DE1039416B - Circuit arrangement for the cyclical transmission of measured values - Google Patents

Description

Is restarted at the end of the same. 20 <

The additional invention deals with an η

Further development of this circuit arrangement insofar as it creates the possibility of dividing the measured values to be transmitted into two groups according to the main patent while maintaining the synchronization, whereby first the measured values of one and the number of cyclically operated switching tubes 25 then the measured values of the other Group tapped measured values to be transmitted without increasing the decrease. If, for example, contact Im _{5 is} closed, gripper and distributor steps must be increased. This connects the line L ₁₈ to the transmitter Se , so that the possibility is achieved by dividing the measured values corresponding to the measured values M ₁ ... M ₈ into groups and following the direct voltages one after the other to the transmitter S for determination the measured value group to be tapped are fed to 30 modulation, whereupon after closing the transmission side the corresponding group of memory of the contact 2u _s due to the influence of the relay U _s to be explained, the line L _{25 is} connected to the transmitter Se , so that the measured values M ₉ . . . M ₁₆ corresponding direct voltages pass one after the other to the transmitter 5 ″ for modulation of the same

devices on the receiving side after starting the pulse frequency transmission by the Sending side emitted synchronization pulse is determined by a further identifier.

To explain the invention, a circuit arrangement is shown in the drawing as an exemplary embodiment cyclical transmission of e.g. sixteen

Measured values M ₁ . .. M ₁₆ via a also for other groups divided to the lines L _le and L _2e serving purposes L, z. B. a remote 40 are closed. The changeover takes place here by voice line, with reproduction of the relay U _e only in this one.

Frame of interest circuits shown. The subsequent tapping is on the sending side

the sixteen measured values M ₄ . . . M ₁₆ , which is affected by transducers MWU ₁ . . . MIVU _16, which is the only one in the present exemplary embodiment and is recorded and converted into a negative DC 45 with a corresponding number of switching paths and voltage with a cold cathode corresponding to the respective measured value equipped with a common anode, are caused by the tube K _s. On the receiving side there is a cyclical closing of the contacts a ₂ . . . a _g the measuring corresponding cold cathode tube K _E for Verteiwerte M ₁ ... M ₈ to the line L _18, and when zy lung to the individual storage devices vorgeklischen closing the contacts a _12th . . a _ig see the measuring 50. To ensure the cyclical transmission of measured values over the line L , it is ensured that tapping and distribution take place synchronously, that is to say that the switching paths of the cold cathode tube K _s and the cold cathode tube Kß are ignited in synchronism.

809 633/271

values M M ₉ ... ₁₆ applied to the line L _25, but depending on whether the transfer relay U _s its contact in the ₈ or 2w _s has closed, the line L _ls or L ₂₅ is connected to the transmitter 6 ". You can see that

The synchronous group switching takes place by an additional measure before tapping or distributing.

