in the event of a deviation the time information of the synchronous clocks is automatically corrected by the information of the normal clock or adjustment of the clocks, thereby avoiding that the comparison clock is independent from the frequency control of the network only to the synchronous clocks via a control line acts and thereby automatically the readjustment using switching devices the clocks to the state of the normal clock causes. In the normal case, the clock system According to the invention, the regulation of the synchronous clocks by keeping the frequency as accurate as possible made in the headquarters. But if for any reason a change in the Generator frequency occurs and thus the display of the synchronous clocks from the data the normal clock deviates, so the correcting or readjustment of the clocks immediately, d. H. made without interfering with the regulation of the power generator. The comparison clock only has an effect on the synchronous clocks if there is a time discrepancy is available. Since, in the arrangement according to the invention, the comparison clock is responsible for the frequency control of the network is not influenced, it can also be used in such networks, where a special frequency control is not provided at all. From this it follows that the special comparison clock is also at one of the installation sites of the Generators can be placed in a remote location, so that they only operate on one Power supply unit or acts on the system of individual consumers equipped with clocks and only in this power supply brings about the readjustment of the synchronous clocks. The adjustment the synchronous clocks by the special comparison clock should preferably be made thereby that they are directly connected to the adjustment motors by means of a special control line of the synchronous clocks acts or that the comparison clock after switching off the Synchronous clocks containing power supply from the rest of the network briefly the clocks connects to a higher frequency power source.

The slave clocks controlled by the comparison clock are with synchronous motors equipped, which compared with the occurrence and during the duration of a time deviation a control clock can be influenced by the comparison clock in such a way that it can be readjusted the pointer effect. One can make the arrangement so that this re-enactment only in the event of larger frequency errors or if there is no power occurs. There can also be special synchronous motors for readjusting the clocks as well the synchronous motors used for normal operation are provided, in which case these special synchronous motors set the hands of the clock at greater angular velocity drive to shorten the reset time. Such a shortening of the reset time is also guaranteed if the system fails when a time discrepancy occurs the synchronous clocks disconnected from the normal network and connected to a power source The frequency of which is much greater than that of the normal Generators possible frequency increase. So in this case too it will be up to Compensation of the time deviation results in a faster rate of the clocks to be regulated.

Exemplary embodiments of the invention are shown in the drawing.

Fig. I and z show the adjustment device connected to the master clock in front view and in section, seen from the side.

Fig.3 illustrates a control unit on a larger scale, -Fig. q. gives a circuit diagram of the adjustment device and slave clocks, Fig. 5 shows the circuit diagram a modified embodiment with a special power generator of higher Frequency.

The adjusting device according to fig. I and 2 is contained in the master clock one with an independent drive, e.g. B. spring drive, equipped control clock; which themselves are driven counterclockwise by synchronous motors 28 or 29 will. A pointer of this control clock, which acts on a switching element, keeps its Position in space when the angular velocity with which the control clock is rotated counterclockwise, exactly the relative angular velocity of the clock hand opposite - corresponds to the control clock. A normal clockwork io is arranged between two circuit boards 1i and 12. The main drive spring is located located inside the drum 13 and can be drawn by a shaft 14, the through the board 12 is enough and firmly connected to a gear 15 is. A shaft driven at the angular speed of a minute hand 16 extends through the board 12 and is firmly connected to a pointer 17, which as Control element of the adjustment device acts. On the shaft 16 there is still a small one Gear 18, the meaning of which will be explained later.

One turn of the entire clockwork movement counterclockwise to enable, this is mounted on a large gear 1g, whose axis with the axis of the minute shaft 16 lies in a line. The gear 1g is by means of a Sleeve 2o mounted on a stub axle 21 which is fastened to a base plate 22 is. The sleeve 2o is held by a screw 23 on the stub axle 21, and this screw 23 also carries a fixed gear 24. When the gear 1g rotates, a gear 25 meshing with the fixed gear 24 is also rotated and drives a gear 27 on the other side of the movement through a shaft 26. The wheel 27 engages in the gear 15, which sits on the spring shaft 14, and pulls open the pen. The gear ratios are chosen so that the nib is normally in is drawn up to the same extent as it expires.

