DE3411096A1 - Multi-channel measurement-value pick-up, transmission and processing system - Google Patents

Abstract

The invention relates to a multi-channel measurement-value processing system comprising fibre-optical analog measurement-variable pick-ups as measurement converters, a hybrid microprocessor-controlled measurement field concentrator and an optical-fibre cable for the bit-serial and time-division-multiplex transmission to a central station. During the bidirectional exchange of data, the measurement- variable pick-ups are also parameterised and diagnosed and actuators are driven via the optical-fibre cable. The invention is applied in multi-channel fibre-optical measurement-value transmission systems. <IMAGE>

Description

Multi-channel acquisition, transmission and

processing system The invention relates to a multi-channel data acquisition, -transmission and processing system with peripheral, arranged in the measuring field Converters with low power requirements.

Several fiber optic transducers have been proposed to be looped in parallel between a feed light guide and a signal light guide, that light pulses emanating from a pulsating feed light source differ in transit time obtained, which are caused by different feed and signal path lengths and to a time-multiplexed arrival of the modulated in the measured variable transducers Lead impulses in a light receiver at the end of the signal line. A flawless one The functioning of this system undoubtedly depends on a suitable choice of the path lengths away. It is therefore difficult to imagine that a measuring field can be served with this system can be, whose measuring points are arbitrarily distributed.

The invention was based on the object of a system mentioned at the beginning specify that also manages with a minimum of transmission lines, however does not provide any conditions for the length of the path to the individual measuring points.

This object is achieved according to the invention with the in the characterizing Part of claim 1 specified features solved.

In principle, the new system does not require any longer cable routes needed than the one mentioned above proposed system. However, the cable lengths to the individual transducers are not through Considerations about the runtime of the signals are given. Next is the new system at least in one embodiment also from a central control room only with Light fed with energy. Eliminate a substantial part of the transmission path With the new system, influences of changing light attenuation in the lines are possible Transmission error for the measuring signal, because intensity-analog measuring signals only over Relatively short line sections between intensity-analog signals emitting Accumulate measuring transducers and the measuring field concentrator. Via the light line between the measuring field concentrator and the central control room, on the other hand, are digital Transmit signals, which can be read out by the line attenuation as a first approximation is not affected. The fiber-optic measurement transducers can both be intensity analogs as well as frequency-analog signal outputs. In the case of the latter, the measured value is mapped as the frequency of a pulse train or an alternating voltage.

An embodiment of the measuring point selection switch consists of one electro-optical converters for feeding purposes.

A star coupler for light feed lines is connected to it to the transducers. Apply signal lines from these sensors In the MerJfel dkonentrator a multiple arrangement of op-to-electrical measuring signal converters.

Another embodiment of the measuring point selector switch sets consists of a multiple arrangement of electro-optical converters for light feeding purposes the transducer, a star coupler in the signal paths from the transducers and an opto-electrical measuring signal converter after the star coupler.

At least the aforementioned multiple converters are expediently one after the other clock-controlled by the microprocessor contained in the measuring field concentrator.

With bidirectional data exchange via the fiber optic cable, in an advantageous manner a parameterization or diagnosis of the converters or measured variable transducers can be done from the central control room. It is also possible to use the fiber optic cable with fiber-optically controllable actuators in the measuring system to be included, as they are from "Wiss. Ber. AEG-TELEFUMKEN" 55 (1982) 1-2, p. 22 are known. Also the use of actuators with pneumatic control pressure is possible.

In addition to the above-mentioned transducers, the system can can also be supplemented by further locally battery-fed measured variable transducers.

These transducers expediently have outputs for bit serial Signals on.

The operating energy for the measuring field concentrator can be supplied by a local battery can be removed.

The operating energy of the measuring field concentrator is partly or completely also as light energy from the central control room via a second wire of the control room with the Neßfeldzentrator connecting fiber optic cable can be fed.

Advantageously, several can each become measuring field concentrators Combined microprocessor-controlled, hybrid measuring point selector switch with a downstream Analog-digital converter, memory and digital light modulator via light distributor and a single fiber optic cable connected to a central control room.

