DE855470C - Device for the display, signaling, registration or control-technical utilization of a plurality of electrical or electrically representable measured quantities - Google Patents

Description

Device for display, signaling, registration or control technology Utilization of a large number of electrical or electrically representable measurands the Invention relates to electrical measuring systems for controlling a mechanism such as B. a registration device, depending on variable control or Measurands.

It has already been suggested that a cyclic working potentiometer with a number of resistance levels as essential Adjustment element of a measuring and relay circuit included, this potentiometer synchronously with one of the two interacting members of a recording device is controlled. Here, a large number of recordings can be made on a single Registration strips in accordance with an equal plurality independently variable control variables are generated. The proposed subject registration system requires a cyclically running potentiometer with just as many, each in one Number of resistance units subdivided into levels, such as quantities to be measured are.

Among other things, the invention relates to that described above Kind of creating related measurement and registration systems that are simpler to construct are or are used for other and more diverse areas of application can or what both advantages in themselves unite. In particular It is the object of the invention to provide a multiple recorder for measuring a plurality to create independent measured variables, with only a single potentiometer resistor is required for the desired multiple registrations. Another item of the invention is to provide a registration system with a cyclically operated resistance or impedance element, preferably of the potentiometer type, to operate that none Subdivision into a certain number of contact steps is required, rather than itself continuously changes. The invention is also based on a registration system of the kind in question here to create that is not only suitable for measurement of voltage changes, but also for measuring any variable Measured variables that are generated by corresponding changes in electrical circuit elements shown and with the help of an adjustable impedance element in a measuring circuit can be measured. The means provided to achieve these goals will be in the following description with reference to the embodiments shown in the drawings explained.

Fig. I to 4 show the current flows of four different measuring systems, each of which serves to accommodate a multitude of different variable sizes in a record the corresponding number of graphs on a single recording strip. FIG. 5 serves to explain the exemplary embodiment shown in FIG. 4, and Fig. 6 shows a tab as you would from each of these embodiments receives. 7 and 8 relate to a fifth embodiment and represent represents the transmitter or receiver circuit of a system that is used to send measured values serves, e.g. B. from an aircraft to a remote receiving station.

The system shown in Fig. I is used to test aircraft designs or similar composite constructions with regard to their vibration properties. A variety of vibration-sensitive pick-up coils, here z. B. by the three Coils 111, 112 and 113 shown are provided. These coils are at different Place the structure to be tested in place where there is excessive vibration could occur if the structure is overstressed at or near these locations or is damaged. A connection of each of the three coils 111, 112 and 113 is with connected to a common main line I60. The other coil connections are via the lines I6I, I62 and I63 individually with a corresponding number of Contact segments 141, I42 and I43 of a contact device 140 connected. If the Rotary contact 145 of this device comes into action, it rotates in the direction of the Arrow I46 and grinds one after the other over segments 141, 142 and 143. The rotary contact I45 is through line I64 to a terminal of the resistor 121 connected, which forms part of the potentiometer device 120. The second Terminal of resistor 12I is through a resistor I23 to the common Line I60 of the take-up coils III, 112 and 113 connected.

Resistance 121 of the potentiometer device. tung 120 is in a Number of resistance levels divided and contains a corresponding number of Contacts labeled 20, 19 IS, I7, etc. through I. Another, with o designated contact is provided between stages 20 and 1. This contact 0 is through line 185 via an auxiliary power source 186 to the common line 160 connected. If the rotary contact I25 of the potentiometer is set in rotation, he passes over the contacts 0 and 1 to 20 one after the other. The one for this type of execution The direction of rotation taken into account in P> is that selected for the contactor 140 is indicated by the arrow I26. The potentiometer contact 125 is connected by line 165 to a supply terminal of an amplifier 166, its second supply terminal to the common line I60 of the take-up reels connected.

The extraction circuit of the amplifier 166 is connected to a relay I67. The relay has a moving contact 168 and two fixed contacts I69 and 170.

