DE2009900C3 - Remote display system - Google Patents

Description

The invention relates to a remote display system according to the preamble of claim 1. A Such a remote display system is already known (DT-AS 12 46 859).

From the DT-AS 12 65 206 is a system for recording the angular position of a shaft known, in which a code disk is arranged on the shaft, the corresponding a binary code has concentric tracks on which there are segments corresponding to the code Permanent magnets and segments without permanent magnets are located. Each track is at least one with a coil provided magnetic core assigned stationary. The inductance of the coil changes as a function whether the magnetic core is a segment with a permanent magnet or one without a permanent magnet opposite. An alternating voltage generator of a fixed frequency is connected to each of the via a resistor Coils connected so that, depending on the inductance of the coil, the AC voltage continues through a rectifier arrives at an evaluation circuit or not.

From DT-AS 12 67 251, the production of a coding disk is known, as it is in the system according to

> ° the DT-AS 12 65 206 is used. The disc contains a multitude of magnetic elements on each of its two surfaces, in concentric tracks are arranged. They can be distributed in the form of any suitable digital code. To the presence heat a magnetic field on the surface of the disc becomes a saturable magnetic toroidal core, which is provided with a read winding and an output signal winding, opposite the rotating one Disc arranged in such a way that the different

μ magnetic segments of the individual tracks on the Disc associated magnetic field is coupled with the core. If this is a magnetic segment is opposite, the flux surrounding the element saturates this core. Will the reading winding with a If the AC read signal is applied, the saturated core prevents the read signal from being transmitted to the Output winding appears. On the other hand, if the core is not in a magnetic field, a will be The read signal applied to the read winding is induced by the unsaturated core on the output winding. From DT-AS 11 06 087 there is a digital-analog conversion device for coding 2 "different Values of a measurand known. This arrangement provides for a coding disk in which in concentric tracks divided into segments are arranged according to electrical conductors, depending on which Coding one part is connected to an alternating voltage generator, but the other part is grounded. For every Slpur is an alternating voltage generator of another

Frequency provided. An electrically conductive pointer moves across the disk, depending on the angular position on the individual tracks either an earthed or an alternating voltage electrical Head opposite. As a result of capacitive coupling there is a mixture of frequencies in the pointer, whose generators are connected to the live conductors, to which the pointer is in a faces a certain position. The frequency mixture therefore gives the pointer position in coded form again. This known system is designed for the acquisition of analog values and is disadvantageous in that that a large number of connections between the center, which contains the frequency generators, and the Measuring point must be provided.

In the known systems in which there is a question of the size or the existence of a magnetic flux arrives, the influence of leakage flux turns out to be a problem when the magnetic flux is small or is nonexistent, which leads to unreliability.

6f From the above-mentioned DT-AS 12 46 859 is one Control and reporting device, known in particular for underground mining, with several transmitters and receivers of different transmission frequencies are connected to a common line

and by means of which several control and / or reporting commands can be transmitted at the same time. The transmitters can be connected to the receivers by a two-core cable. To the common connec-

dunssleitung are in the desired places, for example on different levels of the mine operation, command devices connected, which result from an inductance, a capacity and a switch. The oscillating circuit elements are in the individual command transmitters sized so that the voltages of the various frequencies can be selectively changed. Mii With the help of these passive resonant circuits, the voltage of the transmitter in question can be short-circuited, see above that the voltage is withdrawn from the downstream receiver. When the receiver is de-energized or only receives a correspondingly reduced voltage, an assigned relay drops out and it becomes this triggers the desired switching process.

To achieve this, however, the switch in the relevant command generator must be closed be, so that this known control and reporting device is not able to transfer any measured quantities.

From DT-PS 9 34 562 there is an arrangement for the transmission of a large number of measured values known, which are characterized by lower frequencies that are consistently in the same Change frequency range, and by means of which different carrier frequencies are modulated.