Analog-digital converter, memory and microprocessor allow one Signal preprocessing in the measuring field concentrator, which is often due to, for example, a non-linear characteristic of some transducers is desirable. With deii microprocessor are also calculations for data concentration, e.g. limit value formation, plausibility test etc., feasible.

The invention is explained in more detail with reference to a drawing with three figures.

FIG. 1 shows a schematic representation of the new measured value processing system.

FIG. 2 shows an embodiment of the measuring field concentrator mentioned Units as a block diagram.

Figure 3 shows an embodiment of an additional battery-powered Transducer.

In Figure 1 is a central control room 1 via a two-core fiber optic cable 2 connected to a measuring field concentrator 3. The measuring field concentrator is in his The entirety is a hybrid component, it contains opto-electrical input circuits and electro-optical output circuits and purely electrical units that are explained in more detail in FIG. A local battery is the source of its operating energy 4 provided. The operating energy can, however, at least partially also be used as light energy can be fed from the control room 1 via one of the two wires of the fiber optic cable 2. The opto-electrical input part of the measuring field concentrator 3 is also two-wire Fiber optic cables 5, 6 and 7 with individual converters, here measuring transducers 8, 9 and 10, connected to a measuring field. Influence in the transducers 8 and 9 Physical quantities in each case via the one wire of the fiber optic cables 5 and 6 light supplied in such a way that the light intensity in the measured variable transducer 8 and the light is frequency analog nodulated in the measured variable sensor 9. In each The measurement signals modulated in this way are transmitted to the other wire of the fiber optic cables 5 and 6 the Neßfeldzentrator 3 returned. The measured variable recorder 10 is a hybrid Transducer thought, in which a physical measured variable is an electrical part of the Au- affected in such a way that it uses an optical transmitter caused to transmit optical signals modulated to be measured. The operating energy A local battery 11 provides an exemplary embodiment for the measured variable pick-up 10 of the measured variable pick-up 10 is explained with reference to FIG. With bidirectional Data exchange via the fiber optic cable 2 is also a parameterization or diagnosis the transducers 8, 9, 10 are possible.

In addition, control signals can also be sent via the optical lines to actuators that can be included in the system as converters. For this optically controllable thyristors are suitable. Furthermore, the application of Pneumatic control valves that do not require electrical control power are possible. They require continuous control through control pressure. This could can be specified by a pneumatic control valve, the pressure of which, for example is monitored by a piezoresistive sensor. The supply helps poor people with energy electrical functional components for signal pressure generation can be achieved by batteries or if there is a limited demand for auxiliary energy, it can be done by means of a feed light.

The control commands are then canceled, for example, by means of a brief interruption the feeding light supply. Forward and backward impulses can e.g. B. can be recognized by different duration.

Figure 2 shows an embodiment of a measuring field concentrator represent. At the outputs of a star coupler 20 is one of the wires of the fiber optic cable 5, 6 and 7 from Figure 1 connected. The other wires of this fiber optic cable are at optical inputs of a multi-faceted arrangement 21 of opto-electronic Wancllern. An input of the star coupler 20 is connected to the optical output elek-tro-o; ischen converter 22 connected. At least the array 21 of op Lo-electronic converters are successively controlled by an electronic control unit appropriate which is generated in a microprocessor 23. Of the Microprocessor 23 also controls an analog-to-digital converter 24, at its input the electrical outputs of the multiple arrangement 21 of opto-electronic converters lie parallel. Outputs of the analog-digital converter 24 are connected to inputs of a Memory 25 which is part of the microprocessor 23 is connected. With the help of the microprocessor the content of the memory 25 can be read out sequentially, a corresponding output of the memory is at the modulation input of a digital light modulator 26. Am optical output of the light modulator 26 is a bit-serial signal that through one wire of the optical fiber cable 2 from FIG. 1 is not shown in FIG Wait is fed. The operating energy for all parts of the shown in FIG The measuring field concentrator provides a local battery 27. At least some of the can Operating energy also from the control room as light energy via the second wire of the fiber optic cable 2 are fed. The light energy is in an opto-electrical converter 28 in to transfer electrical energy.