The components and lines described so far form one Measuring circuit through which the relay depends on the changes to be measured Size can be operated. In the illustrated position of contact I45 is the take-up spool 111 via line 161, segment 141, contact 145, line I64 and connected to the ends of resistor 121 via line 160 and resistor 123. As a result, the voltage in resistor 12I depends on that generated in coil II 1 current voltage. The amplifier I66 and the relay 167 are through the Voltage drop between one end of resistor 121 and contact I2j energized. This voltage drop is a minimum when contact 125 makes its revolution on contact 20 begins and grows gradually as contact 125 moves towards the Arrow I26 moved on. The initial minimum value of the effective voltage drop depends on the rating of resistor 123. This dimensioning as well as that of the resistance I2I is matched to the sensitivity of relay 167; H. the minimum value (threshold value) the voltage required to trigger relay I67 with respect to the resistance value of the resistor 123 chosen so that under normal Operating conditions the relay remains idle when the potentiometer contact 125 the contact 20 strokes. On its further path, the contact 125 reaches a Resistance level at which the voltage drop acting on relay I67 is sufficient to exceed the threshold 1 value, so that now relay 167 is sufficient is energized to switch its movable contact I68 from contact I69 to contact I70. The angle at which the potentiometer contact is at this moment depends on the voltage supplied from the take-up reel 111, as a result this instantaneous position of the contact 125 indicates the size to be measured. To Completion of each revolution, d. H. when contact 125 leaves contact 20, the relay armature 168 falls back to the contact 169, whereby the capacitor 171 being recharged. Before it reaches contact 1, the contact passes over 125 however, the contact 0 and thereby leads the amplifier 166 and the relay 167 Excitation voltage from battery 186 increases. The capacitor is also discharged at the same time 171 through the control circuit every time a new revolution begins. The result is that the registration mechanism is caused to put a zero mark on the registration strip to record.

The measuring process is repeated with regard to the take-up reels 112 and 113, when contact 145 of device 140 is on segments 142 or

143 stands.

A registration mechanism 150 is provided to follow a plurality of curves in accordance with FIG to record the successive measurement processes of the arrangement described above. The registration mechanism includes a drum 151 which has a on its outer surface records responsive to current, preferably electrolytic recording strips. The drum serves as one of the electrodes that carry the electric current through Send thin strips. The second electrode consists of the pen 153, the mounted on holder 154. This holder is in engagement with a worm shaft 155 which is driven by a motor 157.

During a measuring period, the pen gradually moves over the drum 151 at a speed equal to that of the motor drive 157 is dependent. At the same time the drum is driven by a shaft 156 connected to the drum second drive motor 152 in rotation. In order to determine the vibration properties of a construction as described above, To determine, the motor 152 is started in direct proportion to the time, i. H. it can either be one from an alternating current source of sufficiently constant Frequency-fed synchronous motor or any other drive motor constant speed, e.g. B. a clockwork, to check the vibration properties the motor drive 157 is dependent on the frequency of the vibration generator put into action. When testing aircraft z. B. is the oscillation frequency depending on the speed of rotation of the aircraft engine. As a result, can the engine 157 with a generator driven by the aircraft engine which is proportional to the speed of rotation of the aircraft engine Supplies voltage, d. H. the speed at which the pen 153 moves Moved in this embodiment, the test frequency is proportional. Another means Operating the screech pen in this way is using a speedometer as drive motor 157.

The drum 151 of the registration mechanism is through line 175 connected to the fixed relay contact 170. The pen electrode 153 is through line 174 with a discharge circuit in communication, which over the movable Contact I68 and the fixed contact of the relay leads.

This discharge circuit contains a capacitor I7I, a current source: '72 and a resistor 173. In the illustrated rest position of the relay contacts the capacitor 171 is charged by the power source 172. As soon as the relay I67 responds, the movable contact 168 provides a connection between the capacitor 171 and the contact 170 and thereby closes the electrode circuit. Consequently the capacitor is quickly discharged through electrodes 151 and 153 and thereby calls a marking of the electrolytic recording strip emerges.

