DE1022128B - Circuit arrangement for the cyclical transmission of measured values - Google Patents

Description

Circuit arrangement for the cyclical transmission of measured values cyclic measured value transmission. the measured values on the transmitter side in cyclical order recorded by means of a tapping device and corresponding signals in time passed on one after the other via the same transmission path. On the receiver side the reverse process is done by removing the individual. arriving one after the other Signals from the transmission path synchronously from,-taken and through a distribution device can be switched to the individual measured value indicators. Used for tapping and distributing mechanical switches, so have. these have the disadvantage that they their constant circulation are subject to mechanical wear; aside from that work relatively slowly and result in a correspondingly long delay in transmission, which is undesirable for many purposes. Therefore one has for tapping and distributing gas discharge tubes. used. Here is with everyone. the receiving center z. B, recorded as a pulse of a certain amplitude Measured value brought about a synchronization of the cyclical transmission. The impulses are therefore not only used to influence the cyclic transmission each provided measured value indicator, but are also an amplifier fed in such a way that at the end of each pulse the deletion of the straight to influence of a measured value indicator. Interrupter and after passing through a delay element the ignition of the following interrupter for the purpose of subsequent provision of the for instrument serving next measured value display. The interrupters - it can Incidentally, as it is known for the purposes of multiple telegraphy, in place A single tube can be used for a large number of tubes - that is, in cyclical sequence ignited and extinguished. The duration of the transfer the pulse corresponding to the last measured value and thus also the burning time the last interrupter. is with these. Arrangements about two to three times longer selected as the burning time of the preceding switch tube. Accordingly is also the time between the ignition of the last interrupter and the next in the cycle first interrupter longer. Should for some reason the switching cycle of the interrupters on the receiving side apart from synchronism with the incoming measured value corresponding If pulses fall, the first switch tube speaks due to the longer time span to pulses arriving in quicker succession after passing through the delay element does not come on, and the last interrupter continues to burn until the one after a long pause incoming pulse, again corresponding to the first measured value, triggers the first switching tube ignites. The synchronism is then restored.

The invention proceeds to ensure the synchrenism between the cyclical tapping of the signals corresponding to the measured values on the transmission side by cyclic actuation of interrupters, preferably in a single one Cold cathode tube arranged switching paths, and the synchronous. Distribute on Storage facilities. with display devices on the receiving side as well by cyclic actuation of interrupter tubes, preferably a single cold cathode tube, another way.

This way is characterized in that the cyclic actuation is achieved by pulse generators of the same frequency provided on each side, their synchronism by a. synchronization pulse emitted at the end of each transmission cycle it is ensured that the pulse frequency transmission for the switching tubes on the Send and on the receive side after each transmission cycle on the receive side at the beginning of the: synchronization pulse emitted by the transmitting end and is only started again at the end of the same.

To explain the invention is shown in the drawing as an exemplary embodiment a circuit arrangement for the cyclical transmission of, for example, nine measured values via a line that is also used for other purposes, e.g. B. an intercom line, showing only the circuits of interest in this context.

The nine measuring points NIl,? 1l2 . . . M, incoming measured values are recorded by Meßwertumfo @ rmern.MZ, TWI, MUW2 ... MUW9 and during intermittent tapping by subsequent closing of contacts a1, a.,. . . a9 as negative DC voltage with one of the respective. Measured value corresponding height (signals) given to the transmitter S whose frequency z. B. is determined using a reactance tube, the slope of which by changing its retardation grid voltage according to the size of the negative. DC voltage (measured value corresponding signal) is changed so that a capacitance, which determines the respective transmission frequency, appears between the anode and cathode of the tube. In the present exemplary embodiment, depending on the measured value to be transmitted, the transmitter S transmits frequencies which are in the range of over 2.9 ... 3.3 kHz. After passing through the high-pass filter TIPS, they are forwarded via the telephone line L to a receiving point, in which they influence the receiver E after passing through the high-pass filter HPL, in which the respective recorded frequency is converted in a demodulation stage into a negative DC voltage corresponding to the measured value. This DC voltage is applied to the storage device (Spi ... Sp9) which corresponds to the respective measuring point on the transmission side via the subsequently actuated contacts v1 ... v9 on the receiving side in the course of a distribution corresponding to the tapping on the transmitting side; The instrument (7i... J9) of the connected storage device displays a corresponding display of the measured value. The subsequent tapping is initiated on the transmitting side by temporarily closing switching paths of the only cold cathoid tube Ks in the present exemplary embodiment, which has the required number of switching paths and a common anode. A corresponding cold cathode tube KF is provided on the receiving side. To secure the cyclical transmission of measured values via. the line L must be ensured that the tapping and distribution take place synchronously, i.e. the ignition of the switching paths of the cold cathode tube Ks and the cathode tube KL takes place in synchronism, since this then causes the relay A1. . . A9 synchronous with relay Z'1. . . L'9 are operated.