Another possibility to switch off the Neßstellenscla] ter is not shown in a figure. Instead of a multiple opto-electronic wall glue 21 a multiple electro-optical converter, for example several controlled light-emitting diodes to be provided, the electro-optical Waidl He 22 to replace the feed @ wire connections with a 1 opto-electronic converter to swap the fiber optic cables 5, 6 and 7 with their measuring signal wire connections and to control the electrical side of the multiple transducer from the microprocessor 23, while the output of the opto-electronic converter to the Analog-Digi ts 1 converter 24 is connected.

FIG. 3 shows a battery-powered measuring device according to Type of transducer 10 shown in FIG. 1.

The fV; eß size controls an amplifier 30, whose output output signal an analog-to-digital converter 31 is supplied. The digital values from the output of the analog-to-digital converter 31 are stored in a microprocessor 32 and processed. They control the electrical input of an electro-optical light modulator 33 so that it emits a bit-serial signal via an optical fiber 34. the Operating energy for the units 30 to 33 is provided by a local battery 35. A second one Wire 36 guides the light to be modulated to the electro-optical light modulator 33 from the measuring field concentrator.

10 claims 3 figures

Claims (10)

Claims ö) 1 multi-channel measurement acquisition, transmission and processing system with peripheral converters arranged in the measuring field Power requirement, that is, a number fiber optic controllable converter with intensity analog and / or frequency analog Signal outputs is available, - a microprocessor-controlled, hybrid measuring point selector switch with downstream analog-digital converter, memory and digital light modulator is present and that - a fiber optic cable (2) for a bit-serial, time-division multiplexing Data exchange with a central product is available. 2. Nehrkanaliges measuring system according to claim 1, d a d u r c h g e k e nn z e i c h n e t that the measuring point selector switch consists of an electro-optical Converter (22) for feeding purposes, a star coupler (22) for Li.speiseleibungen to the transducers (8, 9, 10) as transducers uw1 multiple opto-electrical Measuring signal converters (21) consists. 3. Nehrkanaliges measuring system according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the measuring point selector switch consists of a multiple electro-optical Converter for light feeding purposes of the measuring sizes upwards as a converter, a star coupler consists in the measurement signal path and an opto-electrical measurement signal converter. 4. Nehrkanaliges measuring system according to claims 2 or 3, d a d u It is noted that at least the multiple converters (21) are sequential are clock-controlled-t. 5. Multi-channel measuring system according to one of claims 1 to 4, d a d It is indicated that the transducers (10) act as converters with bidirectional data exchange via the fiber optic cable (2) from the central Control room (1) can be supplied with control commands for parameterization or diagnosis. 6. Multi-channel measuring system according to one of claims 1 to 5, d a d u r c h e k e n n n z e i c h n e t that fiber-optically controllable actuators as Umforr, ier are available, the setting commands for bidirectional data exchange Received via the fiber optic cable (2) from the central control room (1). 7. Nehrkanaliges measuring system according to claim 1 or one of the preceding Claims that the local battery fed Measured variable pickups (10) are provided with outputs for bit-serial signals. 8. Nehrkanaliges measuring system according to claim 1 or one of the preceding Claims that the operating energy for the microprocessor-controlled measuring point selector switch (20, 21, 22), the analog-digital converter (24), memory (25) and digital light modulator (26) from a local battery (27) is delivered. II 9. Multi-channel measuring system according to claim 1 or one of the claims 2 to 6, that the operating energy for the microprocessor-controlled measuring point selector switch (20, 21, 22), the analog-digital converter (24), memory (25) and digital light modulator (26) at least partially as light energy is supplied from the central control room. 10. Multi-channel measuring system according to claim 1 or one of the preceding Claims, d a d u r c h e k e n n -z e i c h n e t, that several each become measuring field concentrators (3) combined microprocessor-controlled, hybrid measuring point selector switches with downstream analog-digital converter, memory and digital light modulator Via light distributors and a single fiber optic cable (2) with a central control room (1) are connected.