The drum electrode 151 or its drive is through a through Dotted line 132 indicated transmission with the contact 145 and with a Transmission gear 130 connected, which in turn has a through the dash-dotted line Line 131 shows a suitable coupling or connecting link with the movable one Potentiometer contact 125 is connected. Because of this coupling, the The rotation speed of the contact I45 is the same as that of the register current mel 151. The transmission between the contact and the potentiometer is like that chosen that the speed of rotation of the potentiometer contact 125 through the number of recording reels a certain multiple of the speed of the recording drum is, d. H. in the example shown has the transmission or the transmission gear 130 has a transmission ratio of 3: 1, so that the potentiometer contact 125 a makes full rotation, while the drum 151 and the contact 145 only a third one full turn. Contact 145 of device I40 migrates from one segment to the next, every time the potentiometer contact 125 one Has completed circulation, d. H. the three take-up reels 111, 112 and 113 are sequentially connected to the potentiometer device 120 so that at every full revolution the recording drum three independent measurements and registrations take place. During each individual rotation of the potentiometer contact 125 takes place a record on the associated section of the tab.

One made using the system described above Curve sheet is shown as an example in FIG. 6. The electrolytic recording strip is designated with I90. The recording dots form in each of the three sections the three corresponding curves 191, 192 and 193; according to the by the three take-up spools 111, 112 or

113 supplied variable voltage quantities 194, 195 and 196 are the corresponding zero lines. They consist of points, one of which is in the Moment is recorded when the movable contact 125 den Contact o at the beginning of each new turn. The abscissas each of the three curves 191, I92 and 193 represent the frequency, while the ordinates Each curve is proportional to the voltage in the pick-up coils and therefore the amplitude the oscillation at the point where the corresponding take-up coil is attached is.

A test measurement can be carried out in such a way that the vibration generator, z. B. the engine of the aircraft structure to be observed, can start and his RPM starting from the lowest tours up to the achievable maximum speed increases. The measuring system operates during the period of increasing speed held. The pen 153 lies from its initial position on the Strip, and with each rotation of the potentiometer there is a registration point recorded on paper.

If the amplitudes of any recorded graph exceed the safety limit exceed or if the resonance curves of any diagram have higher amplitudes, den show in comparison to the recording from an earlier test measurement, so this is a sign that there has been a change in the construction examined or a reduction in strength has occurred. Because the location of the take-up spools is known, the points of the tested construction where stronger or other vibrations occur can be easily limited. From the multiple diagram it is also clear that a higher oscillation amplitude starts at certain frequencies occurs in all or several places and is therefore a general error is due or whether the increase in amplitude is due to the immediate surroundings limited to a take-up reel and can therefore be attributed to local causes. the The width of the vibration maximum in each curve indicates the amount of damping. Changes damping are also an indication of changes in mechanical properties the construction and its materials.

The resistance levels of the combined resistance will be best dimensioned so that when the moving contact receives enough tension to one To record the registration point, he is in a linear relationship to that by the . The voltage generated by the take-up reel is present. This can be achieved by the levels of the combined resistance are graded so that their resistance value is successive increases with each level. If there is a reasonably accurate proportionality between the voltages of the pick-up coils and the recorded amplitudes are required, the resistance value of each step must best correspond to the formula Rma2 Rn = n, where Rmax is the total resistance of the potentiometer and n is the serial number of the successive resistance levels.

The resistance value Rmtn of the first stage, i.e. H. the value of the resistance I23 in Fig. I, Rmax should be Rmin = m, where m is the total number of resistance levels means.

A numerical example should explain these formulas in more detail: If one assumes; n 20 steps in a system with pick-up coils for a maximum pick-up voltage within the registration range of 10,000 mV and with a relay whose threshold voltage is 50 mV, then one can calculate the total resistance of the Potentiometer I2I select a value of 10 000 Ohm and measure the individual steps as indicated in the table below. Here, the resistance stage 20 indicates the value of the resistor 123, and the following stage numbers relate to the next and different subdivisions of the potentiometer resistor I2I shown in FIG. resistance Level no. in ohms 20 .............. 500 19 .......... 526 18 ............ 555 17 ................. 588 16 ................ ..... 625 15 ....... ... 667 14 .......... ...... 714 13 ............... 769 12 .... ....... .... 833 909 10. ...... 1,000 9. 1 III 8th . I250 7. ..... ... 1 429 6. ...... 1 667 5th .... 2,000 4 .... ..... 2,500 3 ............... 3 333 2. ............ 5,000 1 ..... 10,000 Here a certain non-linear graduation of the potentiometer resistance is described in order to obtain a proportional scale division.