The wheel 1g can be countered by a motor 28 or a motor 29 driven clockwise. These motors are useful as self-starting Synchronous motors built as those for driving electric clocks have become known are. The motor 28 drives the wheel 1g normally so that this wheel during i makes one revolution for an hour. For this purpose there is a gear wheel 3o on the motor shaft provided, which meshes with a gear 31. The gear 31 has a scoring 132 connected, which in turn meshes with a gear 33. The gear 33 rotates on an axle mounted on a gear 34 and connected to a Gear 35. The gear 35 meshes again with a gear 36, which with a gear 38 sits on one and the same shaft 37 and is firmly connected to this. The gear 38 finally drives the gear 1g. In normal operation, the gear 34 is stationary still, so that the wheels 33, 35 form a countershaft with a fixed axis. While during the adjustment process, however, the motor 29 drives the gearwheel via a gearwheel 3g 34 also on, in such a way that the control clock turns anti-clockwise is rotated. The rotation of the gear 34 and the associated reduction gear 33, 35 around the axis 37 increases the angular speed with which the gearwheel 1g is rotated so that the readjustment takes place quickly. For example, can the angular speed of the gear 1g for the adjustment process ten times as great than in normal operation.

The control element z7 becomes like a minute hand relative to the clockwork io turned around once an hour. This pointer-like control element therefore remains during normal operation, d. H. if. only the motor 28 is running, standing still in the room. Puts but if the motor 28 is off due to the absence of the mains current, the pointer moves 17 clockwise in the room. The angle by which this pointer is from its normal Position deviates, is a measure of the duration of the power interruption. As the slave clocks if there is no mains current as well as stopping the motor 28, there is the deviation of the pointer 17 is also a measure of the angle by which the minute hand of the slave clocks have to be readjusted.

The pointer 17 is therefore suitable as a control element for the adjustment process.

For example, Figure 4 shows a circuit diagram of a clock system with several Slave clocks that are regulated by an adjustment device according to the invention. The slave clocks 42 are all equipped with two synchronous motors that are based on the Pointers act through a planetary gear with the same gear ratios as the motors 28, 29 on the control clock, so that the readjusting movement of the pointer for example ten times as fast as their normal movement.

The lines 40, 41 are the normal lines of the alternating current network. The two motors of each slave clock are connected to one power line by a conductor 43 40 connected. The connection of the two synchronous motors of each slave clock with the other However, power lines 41 are disconnected. The engines that the normal operation of the Pointers are incumbent on a common line 44 via a switch 47 the power line 41 is permanently connected. The motor 28 is also the adjustment device the master clock is permanently connected to the power lines 40, 41. The normal drive The synchronous motors serving the slave clocks accordingly correspond to the synchronous motor 28 the - master clock.

The adjustment motors are connected by a common conductor 48 via a conductor 57 and through the switch 47 to the contact 6o of a switch 46. One pole of the adjusting motor 29 of the master clock is also connected to the same contact 6o, so that when the switch 46, which is to be referred to as the adjusting switch, is closed, current is sent through the motor 29 and the adjusting motors of the slave clocks. The adjustment switch 46 is controlled by the pointer 17. This presses against a contact spring 49 which is connected to one end of a magnetic coil 52 of the adjuster switch 46. The contact pillar 49 is normally pressed by the pointer 17 against the contact 5 = and, when it is released by the pointer 17, can automatically move towards the contact 50 which is opposite the contact 51. The contact 51 is connected to the power line 40 via the lines 71 and 43, while the contact 50 is connected to a contact 54 of a thermal switch 53. The pointer 17 is set so that it presses the spring 49 against the contact 5 = during normal operation, and this position, as described above, is assumed by the pointer 17 as long as the motor 28 is running at the correct number of revolutions. If the current fails or the mains frequency deviates, the pointer 17 moves clockwise and allows the spring 49 to touch the contact 50. This closes a circuit which leads from line 40 via line 43 through coil 52, contact spring 49, contact 50, 54, switch 53, line 57, 58 to power line 41. The thermal switch 53 contains a heating coil 55 which is permanently connected to the lines 40, dz via the lines 57, 58 on the one hand and the reactance 56 and line 43 on the other hand. If there is no mains power, the thermostat 53 cools down and moves against the contact 54. The cool-down time can be set and corresponds to the period of time which is considered to be permissible as a deviation of the clocks. The thermostatic delay of the adjustment is not absolutely necessary and can also be omitted. The contact 50 is then connected directly to the line 58. The thermostatic switch, however, has the advantage that in the event of small deviations in the mains frequency, which often occur, the adjustment device does not come into action, so that it is spared. However, if the entire clock system is connected to an alternating current network, the frequency of which is not specially regulated, it is advisable to omit the thermostatic switch 53 so that the system frequency can be readjusted immediately if errors occur. As a result, a special regulation of the network frequency is unnecessary.