If one starts from the time at which in the cold cathode tube Ä _'s on the transmitting side, the contact gap K is ignited ₁₀ -A, so synchronization is first with respect to prepare the first tapped off measured-value by the above relay 5 "s tapped positive voltage. Assuming that the tube Ra ₂ straight draws current, so the relay U _s is energized via its winding II so that on its contact 2 _s w is the group II with the measured values M _9... M ₁₆ via the line L _{25 is applied} to the transmitter 5 ″, the said positive voltage now influences the grid of the tube Ro _{1 in} such a way that the tube Ro _{1 also} ignites. There is such a voltage drop across the resistor Wi ₂₀ ^em that the capacitor C is reloaded. An additional current thus flows through the resistor Wi ₂₁ , so that the operating voltage of the tube Ro ₂ is not reached and this tube is extinguished. The relay U _s is now excited via its winding I in such a way that the measurement group I (measured values M ₁ ... M ₈ ) can be tapped by connecting the line L _1S to the transmitter S via the contact 1k _s . In addition, since, as I said, on the transmit side, the contact gap K ₁₀ -A is ignited, the synchronization transmission relay excited about this switching path 5 "$. By closing the contact 2s _s is applied to the transmitter S a positive DC voltage, that the negative braking grid voltage of a reactance tube present in the transmitter is lowered so far that the transmitter sends a frequency of about 2.8 kHz to the receiving side via the high-pass filter HPg and the line L. This frequency is converted into a positive one in the demodulation stage of the receiver E DC voltage converted, which is amplified and differentiated in a synchronization stage S _st on the receiving side with known means, so that the beginning or the end of the synchronization surge occurs as a negative or positive voltage surge on the grid of a tube flip-flop circuit of the known type , in whose electron stream the synchronization receiving relay S _{E is} arranged t, made conductive at the beginning of said synchronization surge. The synchronization receiving relay S _E allows when it is energized, since the contact 1 s _{E is} open, the sole ignition of the switching path K ₁₀ -A in the cold cathode tube K _E. On the transmitting side, an oscillator O ₁ continuously supplies a frequency of 500 Hz, which is converted into a frequency of 25 Hz _{by dividing it into frequency dividers, F 1} S (500/100) and F _{25 (100/25), which work as a blocking oscillator.} This frequency is coupled into the control circuit of the cold cathode tube K _s 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 K _{10 to} the auxiliary cathode on the right, as a result of the structural design of the tube which is not of interest here, since the voltage between the anode A and the auxiliary cathode as a result of the negative pulse voltage is the ignition voltage for the auxiliary cathode mentioned achieved. A current flows across the switching path of this auxiliary cathode, which causes an additional voltage drop across the anode resistor R _A , so that the voltage at the path K ₁₀ -A is not reached. The synchronization transmitter relay S ₅ drops out and terminates the synchronization burst by opening the contact 2 j _s; the subsequent ignition of the next switching path is prepared on the contactless. At the end of the negative pulse voltage, the voltage between the anode A and the auxiliary cathode is less than the anode voltage, while the voltage between the cathode K ₁ and the anode A , which is located on the right λόιι of the ignited auxiliary cathode due to the circular arrangement of the switching paths, is equal to the anode voltage. The ignition now jumps over to the cathode K ₁ , since this is pre-ionized by the previously existing auxiliary cathode path. With each occurrence of the negative pulse voltage in a rhythm of 25 Hz, the ignition of the switching paths continues, so that one after the other the relays A ₂ IA ₁₂ . . . A ₉ ZA _{19 are} excited and de-excited again. By energizing the relay S ¹ via the cathode 1, a voltage Ug _p , which is in the range of the voltage used for measured value transmission, is sent via the line L ₁₈ to the transmitter S _{e via the contact} To provide the storage devices of the corresponding measured value group I on the receiving side. 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 has drawn current while blocking the first-mentioned tube, so that the synchronization receiving relay S _E drops out and in the cold cathode tube K _E after the contact is closed 1 s _E enables subsequent ignition of the switching paths as in the case of the cold cathode tube K ₈ . For this purpose, the cold cathode tube K _{E is} also supplied with a negative pulse voltage at a rate of 25 Hz. However, this pulse voltage is set if one assumes that the pulse voltage on the transmitting side causes each switching path to burn for about 40 ms. 10 ms later than on the transmission 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 Sp ₁ . . . Col ₈ and Col ₉ . . . Sp ₁₈ takes place at a point in time at which the corresponding transducer MWU ₁ . . . MWU ₈ or MWU ₉ . . . _{MWU 16 is} definitely switched on on the transmission side. The pulse voltage is generated on the receiving side with the help of the oscillator O ₂ (500Hz), the frequency divider F _IE (500/100), which works as a blocking oscillator, and the frequency dividers F _2E (100/50) and F _sE (50/25), which operate in flip-flop ). Characterized in that the said flip-flop of the synchronization step S _St in the course of the synchronization burst in accordance with its beginning and its end, five pulses P ₁ ... P of the form shown in the drawing are taken, the following switching operations in the frequency dividers F _lE are F _2E and F _3E caused on the receiving side: During the entire duration of the synchronization surge, a negative square-wave pulse P _{5 is} taken from the flip-flop circuit, which is used to block the frequency divider F _IE . The frequency divider F _IE accordingly does not emit any pulses during this time. The frequency divider F _2E is brought into a selected tilted position by a pulse P ₁ , which is taken from the flip-flop circuit as a positive pulse at the beginning of the synchronization surge. The frequency divider F _sE is also brought into a selected tilted position by a voltage surge taken from the trigger circuit as a positive pulse P _{4 at the beginning of the synchronization surge.} At the end of the synchronization burst, the following occurs: The already mentioned negative square pulse P ₅ disappears.

det, so that the _{frequency divider F 1} ^, controlled by the oscillator O ₂ and working as a blocking oscillator, emits pulses of 100 Hz. The frequency divider F _2E is brought into the opposite tilt position by a voltage pulse, which is taken as a positive pulse from the flip-flop circuit at the end of the synchronization pulse, the frequency divider F _3E also reaching the opposite tilt position through the same voltage pulse. If the frequency divider F ₁ E emits a pulse, first the frequency divider F _2E and then the frequency divider F _3E tilts, so that with every fourth pulse of the frequency divider F _IE a pulse is emitted at the output of the frequency divider F. _{iE, i.e. a pulse frequency of} 25 Hz can be removed. The tilt position in the frequency divider F _2E and F _sE is selected so that a symmetrical pulse frequency of 25 Hz is produced at the output of the frequency divider F _3E , the effective positive part of which is in the middle of a measured value transmission from the transmitting side. As a result of the subsequent ignition in the cold cathode tube K _{E in} accordance with the 25 Hz pulse voltage, the relays V ₉ are accordingly switched from the cathode 2 onwards. . .V ₉ or V.

12th

V.