Of course, any other scale division can also be used possible through a corresponding graduation of the resistance level. For example a logarithmic amplitude scale is sometimes useful.

The resistances belonging to the potentiometric contact device are best ohmic resistors, albeit inductive or capacitive potentiometers are also applicable. The amplifier and the relay are set so that at an input voltage of 50 mV at the amplifier the capacitor discharge acts on the recording paper and records a registration point. At a A voltage of 100 mV in the pick-up coil is 50 mV at the amplifier, if the movable contact adjusts itself to step 20 and thereby the voltage is switched off the first B'ixderstandsspule I23 of 500 ohms.

If the voltage generated in the take-up coil has a value of has only 300 mV, the moving contact will find the required voltage of 50 mV on contact step 6 where the resistor is 1667 ohms, i.e. H. one sixth of the total resistance of Ioooo ohms. As a result, recording is made only when the rotary contact I25 has moved from step 20 to step 6. Therefore the recorded amplitude now corresponds to only six resistance intervals, d. H. six times the relay sensitivity.

If only Ioo mV are supplied by the take-up coil, the voltage of 50 mV required for recording a registration point at contact 2, and the registered amplitude appears correspondingly shortened.

The above type of dimensioning results in linear proportionality between the measured quantities and the amplitudes recorded on the recording strip.

Instead of an amplifier 166 between the potentiometer device 120 and the relay I67, it is also possible. Reinforcing agent between turn on the pick-up coils and potentiometer. The use of an amplifier at the point indicated in the drawings, however, has the advantage that no linear Gain characteristic is required, which would be the case if the amplifier stage would be on the primary side of the potentiometer device.

Of course, instead of a potentiometer device with separate contacts and corresponding taps a non-subdivided or continuous resistance can be used, although it is more advantageous to use the The potentiometer resistance should be dimensioned in such a way that it is nonlinear or hyperbolic Change of the effective resistance value on the movement path of the rotary contact having.

The embodiment shown in Fig. 2 illustrates a system that is not used for measuring variable voltages, but for other quantities.

According to FIG. 2, there are three variable closure members 2II, 2I2 and 2I3 provided, the resistances or impedances in accordance with the change corresponding quantities to be measured. These three circuit elements are through the lines 26I, 262 and 263 with the segments 241, 242 and 243 of a contactor connected, the movable contact 245 of which is connected to a measuring circuit 280 which can be diverted with the connection being via lines 260 and 264.

The LIeß circuit forms a Wheatstone bridge and contains a constant one Impedance element 28I, a current source 282 (alternating or direct current) and the resistance element 22I of a potentiometer device 220, the movable contact 225 of which in the zero branches 283 of the bridge is in series with a relay 267 of the moving coil type.

I) el- movable potentiometer contact 225 and the hesvegliche contact 245 of the contact device are linked to each other by the dashed and dotted lines indicated engines 23I and 233 connected. The translation 230 of these engines is such that the potentiometer contact is three for each revolution of contact 245 makes full turns. The contact device is also with the drum electrode a writing unit 2jo connected, which is driven by a drive motor 252 in the through the direction indicated by arrow 256 is moved. The motor 252 has a constant Speed, d. H. with time proportional N% rsehul). The writing pen 253 of the Writing works is also constructed as an electrode. He sits in a holder 254, that engaged with one by the motor 257 in accordance with mi; a control variable driven screw shaft 255 stands.

Moving contact 268 of relay 267 works in conjunction with two fixed contacts 269 and 270. Capacitor 27I, a current source 272 and a Resistor 273 are connected to contacts 268 and 269 so that the capacitor is charged from the power source 272 when the movable contact 268 is the illustrated Assumes tightening position. When falling, the movable contact 268 switches the capacitor from the charging circuit and turns on contact 270, so that now the capacitor via lines 274 and 275 and electrodes 253 and 251 of the writing unit is discharged. The discharge creates a registration point on the drum 251 hostile current-sensitive recording paper.