First of all, it should be mentioned that in the rest position, so as long as no measured value is transmitted, the braking grid voltage of the mentioned reactance tube in the transmitter S is chosen so that a rest frequency of z. B. 2.9 kHz is given from the transmitter S over the line I_ . The demodulation stage of the receiver E is set so that the DC voltage is zero when the quiescent frequencies7 are recorded.

Assuming the point in time at which the switching path KW A is ignited in the cold cathode tube Ks on the transmitting side, then the synchronizing relay S is energized via this switching path. By closing the contact. 2, s5 a positive DC voltage is applied to the transmitter S, so that the negative braking grid voltage of the above-mentioned reactance tube in the transmitter S is lowered to such an extent that the transmitter sends a frequency of about 2.8 kHz via the high-pass filter HPS and the line I_ to the receiving side . This frequency is converted into a positive DC voltage in the demodulation stage of the receiver S, which is implemented in a synchronization stage Ssl on the receiving side using known means. is amplified and differentiated, the beginning or the end of the synchronization surge occurs as a negative or positive voltage surge on the grid of a known type of flip-flop. As a result, that tube of the flip-flop circuit in whose stream of electrons the synchronization input relay SE. is arranged. made conductive at the beginning of said synchronization surge. Since the synchro: nisierungsempfangsrelais SF allows when its excitation, since the contact 1sE is open, the sole ignition of the switching path K19 -.- 1 in the cold cathode tube ML. On the transmitting side, an oscillator 01 continuously supplies a frequency of 500 Hz, which is converted into a frequency of 25 Hz by dividing it in the frequency dividers Fis (500/100) and Fzs (100/25), which work as blocking oscillators. This frequency is coupled into the control circuit of the cold cathode tube Ks and causes the individual switching paths to be triggered as a negative pulse voltage. When the negative pulse voltage occurs for the first time, the ignition jumps from the cathode K1. as a result of the structural design of the tube, which is not of interest here, to the auxiliary cathode on the right, since the voltage between the anode A and the auxiliary cathode due to the negative pulse voltage reaches the ignition voltage for the auxiliary cathode mentioned. A current flows through the switching path of this auxiliary cathode, which causes an additional voltage drop at the anode resistor RA, so that the operating voltage is below the line Kiä <4. The synchromization transmitter relay SS drops out and ends the synchromesh shock by opening the control 2ss. at the grain cycle l, ss the subsequent ignition of the next switching path is prepared. At the end of the negative: pulse voltage is the voltage between the anode. and the auxiliary cathode is less than the anode voltage, while the voltage between the cathode K1, which is located to the right of the ignited auxiliary cathode as a result of the circular arrangement of the switching paths, and the anode A is equal to the anode voltage. The ignition now jumps over to the cathode K1, since this is pre-ionized by the previously existing auxiliary cathode path. With each occurrence of the negative pulse voltage at a rate of 25 Hz, the switching paths continue to fire, so that one after the other the relays .41, = 1. = ... .79 are energized and de-energized again. On the receiving side, at the end of the mentioned synchronization surge arriving from the transmitting side (positive voltage surge), the other tube of the flip-flop circuit draws current while blocking the first-mentioned tube, so that the synchronization receiving relay SL drops out and subsequent ignition in the cold cathode tube KL after the contact 1sL is closed the switching paths as hot the cold cathode tube Ks allows. For this purpose, the cold cathode tube ItL is also supplied with a negative pulse voltage at a rate of 25 Hz. This pulse voltage starts, however, if one assumes that the pulse voltage on the transmitter side lets each switching path burn about d0 ms, 10 ins later than on the transmitter side and stops 10 ms earlier. This ensures that the switching process of the subsequent distribution, namely the subsequent switching on of the storage devices, @ pi. . . Sp9, 711 takes place at a point in time at which the corresponding measured value converter d.IL'Wi. . . .ITLTR'9 is definitely switched on on the sending side. The pulse voltage is generated on the receiving side with the help of the oscillator 0, (500 Hz), the blocking oscillator FlL (500/100) and the frequency dividers F. = L (100/50) and F.31, which operate in flip-flop. (50/25). The fact that five pulses P, ... P5 of the form shown in the drawing are taken from the aforementioned flip-flop circuit of the synchronization stage SSt in the course of the synchronization