DE896316C - Receiving arrangement for pulse frequencies - Google Patents

Description

Reception arrangement for pulse frequencies In the known pulse frequency receivers a capacitor is discharged via a pointer device with each received pulse or charged so that the mean value of the capacitor current over time is displayed is roughly proportional to the pulse frequency and is therefore a measure of the measurand. To smooth the capacitor currents occurring with high peaks and the display To calm down the receiving instrument, a high pulse frequency is necessary but again the transmission channel stressed unfavorably. One is therefore satisfied with pulse frequencies of moderate magnitude, it becomes a special damping device on the display device, in particular a capacitor connected in parallel is necessary. However, this in turn has the consequence that when there is a change in the measured variable and thus even the pulse frequency, the display only slowly approaches the new value. at Such arrangements mostly a measuring capacitor was used by a relay is alternately charged and discharged with a double-pole changeover contact.

In addition, a receiving device for telecontrol systems operated according to the pulse frequency method is known in which the pulse frequency is converted into a pulse sequence of constant intensity and double frequency at the receiving point by charging or reloading a capacitor arrangement. Two circuits are alternately closed via a device to be set, and a single-pole changeover relay is provided that is excited by the transmitted pulse train, which closes one circuit by means of its armature when excited by a pulse and closes the other circuit during the subsequent pulse pause. In each circuit, a capacitor is each inserted such that the other circuit is shorted to the closing of the circuit via a capacitor of the capacitor. This arrangement has the advantage that only a single pole relay is required. With the reduction in the number of relay contacts, not only does the relay as such become cheaper, but the susceptibility to failure is also reduced. In spite of this, the same applies to this arrangement with regard to the current spray as in the case of the arrangement cited at the beginning, i. H. To calm the display of the measuring device, either a high pulse frequency must be used, or a special damping device, for example a capacitor, must be assigned to the display instrument, which in turn has the effect that the setting is delayed when the measured value changes.

The invention also relates to a receiving arrangement for pulse frequencies in which the same amount of current flows through the display device for each pulse received, in that the charge or discharge current surges of one or more capacitors generated with each pulse and decaying according to an exponential function flow through the display device. However, it is not the task, as in the case of the known devices, to simplify the receiving device in such a way that only a single-pole relay can be used; , which would otherwise result in a delay in setting, can be dispensed with. This is made possible according to the invention in that the course of the capacitor charging or. -Entladeströme by switching means in front of the exhaust sound is interrupted at a desired point in time or delayed so that the individual current pulses overlap partially. In one case, the capacitor charging current runs according to a decaying exponential function, which can be made sufficiently flat by appropriate selection of the time constants, and this current curve is interrupted at a selectable point in time before the decay process is ended. In this way, individual pulses flowing through the display device are obtained which are almost rectangular in shape, i. H. that the instrument is traversed by a very flat direct current. Therefore, in this case, special smoothing devices are unnecessary, in particular if, according to a further invention, it is ensured that these current surges are strung together without gaps. - In another case, the arrangement but can also be formed so that the receiving measurement device running according to an exponential function completely decaying current pulses are fed, whose duration is a multiple of the pulse duration. The individual current surges follow one another with a phase shift of one pulse duration each, so that they are in the circuit containing the receiving instrument. Superimpose current surges at intervals of a pulse duration and thus result in a sawtooth-shaped direct current, which now has a low ripple. Finally, the received current can also be used to switch over suitable switching elements, for example ohmic resistors, by means of relays in such a way that a sufficiently smooth direct current is produced even with a low pulse frequency.

Two exemplary embodiments of the invention are shown schematically in the figures shown, namely Fig. i shows a receiver that serves to receive the incoming To convert the pulse frequency so that the receiving instrument receives current surges with each pulse of almost rectangular curve shape. Fig. 2 shows a receiving arrangement, which due to each impulse a completely decaying flow through the display device Current surge forms, but with successive current surges in time so cover the fact that the total current now has a low ripple.

In Fig. I, E denotes a voltage source whose positive pole i or its negative pole 2 is connected to a voltage divider Sp. In parallel with this voltage divider, there is an ohmic resistor R in series with capacitors C, C. The capacitors are controlled by a changeover contact A belonging to a relay (not shown) that responds to the incoming pulse frequency. The point of connection between the resistor R and the capacitors is denoted by 3. From here to a point 4 of the voltage divider Sp leads a connection which contains an electrical valve V, for example a dry-type rectifier. This valve is switched in such a way that it only lets through current in the direction from 3 to 4, and only if the potential of point 3 is greater than the potential of point 4. The two capacitors C, and C, are equal to one another. The pivot point of the changeover contact A is connected between the two capacitors and denoted by 5. The arrangement also contains a receiving instrument i, the internal resistance of which is neglected in the following for the sake of simplicity.