The function of the registration device in relation to the contactor and the potentiometer device 220 is similar to that described above corresponding components of the system shown in FIG. An essential one However, the difference between the two systems lies in the construction and the function of the measuring circuits. In the system shown in Fig. 2, there is the bridge circuit unbalanced when contact 225 begins to revolve. Goes on his way the contact through a position in which the size of the then over the contact device with the bridge connected variable circuit member is balanced. In At this moment the current flowing through the zero branch 283 passes through the Zero value. As a result, the relay 267 is de-energized and discharges with its contact 268 the capacitor 271 over the electrodes and the recording strip of the writing works. Since at this moment the position of the potentiometer contact 225 determines the value of the indicates the size to be measured, gives the position of the recorded point on the drum surface and also show this value to the register strip. As a result, the are scored Measurement results and the appearance of the multiple curve sheet, in spite of those just described various functions of the measuring circuit, those of the one shown in FIG System similar (see Fig. 6).

From the above description it can be seen that systems according to of the invention can be produced in various modifications. For example can be a variable instead of a potentiometer device with ohmic resistances Inductance, e.g. B. a variometer or a variable capacitance, e.g. a variable capacitor, be used, depending on the particular characteristics of the measuring circuit or depending on the type of quantities to be measured. In all of these cases a non-linear graduation of the mutable member are used when there is a particular dependence of the recorded amplitudes of which the measurands are desired. About linear proportionality To achieve between the recording and the measured variable, the reverse can advantageously be achieved hyperbolic graduation, as shown in the numerical example above, apply. Here are a few examples that shed light on these possibilities to be discussed now.

The measuring system shown in Fig. 3 contains a bridge circuit 385, 386 and 387, respectively, for each of the variable circuit elements 31.1, 312 and 313.

These bridges are made from a common power source 300 either Alternating current or direct current supplied. A contactor 340 and the resistor 321 of a potentiometer 320 are connected to lines 361, 362, 363 and 364 in series in the zero branch of the multiple bridge arrangement switched on so that at the same time only one of the bridge circuits is effective, depending on the position of the movable contactor member 245 to the contact segments 34I, 342 and 343. The Input circuit of an amplifier 366 is with the line 360 and the movable Potentiometer contact 325 connected. Contacts 325 and 345 are driven synchronously and are for this purpose indicated by a dash-dotted line Engine 33.1 interconnected.

This engine contains a gear ratio of 330 or something like that causes the potentiometer contact 325 each time the contact 340 is one of the Sweeps over contact segments, makes a full turn. One also as a dash-dotted line Drawn transmission 332 connects the contactor to the drum of a recording device, that via a control circuit with the aid of one excited by the amplifier 366 Relay is controlled.

The writing mechanism, the control circuit and the relay are shown in Fig. 3 not shown since they are identical to the corresponding parts in FIGS are.

In operation, each of the backell circuits 385, 386 and 387 are imbalanced according to the variable size of their control element 311, 312 or 313.

Therefore, this is on the potentiometer during each individual measurement cycle Acting asymmetry voltage is a measure of the variable to be determined.

As a result, there is the voltage drop across the input terminals of the amplifier 366 also depends on the measurand. As the primary voltage of the amplifier too depends on the position of the contact 325 on the resistor 321, shows the Contact position at which the amplifier has just enough voltage (threshold voltage) receives the variable to be measured in order to make the relay respond. Therefore the recorder makes a record in the same way as in the embodiment shown in FIG. 01> - not the same for resistor 32I taps and contact levels are absolutely necessary, it is preferable to be measured in such a way that its game resistance value increases to an increasing extent during the circular route of the potentiometer contact 325 changes.