From the DT-AS 11 59 820 is finally a Remote display system with remote transmission of coded signals, preferably representing measured values a plurality of different transmitting or encryption stations known from which an equal number of Receiving or decryption stations is assigned, with a single transmission channel via the Signals composed of a fixed number of frequencies by selecting certain frequencies be sent one after the other by simultaneous transmission of the different frequencies. at In this known remote display system, each of the successive signals consists of a binary encrypted one Identification signal, the assigned frequencies of which preferably represent a measured value, and from an addressing signal, which is also binary-coded, its assigned frequencies to the receiving side Selection of those of a plurality of display devices are used with which a value represented by the binary identification signal is reproduced. Each of the consecutive Signals on the receiving end is, using filters, the number of which is the fixed number of Corresponds to frequencies, can be separated in the frequency-selective manner according to its binary combination options Way that the frequencies assigned to the identification signal to a corresponding number of by they get actuated switches that automatically do so by the frequencies of the binary address signal are controllable that a certain display device is applied, each one of the number of Frequencies that can be present in the binary encrypted identification signal, same number of input terminals. In this known remote display system, each of the consecutive Signals from a binary coded identification signal and from a binary one as well encrypted addressing signal, the latter serves to feed the respective signal in the receiving station to a correct display device.

The object underlying the invention is that the remote display system of the opening “Manned Art especially with regard to a larger one Improve the safety and reliability of the reading, while reducing the complexity of the circuitry should be kept comparatively simple for the entire system.

The solution to this problem results from the characterizing part of claim 1.

The reading operation in the remote display system of the present invention is against a leakage flux completely insensitive due to an adjacent permanent magnet on the number disc, so that the Remote display system according to the invention has the particular advantage that the permanent magnets are comparatively can be arranged in a tight space on the number disc, with a reading nevertheless with very great security is made possible.

In detail, the invention can experience an advantageous development that the oscillators and filter-receivers are arranged in one and the same place, and that the common double line from the oscillators to the passive resonant circuits and from there to the filter receivers is returned. A periodic one is useful at the location of the oscillators and filter-receivers Changeover switch is provided, which alternates the oscillators and the filter receiver over the common Double line connects with the passive oscillating circuits. This requires the entire remote display system only one common double line.

In detail, the invention can also experience an advantageous development that the passive Resonant circuits consist of series and parallel connections of chokes and capacitors. According to a As an alternative embodiment, the passive oscillating circuits can contain magnetostrictive oscillating elements.

In a particularly expedient embodiment, there is only one in his instead of several oscillators Frequency adjustable oscillator provided, thereby making the remote display system according to the invention is simplified even further.

In the following the invention is preferred by way of example Embodiments explained in more detail with reference to the drawings. It shows

Fi g. 1 is a block diagram of a device with the Features of the invention,

2A shows a perspective illustration of an electromechanical device used according to the invention Converter,

F i g. 2B shows an illustration of the electromechanical Converter equivalent circuit,

F i g. 3 shows a schematic illustration to explain the influencing of the electromechanical converter by a permanent magnet,

F i g. 4 shows a diagram of the resonance curve de; electromechanical converter in the state according to. F i g. 3,

Fig. 5 is a schematic representation to illustrate the schaulichuiig; Relationship between the on one to be read number disc mounted permanent magnets and the converter,

Fig. 6 is a conversion table for the decimal digits and the reproduced binary codes and

F i g. 7 and 8 block diagrams of modified embodiments of the invention.

In the following description of the execution form Men of the invention is assumed to explain that the counters located at the remote stations nii contain an order of magnitude, d. i.e. that only one

Number disc is provided. In general, such a number disc has ten digits to be displayed on. namely the numbers from 0 to 9. According to the invention is a device for converting these decimal digits provided in binary code. The reading devices for reading out ten different digits a number disc thus comprise four separate devices, namely one for each bit of the code.

In the embodiment of the invention shown in Fig. 1, the center with four low-frequency oscillators 10 to 13, which supply four fixed frequencies / Ίο, / "π, f \ 2 and f \} , a chopper 14, four connected to receive these output frequencies separate filter receivers 16 to 19 connected to the chopper 14, a binary-to-decimal converter circuit 20 connected to receive the output signals from these receivers and a display device 21 connected to the latter in the range from / Ίο ± Af to / "u ± Af. Each of the remote stations is provided with a counter 15 connected to the chopper 14. As mentioned, in the embodiment shown, the counter 15 is of an order of magnitude and has a number disk 150 and four reading devices 151 to 154, which are arranged close to the number disk 150 and facing it in a manner to be described below. The reading device 151 is triggered in a manner to be explained in more detail by the output frequency / Ίο from the oscillator 10 via the chopper 14. In a similar way, the reading devices 152,

153 and 154 activated by the output frequencies / Ή, fn and fn, respectively. As will be explained in more detail below, the outputs from these reading devices 151 to 154 convert each digit of the number disk into a binary word consisting of four bits. Before explaining the mode of operation of the device according to FIG. 1, let us first consider the structure of the reading devices 151 to

154 of the remote station.