To explain the mode of operation, it is assumed that the changeover contact A is in the position shown and the capacitor C is initially uncharged. If the voltage source E is now switched on, this capacitor is charged according to the potential difference between points i and 2. The charging circuit runs from point i via the resistor R, the changeover contact A, the capacitor Ci and the receiving device i to the point, - ?. At the beginning of charging, the potential of points 2, 5 and 3 is the same, and in any case the potential of point 3 is lower than that of point 4. As a result, valve V is initially ineffective. In the further course. the potential of points 3 and 5 increases according to an exponential function until the potential of point 3 has become equal to that of point 4. At this point in time, the capacitor C is practically charged to the partial voltage Ei tapped at the voltage divider Sp. However, the potential of point 3 can no longer rise, because as soon as this potential rises only a little above that of point 4, valve V becomes current-permeable and thereby compensates for the potential difference. Since the increase in potential, which proceeds according to an exponential function, is ended at this point in time, the capacitor C, is no longer charged, and its charging current flowing through the measuring device suddenly drops to zero . Although an invariable current flows through the resistor R, which results from the resistance value and the partial voltage E according to Ohm's law, this current is irrelevant for the mode of operation of the arrangement.

The charging voltage thus runs according to an increasing exponential function, which breaks off when the potential of point 3 has become equal to that of point 4. The charging current of the capacitor C, is reversed. It can be represented by an exponential function which decreases exponentially from the initial value EIR and suddenly drops to zero at the same point in time as the voltage increase stops. If the time constant R - C is chosen to be sufficiently large, this drop can be made as weak as desired, almost straight, so that the curve of the charging current has an approximately rectangular shape.

If the relay contact A is now turned to the right after the pulse has expired, the game repeats itself in that the capacitor C, which is uncharged at the beginning of this period , takes the place of the capacitor C. By suitable selection of the tap 4 on the voltage divider Sp, the duration of the square-wave current impulse is set so that it is equal to the shortest pulse duration t j.- at the highest pulse frequency. In this case, the current curve in the measuring device i is a series of continuous, almost square-wave current impulses, i. H. a very largely leveled, only weakly undulating direct current. If the pulse frequency is lower, i. H. If the pulse is greater than t """, there is a pause between the invariable, almost square-wave current curves, and since the individual rectangles have a shape that is independent of the pulse frequency and is only determined by the time constant and the magnitude of the voltage Ei the mean value of the current displayed is proportional to the pulse frequency.

A seamless stringing of the current impulses can also be achieved if not the highest but any lower pulse frequency is sent. For this purpose the resistance R is increased, i.e. H. the time constant is increased and thus the increase at which the potential of point 3 changes from zero to the potential of point 4 is increased. This delays the point in time at which the exponentially decaying charging current of the capacitor drops to zero and thus increases the pulse width. The change in resistance required for this can, as will be shown later, be made automatically by means of a current-dependent relay.

Another embodiment of the invention is shown in FIG. Here IN denotes a cam disc which, due to the recorded pulse frequency, executes a step-by-step rotary movement. The cam disk is in position I during one pulse, in position II during the next pulse, and so on . H. it changes from one position to the other between two successive impulses. The position change takes place jerkily according to the prerequisite, which can easily be achieved by suitable design of the drive of the cam disk, for example by means of a rotating armature. As it rotates, this cam disc actuates changeover contacts one after the other, which can change their position between mating contacts, for example between b and ei. The pivot point of each changeover contact, for example point a1, is connected to a capacitor C, from which a connection to a pole of a current source E is made. The other pole of the power source is connected to the mating contact c i via a small resistor r. A connection leads from the contacts b, -b4 via resistors R, -R4 to a measuring device -i. The short-circuit connection at voltage source E , shown in dashed lines, or the voltage source shown in dashed lines elsewhere, are initially to be regarded as not being present.