Fig. 4 is a simplified circuit diagram of a measurement system in which the potentiometer device is of a capacitive type. As in the previous example the writing mechanism, the control circuit and the relay are also omitted here, because these parts are similar to those described above. Three voltage generators Encoders or pick-up coils 4IWI, 412 and 413 are via lines 46I, 462 and 463 is connected to corresponding segments 441, 442 and 443 of a contactor 420. A line 460 connected to the second terminal of the transmitter leads to a capacitive one Potentiometer, the second connection terminal of which with the movable member 445 of the contactor 440 is connected. The capacitive potentiometer contains a variable capacitor 420 and in series with it an unchangeable capacitor 420 '. The input circle an amplifier 466, which is used to operate the relay of the control circuit, is bridged by the invariable capacitor 42d. The rotor of the mutable Capacitor 420 is indicated by a dash-dotted line transmission connected to the rotary contact 445. This transmission contains a transmission gear (not shown on FIG. 4) as the implementations of the described above Patent. The rotor of the capacitor and contact 445 are as shown by the dash-dot line 432 indicated, also coupled with the drum of the writing mechanism.

When the apparatus is in use, the rotor describes a full one Rotation during each of the three measurement periods, i.e. H. for each of the three during each Circulation of the contact 445 measuring points to be recorded. The voltage drop V2 in Condenser 420 'varies depending on the phase position of the condenser rotor 420. Therefore the position of the rotor iii corresponds to the moment in which the encoder voltage VX is sufficient, V2 üI, he increase the threshold value of the amplifier relay arrangement, the to measuring size. Since at this moment the Tormmel of the recorder a has the corresponding phase position to the writing unit, it then shows by the relay-influenced Control circuit recorded point also indicates the measured variable.

The change in capacitance of capacitor 420 is preferably so choose that the effective capacity grows gradually, similar to those above in relation to the conditions discussed in FIG. Such a one Dimensioning will now be explained with an example.

When the voltage V1 supplied by the transducer is at its highest level Value, e.g. B. 100 mV, the ratio <1: V2 should also be a maximum value be in order to V2 at the beginning of the rotation of the capacitor rotor towards the threshold value to reduce. If z. B. the threshold value is I mV, the capacitances should be C1 and C2 of the capacitors 420 'and 420 at the beginning of the potentiometer cycle approximately C1 C1: C2 = 100, i.e. H. C2 = 100. At a voltage V1 = 50 mV should V2 have the threshold value of I mV at half a revolution, i.e. H. at a Angular adjustment of the rotor from 900. In this position of the rotor should therefore C:: C2 be about jo, so C1 C2 = 50. Similarly, l <ei = 5omV V2 should be the threshold value have full I mV at 90 ° of full revolution, d. H. with an angle adjustment from I620. Therefore the ratio C1: C is approximately = 10, i.e. C1 C2 = 10 at V1 = 2 mV should be C1 = C2 for a rotation of 180 °. The result of this design method can be seen from the graph in FIG. This graph shows the capacity C2 of variable capacitor 420 as a function of the ratio C: C2 and the angular displacement α of the rotor or as a function of C1: C2 and V1. The resulting capacity curve (C1 of FIG. 5) has a relatively sharp one Curvature. This can be achieved by cutting the rotor plates accordingly. Rotors of this type are similar to those used in the well-known capacitors for heat frequency oscillators be used. The required maximum-minimum capacity ratio of C2 can can also be obtained in this way.

If the measuring range between 5 and 100 mV is selected instead of the 2 to 100 mV assumed above, the steep increase in capacitance can counteract the I800 (100 mV) end can be shortened so that the shape of the rotor plates corresponds accordingly is simplified.

A capacitor C2 (420) with a maximum capacity of 1000 µµf can be used so that at a frequency of 1000 Hz the impedance range of C2 (420) is between 150,000 ohms and several Ätegohm. The immutable Capacitor C1 (420 '), which is best of higher capacitance than C2 (420) and the capacitance between stator and earth can include in itself would then be a Have an impedance below 150,000 ohms. At a higher frequency of the measuring current would the impedance of the potentiometer capacitors can be reduced.

The system illustrated by the circuit diagrams of FIGS. 7 and 8 is intended as a flight analyzer for aircraft. The part of the system shown in FIG forms the gel applied in the aircraft. The part shown in Fig. 8 is the receiver set up in the ground station. A system of this type can either be used to test an aircraft during a test finger or for the automatic transmission of other measured variables from the flying aircraft to the ground station.