surge, corresponding to its beginning and its end. the following switching processes are caused in the frequency dividers FlF, FEE and F3E on the receiving side: During the entire duration of the synchronization surge, a negative square pulse P5 is taken from the trigger circuit, which is used to block the frequency divider FiE. The frequency divider FIE therefore does not emit any pulses during this time. The frequency divider FIE is brought into a selected tilting position by a pulse P1, which is taken from the tilting circuit as a positive pulse at the beginning of the synchronization. The frequency divider F3E is also through. a. brought the flip-flop as a positive pulse P4 at the beginning of the synchronization surge into a selected tilted position. At the end of the synchronization surge, the following occurs: The already mentioned negative square-wave pulse P5 disappears so that the Fr@equ.en: zteiler FIE pulses of 100 Hz, controlled by the oscillator 02 and working as a blocking oscillator, emits. The frequency divider F2E is brought into the opposite tilt position by a voltage pulse, which is taken as a positive pulse from the trigger circuit at the end of the synchronization pulse, whereby the frequency divider F3E also reaches the opposite tilt position through the same voltage pulse. If the frequency divider FIE emits a pulse, first the frequency divider F2E and then the frequency divider F3E tilts, so that with every fourth pulse of the frequency divider F1E a pulse is emitted at the output of the frequency divider F3E, i.e. a pulse frequency of 25 Hz can be picked up . The tilt position in the frequency divider F2E and F3E is selected so that a symmetrical pulse frequency of 25 Hz is produced at the output of the frequency divider F3E, the effective positive part of which occurs in the middle of one from the transmitting side. Measured value transmission is. As a result of the subsequent ignition in the cold cathode tube KE according to the 25 Hz pulse voltage, the relays V1 ... V9 are accordingly energized one after the other, after the relays A1. . . r19 on the transmitter side are already excited depending on the 25 Hz pulse voltage there; the relays l'1 . . . f'9 are then also successively before the subsequent de-excitation of the relay A1. . . A9 disturbed. After each cycle, the new start-up is initiated by the end of the synchronization surge. It is therefore a stop-start method which makes stabilization of the oscillator 01 and pulling the oscillator 02 along unnecessary. Influence during operation. the negative DC voltages taken from the demodulation stage of the receiver E, corresponding to the measured values to be transmitted, when the relay A1 on the transmitting side and the relay Ui on the receiving side is energized, the frame R1 in the memory Spi, which is initially powered by a current is traversed, which causes a certain deflection of the flag F1. Using the associated. known tube oscillation circuit, a direct current corresponding to the measured value is driven through the secondary winding WS of the high-frequency transformer HF via the rectifier GZ, which causes the display instrument J1 to deflect according to the transmitted measured value. The current also flows through a resistor g'ii, at which there is also the negative direct voltage corresponding to the measured value. If the current produces the same voltage across the resistor Wi, then so. is a: state of equilibrium reached. The deflection of the instrument J1 is retained even if the contact v1 is temporarily opened again in the course of the cyclical transmission, since the capacitor C1 maintains the voltage state until another voltage value is applied as a result of the change in the measured value when the contact v1 closes again . The other measured values are displayed in a corresponding manner at the other locations.

Claims (1)

PATENT CLAIM: Circuit arrangement for the cyclical transmission of measured values, in which the cyclical tapping of the signals corresponding to the measured values on the transmission side by cyclical actuation of switching tubes, preferably of switching sections arranged in a single cold cathode tube, and the synchronous distribution to storage devices with display devices the receiving side also takes place by cyclical actuation of switching tubes, preferably a single cold cathode tube, characterized in that the cyclical actuation is achieved by pulse generators of the same frequency provided on each side, the synchronism of which is ensured by a synchronization pulse emitted at the end of each transmission cycle in that the Pulse frequency transmission for the interrupters on the sending and receiving side after each transmission cycle on the receiving side, with the beginning of the. The synchronization pulse emitted on the transmission side is stopped and only restarted at the end of the same. Considered publications: German Patent Nos. 921737, 398 789; Dr. Stäb-lein, "The technology of Fern. Wirkanla@gen", p. 148/149.