) edc of the reading devices 151 to 154 used according to the invention has an electromagnetic one Transducer, for example a magnetostriction oscillator to which a tuning fork or a reed is assigned. Figure 2A illustrates an example of a usable in the invention electromagnetic or magnetostrictive oscillator, which consists of a Schwingplattc or reed 30, attached to one end of a coil 31 as the magnetostrictive Wandlerclcmcnt and an electromagnetic pick-up coil 32, which is the other The end of the vibrating plate 30 faces. Terminals 33 and 33 'form input terminals, while terminals 34 and 34 'represent output terminals.

Fig. 2B illustrates a circuit equivalent to the electromechanical transducer formed by a series and parallel connection of inductances Ld, Lc and Lm, a capacitor CM and a resistor R (Fig. 3). In this way, a frequency which brings the impedance of the parallel circuit to a minimum or maximum value and which sets the circuit current to a maximum or minimum value ensures a resonance. It should also be noted that the resonance state of a mechanical vibrating member shows a much larger P value and a more stable state than that of an electric vibrating member, which is not influenced by ambient conditions such as temperature and the like. When the input terminals 33 and 33 'receive an electrical signal with a resonant frequency of the circuit in a quadrupole using this circuit element with excellent selectivity, the mechanical oscillator is excited in a resonance state via the clektromechanical transducer element and gives an output signal of the same frequency via the terminals 34 and 34' like the input signal. It can be seen that the operation of this oscillator provides selective filtering. To the

ίο excitation of such an electromechanical Schwingbzw. Oszillalorsystcms, however, it is necessary to apply a direct magnetic field (a magnet) 35 to the Apply transducer element circuit as appropriate is shown in Fig. 3, which shows half of the block diagram of Fig. 2A. With others It is by controlling the mechanical position of the permanent magnet 35 relative to the words Converter element possible to stimulate the oscillation and the properties of the converter element contactlessly to vary. The invention is based on the principle set out above. Since the oscillator is at Absence of the magnetic field acting on it due to the frequency of the input terminals 33 and 33 ' applied input power signal is not excited to oscillate with the fundamental frequency, a corresponding direct current magnetization can be provided. Therefore, the magnetic flux of the permanent magnet 35 or the strength of the bias can be determined so that the oscillator only starts to oscillate is brought with a certain resonance frequency when the magnetic field is applied to its transducer part. at Application of this basic idea to the Fcrnan / .cigeanlagc will only then be the process of processing possible if there is an electrical input signal from the control center to the oscillator system at the remote station transmitted and at the same time this excitation state is generated when the magnet is attached to the transducer part is facing.

F i g. 4 shows a resonance curve of a circuit for the case that the terminals 34, 34 'according to FIG a filter are completed and the oscillator according to FIG. 2A from a four-terminal to a two-terminal is converted. The curve then represents the resonance characteristics of the oscillator from the input terminal

Men 33, 33 'from the perspective. For this reason, the oscillators of the reading devices 151 to 154 oscillate according to FIG. 1 not even when excited by currents of the frequencies / Ίο to f _n , as long as they are not magnetically biased by appropriate magnets.

According to the invention, the biasing voltage * magnets which excite the oscillators 151 to 154 into the resonance state are arranged on one side of a number disk. Fig. 5 shows an arrangement of permanent magnets, indicated by dots, on one side of the number disc. These permanent magnets are arranged at the points of intersection between the diameters indicated by the display digits and four circles K, L, and N, which are concentric in the axis Λ.

Fig. 6 shows a decimal-binary code conversion table for the Gray Codc. A binary digit I of the Kodi means the presence of a permanent magnet around

a binary digit 0 indicates the absence of a permanent magnet. Wh from I · 'i g. 5, a decimal / .iffer I does not represent any of the circles K, L, M and Λ /. The arrangement of the magnet on the circle K means ciin

Decimal digit 1 and so on. The previously described oscillators of the reading devices 151 to 154 are arranged on the circles K, L, M and N and are located on reading lines (not shown) close to one side of the number disk. The magnets can optionally be attached to the side surface of the number disc or embedded in it.