The transmitter part of the system according to FIG. 7 contains a number of measuring systems, the here z. B. from the six voltage generator coils or pick-up coils 71 1 to 7I6 exist. One terminal of each coil is on a common line 760 connected to one end of the resistance member 721 of a potentiometer arrangement 720. The other end of this resistance member is connected to the movable contact 747 Contactor 740 connected, the six via lines 76I to 766 with the Has coils 711 to 7I6 connected contact segments 741 to 746. Line 760 and the movable contacts 725 of the potentiometer 720 are connected to the input terminals of a connected to actuate an amplifier 766 serving relay 790. One between the ends of the resistance member 721 lying contact 780 is temporarily from the movable potentiometer contact 725 painted over, after the completion of a every turn and before the start of another.

The contact 780 is connected to an auxiliary power source 786, the in turn connected to the line 760, so that every time the potentiometer contact a new cycle begins, a current is sent through the amplifier and the relay will.

A motor drive 752 is used to control the potentiometer and the To operate the contactor, and for this purpose is indicated with both by the dash-dotted lines Lines indicated mechanical transmissions 73I and 733 connected. These transfers included a gearbox 730 or similar mechanism to set a gear ratio of 1: 6 between the contactor and the potentiometer, d. H. the potentiometer contact 725 makes six full turns for each turn of the potentiometer contact 747

The movable armature contact 768 of the relay 767 controls a discharge circuit, the one condenser sator 77 I, a current source 77t2 and a resistor 773 contains When contact 768 is idle, it will touch the fixed relay contact 769 and causes the current source 772 to charge the capacitor 771. When responding the relay moves contact 768 to fixed contact 770 and discharges thereby the capacitor 771 in the input circuit of a radio station, so that a brief impulse is sent to the ground station.

The normal radio equipment of the aircraft can be used as a radio transmitter will.

The ground station contains the recorder. The writing drum 751 is driven by a motor 758. The associated driver pin 753 is mounted in a holder 754 and is by means of a motor drive 757 controlled threaded shaft 755 guided over the drum. Drum and pen form electrodes to print on an electrolytic recording strip attached to the drum To cause recording dots as in connection with the previous patent realizations has been described. The output lines 774 and 775 of a radio receiver 79I are connected to the writing mechanism electrodes so that they can be temporarily activated upon receipt of an impulse from the aircraft transmitter 7go.

The drive 757 operates in proportion to time; H. at constant speed. The drive motors 752 and 758 are synchronized, preferably using the start-stop method. As a result, every position corresponds to the Potentiometer contact to the resistance element 72I of a certain angular position the drum to the pen.

At the beginning of each revolution, the potentiometer contact excites when it is passed over of contact 780 the relay 767 and thereby discharges the capacitor 771. As a result a pulse is sent from the transmitter 790 to the receiver 791. As a result, a Zero point recorded on the registration strip. If the contact 725 is now from Contact 780 moves on to the beginning of the resistance element 72I, it switches the Power source 786 and thereby leaves the movable relay contact 769 in the fall back position shown in the circuit diagram. This causes the capacitor 771 is being recharged. The relay initially remains de-energized while the potentiometer contact is made continues to migrate over resistance member 72I. However, as soon as the from the movable Contact voltage drop taken from the resistor element and fed to the amplifier exceeds the threshold value of the relay, it responds and makes its contact 769 to contact 770 again. Now another impulse becomes the receiving station sent and another point recorded on the recording strip. The angular position this point and thus its distance from the above-mentioned zero point shows the Current position of the potentiometer contact in the aircraft and as a result the size to be measured.

The points recorded in this way for a period of time form on the recording strip six curves that change a picture of the six under observation Sizes.

When the system for determining the behavior of an aircraft design is used during a test flight, it is one of the control circuit systems 711 to 716 best designed so that it responds to the revolutions of the aircraft engine, while the five remaining systems are vibration pick-up coils, as in conjunction with Fig. 1 described.

The curves recorded on the recording strip then permit a conclusion as to the vibration properties or the strength of the various Parts of the tested aircraft structure at different speed conditions.