19th

A _a

energized after relays A ₂ or A _1,. . . A ₁₀ on the transmitting side are already excited depending on the 25 Hz pulse voltage there; the relays V ₂ ... F ₉ or F ₁₂ . . . F ₁₉ are then also one after the other before the following one

. A _Q or A

12th

19th

De-energization of relay A ₂

brought to supra-excitement. In the present switching state, the storage devices Sp ₁ are first influenced in a subsequent manner. . . Sp ₈ . Because as soon as the ignition takes place via the cathode 1, the blocking of the grid G _{2 of} the tube Ro _{3 is} lifted on the receiving side, since the negative grid voltage is now compensated via the resistor Wi ₃₀ through the positive voltage at the resistor H ^ i _31. If the mentioned voltage U _Sp now arrives to switch on the storage devices of group I corresponding to group I provided on the transmitting side, then this arrives at the grid G _{1 of} the tube Ro ₃ . The tube Ro ₃ is opened due to the presence of both of the aforementioned voltages G ₁ and G ₂ . A positive voltage arises at the resistor Wi ₃₂ , which causes the tube Rö _i to ignite. It remains live during the ongoing ignition of the cold cathode tube K _B , regardless of the voltage that is no longer present at the resistor Wi _32. Since i via the tube? Ö ₄ the relay U _e has been energized, the contact is 1 and _e is closed so that by turning on the line L _le the memory devices Sp. ₁ . . Sp ₈ are provided; group synchronization is now complete. The successive excitation of the relays F ₂ ... F ₉ (the excitation of the relias F ₁₂ ... F ₁₉ remains ineffective) affects the negative DC voltages taken from the demodulation stage of the receiver E and corresponding to the measured values to be transmitted, if on the The relay A ₂ on the transmitting side and the relay F ₂ on the receiving side is energized, the frame ^ ₁ in the memory Sp ₁ , which is initially traversed by a current which causes _{a certain deflection of the flag F 1.} By means of the associated known tube oscillating circuit, a direct current corresponding to the measured value is driven through the secondary winding W _{5 of} the high-frequency transformer HF via the rectifier Gl _{, which causes the display instrument Z 1} to deflect according to the transmitted measured value M ₁ . The current also flows through a resistor Wi ₁ , at which the negative direct voltage corresponding to the measured value is also present. If the current causes the same voltage across the resistor Wi ₁ , a state of equilibrium is reached. The deflection of the instrument J ₁ is also retained if the contact v _% is temporarily opened again in the course of the cyclical transmission, since the capacitor C _{1 maintains} the voltage state until a different voltage value as a result of a change, if necessary when the contact V _{2 closes again} of the measured value is applied. The other measured values M _{2 are} displayed in a corresponding manner . . . M ₈ in the other places.

After the transmission of the measured values M ₁ . . . M ₈ , the state is reached again in which the switching paths K ₁₀ -A of the cold cathode tubes are ignited on the transmitting side and receiving side. Apart from the synchronization of the subsequent tapping and distribution that takes place again, the synchronous group switchover is now being prepared. Since the tube Ro _{1 is} now drawing current, the tube Ro _{2 is} ignited by the positive voltage tapped above the relay Sg. Since the tube Ro ₁ goes out, the winding II of the relay U _{s is} excited, so that the contact lu _{s is} opened and the contact 2u _{s is} closed. This prepares the reading of the measured values M ₉ ... M _16. The synchronous switching on the receiving side is caused after the switching path K ₁ -A has been triggered that the voltage U _Sp previously connected to group I is missing, so that the tube Ro ₃ despite the compensation of the negative grid voltage at the grid G ₂ by the voltage via the resistor Wi _{31 is} not opened because the voltage on the grid G ₁ (U _Sp ) is missing. The previously by opening the contact ls _E switched off relay U _e is not energized, so that so that via the contact 2u _e the memory devices Sp. ₉ . . Sp ₁₆ are provided.

It can be seen that by grouping the measured values, the number of measured values to be transmitted is enlarged without increasing the tapping and distribution steps, with the introduction of the synchronous Group switching is ensured by a further identification that the correct transmission is ensured.

Claims (3)

Patent claims: 1. 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 cyclic 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 on the receiving side also by cyclic actuation of interrupter tubes, preferably a single cold cathode tube, is carried out by cyclic actuation by means of pulse generators provided on each side same frequency is achieved, the synchronism of which is achieved by one at the end of each transmission cycle output synchronization pulse is secured by the fact 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 synchronization pulse emitted by the transmitting side stopped and only restarted at the end of the same, according to patent 1 022 128, characterized in that the Readings are divided into groups and after determining the measured value group to be tapped, the corresponding group on the transmission side of storage devices on the receiving side after starting the pulse frequency transmission by the synchronization pulse emitted by the transmitting side by a further identification is determined. 2. Circuit arrangement according to claim 1, characterized in that the marking by an additional pulse in the initial position of the cold cathode tube. 3. Circuit arrangement according to claim 2, characterized in that the pulse in the frequency range the measured values lie. Including 1 sheet of drawings