The device described above according to FIG. 1 works as follows:

In order to read off the value displayed by the counter 15 installed at a remote station at the control center, the oscillators 10 to 13 are set so that they oscillate at a frequency / Ίο to / "n switched to apply the output frequencies / Io to f \ i to the counter 15. The tongue 143 of the 2 'chopper 14 is then folded against the contact 142 in order to transfer the outputs from the reading devices 151 to 154 of the counter 15 to the selective filter receiver 16 to create in the central office to 19. below is now assumed that the counter 15 indicates a decimal digit 0th Under these conditions, according to figure 5 no magnetic flux of the permanent magnet on the axis X of the number disk and the decimal digit 0 intersecting radial line is present, so that none of the oscillators of the readers 151 to 154 will be cut by the magnetic flux of the permanent magnet ie frequencies / Ίο to / u excited to resonance. In other words, no input is fed to the filter receivers 16 to 19 via the chopper 14. In the absence of an output from the filter receivers, the binary-to-decimal converter circuit 20 identifies the digit represented by the counter according to the table of FIG. 6 as the decimal number 0, so that this number is displayed on the display device 21.

In the following it is now assumed that the counter 15 displays a decimal number 6. In this case, the reading devices 151 to 154 again simultaneously receive the frequencies / Ίο to fn. As shown in FIGS. 5 and 6, the reading devices 152 and 154 are facing permanent magnets at this point in time, while the oscillators of the reading devices 151 and 153 are not facing any permanent magnets. As a result, only the oscillators of the reading devices 152 and 154 vibrate while supplying vibration signals / I ₁ and / u to the filter receivers 16 to 19 via the contacts 143 and 142 of the chopper 114. This represents the same state d; ', r, as if the oscillators 11 and 13 of the central would be present in the oscillators 152 and 154 of the counter 15 at the remote station. The receivers of the control center show output signals from the oscillators apparently located at the local point. These two oscillator signals f \\ and / u appear on the outputs of the relevant filter-receivers 17 and 19, respectively. The converter circuit therefore identifies them

20 the digit represented by the counter as cine b as a result of the two signals with a frequency at An or / Ί), the digit b on tier display device

21 is shown. Others represented by the counter Digits can be read in a similar way.

F i g. Fig. 7 shows a modified embodiment of the invention in which each of the restrictive oscillator elements is serially formed into a two-conductor outlet; is switched on. In this embodiment, the oscillator 100 located in the control center has a variable output frequency. All reading devices 151 to 154 located at the remote station are connected in series to the oscillator 100, so that the resonance characteristics of the circuit comprising the reading lines Li, L _{2 are} utilized in accordance with the various frequencies. In this embodiment too, the reading devices 151 to 154 cooperate with permanent magnets provided on one side of a number disk. In this modified embodiment, the oscillation frequency of the variable frequency oscillator 100 is varied and the frequency at the point in time at which the current in the feedback loop corresponds to the corresponding frequency of the oscillator 100 of a resonance response is determined by a detector 200 located in the control center , wherein the ascertained information is transmitted to a processing device 210. The latter is coupled to the mode of operation of the oscillator 100 in order to store its oscillation frequency at the moment the detected signal arrives and to compare the stored frequency with the frequencies predetermined by the reading devices 151 to 154 and the permanent magnets interacting therewith, whereby the relevant, by the The number displayed on the counter is determined.

8 shows a further modified embodiment of the invention, in which four-pole filters are provided in a four-wire line. This Embodiment corresponds to that according to FIG. 7, as the filtered signal value of the respective Current is detected in the feedback loop, however, differs from it in that the Oscillators 101 to 104 work with fixed frequencies.

In this embodiment, the reading devices 151 to 154 are also electromechanical filters which are arranged in the manner of four-pole circuits and are controlled by respectively assigned permanent magnets. The reading lines Lu and L34 are vicarious lines, and if a collecting line La is used, the reading line can be a three-wire counter line. The detectors 201 to 204 are used to determine the maximum values of the feedback currents, ie the filtered frequency of the separation devices. A converter and processor circuit 300 converts the binary code signals of these detectors into decimal codes in order to reproduce the digits indicated by the number disc, although the reading devices 151 to 154 in the two embodiments according to FIGS. are shown, depending on the frequency and construction of the elements or circuits, they can also be connected in other desired circuit types.

Although the embodiment described above form are designed so that the Ablesecinriehtungei resonate with a frequency transmitted by the control center if the resonant circuit in question i a permanent magnet opposite layer is reached, the invention is not specific to this Arrangement restricted. For example, the reading devices can also be arranged so that si at a specific one transmitted by the headquarters Resonate frequency if they are not opposite a magnet, so that the reading device / ceases to oscillate, i.e. a zero output is produced when they are located opposite one another in a permanent magnet

709 638/1

Location.