Below will be. the processes when using a thermal switch described: If the failure of the mains current, the thermostat 53 cools and touches the contact 54, it closes a circuit that connects the coil 52 to the mains. This circuit goes from the line 40 via the conductor 43 through the coil 5z, the spring contact 49, the contact 5o, contact 54, thermostat 53, conductor 57, 58 to the power line 41. As soon as power is available again in the network, the coil 52 energizes and closes the adjustment switch 46, overcoming the force of the spring 59. By closing the switch 46, the motor 29 receives current, as does the adjustment motors corresponding to the motor 29 of the slave clocks. The current path goes from the power line dz via the conductor 58, switch 46, motor 29, conductor 43 back to the power line 40, while at the same time the adjustment motors of the slave clocks receive power from the power line 41 via conductor 58, adjustment switch 46, switch 47, conductor 57 and Line 48. The current path to the other power line 4o goes via the bus line 43. As already described earlier, the motor 29 and the adjusting motors of the slave clocks, as soon as they receive power, cause the clock hands to move ten times faster. The control element 17 corresponding to a minute hand is moved back into the starting position, while the pointers of the slave clocks are brought into a position which corresponds to the display of the control clock. If the control element = 7 touches the spring contact 49 during the backward movement, it lifts it off the contact and interrupts the circuit. The solenoid 52 of the adjuster switch 46 is initially not yet de-energized, since a resistor 61 is placed parallel to the spring contact 49 and thermal switch 53. For this purpose, one end of the resistor 61 is permanently connected to the end of the coil 52, to which the connection to the control contact 49 also leads. The other end of the resistor is connected to the power line 41 via the conductor 58 as long as the adjustment switch 46 is in the closed position. The adjustment switch 46 is thus kept closed as long as the backward movement of the contact spring 49 from the contact 50 to the contact 51 lasts. When contact 51 is touched, coil 5z is short-circuited by conductors 43 and 71. At this moment the resistor 61 lies between the lines 40, dz, -to which it is connected by lines 43, 71 and 58, so that a short circuit is avoided.

The switch 46 opens immediately after the coil 52 has been de-energized and interrupts the circuit of the adjustment motors as well as that of the motor 29. The control member 17 is again in the starting position, and the pointer the slave clocks show the correct time.

In order to enable manual readjustment under certain circumstances, the switch 47 is provided, the connection of the motor 29 corresponding Adjustment motors of the slave clocks are allowed to be connected to the line network by hand.

Instead of special adjustment motors in the master clock and the slave clocks to use, which cause the hands to rotate faster, can also for the purpose of adjusting the connection of the normal synchronous motors of the master clock and the slave clocks to an AC power source with a higher frequency. Fig. 5 shows the circuit diagram of such an adjustment device. The motor 28 drives as already described earlier, the gear i9, so that this normally a Rotation per hour. The control member 17 pushes in the. normal position the spring contact 49 against the contact 51. The coil 52 is also the adjuster switch 46 connected to the network in the same way. - If there is no mains power the switch 46 is closed, but in this embodiment it connects the Motor 62 with the mains circuit that drives a frequency converter 63. As soon the generator 63 has reached the number of revolutions and assumes its full voltage, causes the solenoid 64, which is connected to the generator voltage, the switching of switch 65 so that it touches contact 72. Usually, i. H. so long the coil 64 is not energized, the switch 65 is by the spring 67 against the Contact 66 pressed, at which switch position the motor 28 of the master clock and the synchronous motors of the slave clocks are connected to the network 40, 41. The one The terminal of the generator 63 operating at a higher frequency is through the conductor 43 continuously with a terminal of the drive motor 28 and the synchronous motors of the slave clocks 42 connected so that when the switch 65 is thrown by the action of the coil 64 these motors receive electricity from generator 63 at a higher frequency than the mains frequency, as long as the readjustment process lasts. The generator 63 can for example Generate electricity, the number of periods of which is twice as high as the mains frequency, then the clocks run twice as fast during the adjustment period as with normal Operation.

If the control member 17 and thereby also the contact spring 49, as above described, reaches the normal position, the switch 46 is opened and interrupted the circuit to the period converter. The generator 63 stops, the coil 64 is de-energized, and the switch 65 is brought into the normal position by the spring 67, thereby reconnecting the slave clocks and the motor 28 directly to the power lines will.