During the transition of the cam disk from one position to the other, the changeover contact in question is temporarily switched upwards. For example,% #, when changing from position 1 to position II, the switchover contact is briefly switched from b to ei . As a result, the capacitor C, is charged to the voltage E via the small series resistor r. It thus stores the amount of electricity Q = C, - E. If the cam disk N has reached position II, the switching coefficient A, is placed back to bl, and the discharge of the capacitor C " begins, which takes place via the resistor R and the measuring device i. The size of the resistor R, and as the rest of the resistors is chosen so that this discharge is completed in a time required for the cam disc at the highest occurring pulse frequency for a full cycle Denoting m with t is the duration of a pulse, so performs the cam N in time. - t one full revolution, if n means the number of steps to be covered in a full revolution. At the highest occurring pulse frequency, the duration of the pulse is and the shortest occurring cycle time of the cam disk N is therefore n - ti ". The discharge of the capacitor C, via the resistor R, must be completed during this time, because then a renewed transfer of the contact A, to c, and thus a renewed charging of the capacitor C, takes place. If the pulse duration is generally t, then the amount of electricity C, -E or an average current Cl ' E is delivered to the measuring device by the capacitor c, in the time n-t. The same nt process takes place in the next and each subsequent step on the capacitors C "-C4 and the corresponding resistors RI-R4. The processes follow one another at the time interval between the arrival of the pulses. The total average current from all capacitors is vert therefore when the capacitance of all capacitors is equal to one another. Since the pulse duration t is reciprocally related to the pulse frequency, the mean current value is proportional to the pulse frequency.

The measuring device receives exponentially decaying current impulses from the individual capacitors, the duration of which can be determined by selecting the resistors RI-R4 so that each of these current impulses only occurs after the time -n - ti ", i.e. after one full revolution of the cam disk After the time t, a new current surge sets in due to the succession of capacitor discharges, namely before the previous current surges have completely subsided, since the pulse duration t is naturally considerably shorter than the time n - t .. i, Der The entire current flowing through the measuring device is created by superimposing the individual successive current impulses, so that a sawtooth-shaped current curve with little ripple results.

Instead of the discharge current, the measuring device can also be supplied with the charging current of the capacitor, with only the voltage source E having to be relocated to the point shown in dashed lines and the originally present voltage source having to be bridged by a conductive connection.

If the pulse frequency is lower than the maximum possible value, i. H. if the pulse duration is greater than 1.i. «, then the resistances Rl-R4 could be increased beyond the value that is determined by the time ti". This results from the fact that there is always only the requirement that the Discharge or charge in the time n - t .. i "is practically completed. As a result of this increase in resistors R, -R4, the ripple of the current would continue to be suppressed even with a lower pulse frequency.

For the embodiment example Fig. 2 and earlier for the embodiment example Fig. It has been stated that at a low pulse frequency the ripple of the current in the receiving measuring device can be reduced by increasing the values of the resistances r, -r, in Fig. 2 and the resistance R in Fig change in resistance may be about as follows by simple means automatically performed -Be: i. with the measuring device is connected in a relay that i at a current "" 2e i 2h i in is' a position and ntakte lf'o-through his resistors to the values of the resistors RI-R, or R determined earlier by the pulse duration ti ", whereas with a current i ' > i 22: 0 it is in the other position and through its contacts the resistances are set to the values R,' or R '. Here i 'is an average value between i "." and zero. R, '- R4' and R 'are roughly dimensioned as if the pulse duration belonging to i' were the shortest.

Claims (2)

PATENT CLAIMS: i. Receiving arrangement for pulse frequencies, in which the display device is traversed by the same amount of current with each received pulse. Discharge current surges of one or more capacitors flow through the display device, characterized in that the course of the capacitor charge or discharge currents is interrupted by switching means before decay at a selectable point in time or delayed so that the individual current surges partially overlap. 2. Arrangement according to claim i, characterized in that the charging current of a capacitor is limited by a contact (A) of a relay responsive to the pulses and by a valve (V) which is connected in parallel to the contact and the capacitor and at one adjustable partial amount of the charging voltage is permeable. 3. Arrangement according to claim 2, characterized in that the contact (A) is designed as a changeover contact which alternately controls two capacitors (C1, C.). 4. Arrangement according to claim i to 3, characterized in that a voltage divider (SP) is provided which is used to produce two partial voltages, to which a series resistor (R) is connected in series with the two capacitors (C " C,), and that (4) of the voltage divider and the connection point (3) between the resistor and capacitors .5. arrangement between a dividing point connected to the valve. I according to claim, characterized by a step by step by the incoming pulses moving switching device (N) by means of movable Contacts (A, - A,) briefly charges one of several capacitors (C1-C4) at a constant voltage (E ) at each step in a cyclical sequence, which is then via a measuring device and an associated delaying resistor (R1-R4 6. Arrangement according to claim 1 and 5, characterized in that the voltage source is connected to the circuit of the measuring device, so that the same is the charging current of the capacitor en is fed. 7. Arrangement according to claim i to 6, characterized in that suitable switching elements, such as ohmic resistors (R in Fig, i, R, - R, in Fig. 2), automatically switched over by the received current by means of relays, that also a sufficiently leveled direct current arises at a low pulse frequency. Cited publications: Austrian patent specification No. 139 637; French Patent No. 782,383; German patent specification No. 599 222.