In the embodiments described above, each reading device consists of a reed and a magnetostrictive transducer element attached thereto. Because of this, it is from the Equivalent circuit of the reader can be seen that these embodiments inevitably produce the parallel resonance phenomenon use. However, it is readily apparent that the reading device by a Vibrating element, such as a reed or a tuning fork with a piezoelectric attached to it or electrostrictive transducer can be formed which is associated with a magnetostrictive element can be. In this case it should be noted that the equivalent circuit of this reading device by a number of resonant circuit designs are formed. If the reading device is below Exploitation of electrostrictive or piezoelectric phenomena is formed by a vibrating element, the preload for the transducer element can therefore be supplied by the electromotive force, which is induced by the arrangement of the element in the magnetic flux, so that also a Remote display of the digital counter becomes possible.

It should also be noted that the invention usable decimal digital code not on the Gray codes are limited according to Figure 6; rather, any kind of decimal code can be used will. It is important to have an additional oscillator to perform a parity check in order to determine whether the reading signal is correct using the frequency of the additional oscillator or not, or to control the state of the line or the state of the entire installation including to check the local authorities. Furthermore, a chopper is explained in the foregoing description to simplify the description of its operation as a kind of modulator. The modulation frequency must be the ratio between the modulation frequency and the modulated frequency are sufficient if the reading frequencies / io to / 12 are used.

The invention thus creates a novel remote display device, in which the phenomenon of resonance between the magnetic flux from on one side of one Number disc arranged according to decimal binary codes Magnets and an oscillator system at a remote station in a control center is determined to enable remote reading of the digits represented by the number disc. The remote station therefore does not contain a power source and works without the use of any contact elements. There in addition, the entire reading device is made up of passive elements, works according to the invention Device flawless and reliable and can also be produced cost-effectively.

In summary, the invention therefore creates a remote display device for displaying on a Remote station displayed values in a central office, the remote station being a number disc, several on one side of the number disc arranged in accordance with predetermined decimal binary codes Permanent magnets and a number of passive oscillators arranged close to the number disc having a predetermined number of the passive oscillators each assigned to a bit of the code, while in the control center a single oscillator of variable frequency or several oscillators of different, frequencies assigned to the relevant passive oscillators, several to the oscillation frequencies the passive oscillators responsive selective filter receiver, a binary-decimal converter for the outputs from the filter receivers, a device for reproducing the output from the Converter and a modulator are provided. Each of the passive oscillators speaks with resonance to one of them assigned frequency transmitted by the control center when it enters one of the permanent magnets opposite position arrives, with the different oscillation frequencies from the center at the same time are applied to the passive oscillators at the remote station via the modulator, which connects the passive oscillators with the filter receivers in order to generate the To reproduce the digits displayed on the dial.

In addition 5 sheets of drawings

Claims (6)

Patent claims: 1. Remote display system in which several oscillators and Fiiier receivers of different, predetermined transmission frequencies are connected to a common double line and with which several binary signals can be transmitted simultaneously, with tuned passive resonant circuits being provided for a selective change in the voltages of the transmission frequencies that are connected to one remote point of the common double line can be switched on and off, characterized in that the passive oscillating circuits (151 - 154) can be switched on and off without contact or contact by magnetic fields from permanent magnets (35) by resonance only in the presence or absence of a magnetic field at a predetermined transmission frequency (FIO- F13) is present, and that the permanent magnets (35) are spatially arranged on a number disk (150) in accordance with a decimal binary code. 2. Remote display system according to claim 1, characterized in that the oscillators (10-13) and filter receivers (16-19) are arranged in one and the same place and that the common double line from the oscillators (10-13) to the passive Oscillating circuits (151-154 ) out and fed back from there to the filter receivers (16-19). 3. Remote display system according to claim 1, characterized in that the oscillators (10-13) and filter-receivers ( 16-19) are arranged at one and the same place and a periodic switch (14) is provided at this location, which alternately the connecting - oscillators (10 13) and the filter receivers (16-19) on the common two-wire line with the passive resonant circuits (154 151). 4. Remote display system according to one of claims 1 to 3, characterized in that the passive resonant circuits (151-154 ) consist of series and parallel circuits of chokes and capacitors (Fig. 2B). 5. Remote display system according to one of claims 1 to 3, characterized in that the passive oscillating circuits (151-154 ) contain magnetostrictive oscillating elements. 6. Modification of the remote display system according to one of claims 1 to 5, characterized in that instead of a plurality of oscillators, only one adjustable frequency oscillator (100) is used.