Fig. 3 shows a special design of a control disk with the control member 17 works together and effective in the event of longer power interruptions will. Without this control disk 73, in the event of a power interruption, the longer takes than 1 hour, the control member 17 make a full turn and the contact spring 49 from the other side, which would have to give rise to disturbances, which ultimately would lead to breakage of the control element or the contact spring. The control disk 73 is rotatably mounted on a cross member 76, which by means of spacer bolts 75 with the base plate 22 is connected. The disk 73 is rotatably mounted on the pin 77 and has a ring gear that meshes with the pinion 18. This pinion sits on the shaft 16 of the control member 17, the angular speed of which is a minute wave corresponds, and the translation between the pinion 18 and the disk 73 corresponds the transmission ratio between the minute hand and the hour hand is 1: 12 if the slave clocks have a 12-hour division. On the side that dem Control member 17 is facing, has the disc 73, which is arranged in front of the control member is, an elevation 74, which is circular and 1l / 12 of the disk circumference occupies. This increase is provided on the disc 73 that the control member 17 in its normal position between the ends of the elevation touches the disk 73. To. One twelfth turn of the disk 73 is already the increase 74 at the point that corresponds to the normal position of the control member 17, so that this Control element, when it returns to this position after a full turn, on the switching spring 49 cannot act because it is out of the plane due to the elevation 74 this switching spring is pushed out. After the switching element 17 but twelve revolutions has made, the point on the control disk 73 reaches the point where there is no increase 74 is back to the starting position, and. the switching element 17 can be exactly the same act as if there were no elevation 74. 'Since the translation is between the switching disk and the switching element of the translation between the hour hand and The hour hands of the slave clocks are now the same as the minute hand lagged so far behind that their position again corresponds to the time on the control clock is equivalent to.

Claims (9)

PATENT CLAIMS: 1. Clock system connected to an alternating current lighting network connected and fed or monitored at the normal frequency by the network Synchronous clocks using a comparison clock common to the synchronous clocks, if the time specification of the synchronous clocks deviates from the specification of the normal clock automatically corrects or readjusts the clocks, characterized in that that the comparison clock is only independent of the frequency regulation of the network the Synchronous clocks acts via a control line and thereby using Switching elements automatically adjust the clocks to the state of the normal clock causes. 2. Clock system according to claim i, characterized in that the adjustment of the synchronous clocks connected to the AC mains by means of special adjustment motors takes place, which is controlled directly by the comparison clock by means of a control line will. 3. Clock system according to claim i, characterized in that the adjustment the synchronous clocks connected to the alternating current network takes place in that the the power supply unit containing the synchronous clocks through the comparison clock from the rest of the network temporarily disconnected and temporarily connected to a higher frequency power source will. q .. Clock system according to claims 1 and 2, characterized in that in the individual synchronous clocks apart from the synchronous motors intended for normal drive Another synchronous motor is built in, which drives the clock hands faster causes as soon as it receives electricity. 5. Clock system according to claim i to q., Characterized by a relay, which when there is a time difference between the control clock and Slave clocks (failure of the mains current) closes a circuit that occurs when it occurs again of the mains current connects the synchronous adjustment motors of the slave clocks to the mains and keeps connected until there is a match between the control clock and the slave clocks is made. 6. clock system according to claim i to 5, characterized characterized in that the comparison clock contains a clockwork (1o) by a synchronous motor connected to the mains counterclockwise, at correct mains frequency but with the same angular velocity as a pointer this clockwork is rotated, so that at normal mains frequency as the control element serving pointers of the clockwork its position in relation to the fixed control organs in the room, with whom he works does not change. 7. Clock system according to claim i to 6, characterized in that the adjustment circuit is directly or indirectly Closing switching element (q.9) from the control element (pointer 17) when the Slave clocks and comparison clock is pushed out of its current short position and into this automatically returns when the control element (pointer 17) due to a time discrepancy changes his position. B. Clock system according to claims i to 7, characterized in that that the comparison clock is also equipped with an adjusting motor (29), the when the control of the synchronous slave clocks starts, a correspondingly faster one Rotation of the clockwork (io) and thus a return of the control pointer (17) brings about. 9. clock system according to claim i to 8, characterized with a delay device by a thermal delay relay (53), which activates the adjustment device only effected when the mains current has been absent for a certain period of time. ok Clock system according to claim i to 9, characterized in that the control member (pointer 17) with the angular speed of a minute hand driven wildly and at greater Deviation from the normal position of one with the angular velocity of one Hour hand revolving control disc (73) is pushed out of the plane in which it can act on the switching element until the time deviation is determined by the adjustment mechanism corrected or the position of the hour hand of the slave clocks with the control clock matches.