A system like the one just described can also be used to advantage used, from a ground station, the flight conditions during a long-haul or overseas flights. In this case the control systems serve up to 716, such essential flight conditions as altitude, fuel consumption, speed through the air, speed above the ground, etc. and are to be measured accordingly built in and constructed. A similar system can also be used to the weather conditions in different places and at different altitudes from a flying airplane to a weather station.

To facilitate the synchronization of the motorized drives 752 and 758, the motor 752 could be built for continuous operation, while the motor 758 after the The start-stop principle works.

In this case, the above-mentioned zero signal sent by the aircraft, which serves to signal the zero position of the potentiometer, also to do so used to start the drive motor 758 so that it begins its work cycle. At the end of this work cycle, the 758 engine stops until it is driven by the the next zero signal is started again. Lines 759 make the connection between the starting mechanism (not shown) of the motor drive 758 and the receiver 791 required for the latter operation.

Apart from the advantages of a long-distance transmission system listed above according to the invention it is also evident that the weight to be borne by the aircraft is reduced to a considerable extent. Also the guide and the crew of the aircraft from the otherwise necessary monitoring and operation of the measuring device relieved. In fact, they can be broadcast via the radio from the ground station various flight states that are currently registered in the station will. The operation of the radio is controlled by the function of the measurement and transmission system not noticeably disturbed, since the above-mentioned signal pulses are of short duration and can be easily distinguished from ordinary radio broadcasts.

The numerical examples given above represent only a few Realizations of the invention represent and can depending on the requirements of each can be changed in individual cases. With regard to Fig. 4 it should also be said that, while only simple (Tel) reels 411, 412 and ßI3 are shown, the variable ones Control systems also parts of one or more measuring circuits, in principle like the Bridge circuits 280 and 385-387 of FIGS. 2 and 3, respectively, and preferably from FIG can be capacitive type. Such changes in the nightmare affect the essential Operation of the potentiometer, contactor, recorder and relay operated Control circuit not, as from the various, described in the above Systems can be seen.

The variable potentiometer device, especially the variable one Capacitor 420 of the system shown in Fig. 4, for reasons of space saving, Economy and shielding built into the drum of the recorder and the rotary link of the potentiometer device can be connected directly to the drum be married.

PATENT APPLICATION; CHE: 1. Device for display, signaling, registration or control-technical recovery of a WIehrzahl, preferably electrical or electrically representable measured variables, characterized in that the measured variable supplying measuring points in a cyclical sequence by means of switching devices on one of these Measuring points jointly assigned, its position constantly changing adjustment organ can be switched, with the balancing element comparing variables, compensation variables or supplies threshold values, whereby switching devices are activated, the one registration of the respective measured value when running through the adjustment position cause ng.

Claims (1)

2. Apparatus according to claim I, characterized in that between the measuring points and the revolving Abgle ichorgan with these and the drive The switching element coupled to the registration surface is provided for the measuring points. 3. Apparatus according to claim I and 2, characterized in that the electrical measured value by means of a rotating voltage divider with a fixed voltage A comparison is made until the response voltage of an electromagnetic one is reached or electronic relay (Fig. I). 4. Apparatus according to claim I and 2, characterized in that the electrical measured value by means of a rotating voltage divider in a bridge arrangement is adjusted when the registration is initiated by a zero relay (Fig. 2). 5. Apparatus according to claim I and 2, characterized in that the electrical measured value is transformed into the zero branch of a bridge arrangement and the adjustment device is changed in such a way that when the response value is reached, through an electromagnetic or electronic relay initiates registration becomes (Fig. 3). 6. Apparatus according to claim I and 2, characterized in that the electrical measured value on a capacitive or inductive voltage divider with constantly changing division ratio is given in order to achieve the response value an electromagnetic or electronic relay (Fig. 4). 7. Apparatus according to claim t to 6, characterized in that the registration impulses are given over a wireless link during synchronization of giver and recipient. 8. Device according to claim 2, characterized in that according to the full passage through the measuring range by the adjustment element, the switching element switches from measuring point to measuring point.