BE524526A - Further training in telemetry systems - Google Patents

Description

       

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   HEWITTIC S. A.R.L., residing in SURESNES (France).



   IMPROVEMENTS TO TELEMEASURE SYSTEMS.



  (inventors: J. Dubourg and M. Touly).



   It is known that telemetry transmission can be achieved by means of an acoustic frequency modulated at very low frequency, the latter frequency being the measurement value, while the first is a carrier wave characteristic of the station. program.



   Thus, on the same line, it is possible to transmit several telemetry, these being differentiated by the value of the carrier frequency.



   At the receiving station, filter circuits are available, making it possible to separate the various telemetry, that is to say, the various carrier frequencies. After detection of the latter, we obtain the very low frequency, that is to say, the characteristic frequency of the measurement, then by means of secondary demodulators, a current or a voltage, proportional continuous to the measured value. It can then be noted that it is necessary to have as many complete receiver assemblies, that is to say, filter, detector, secondary demodulator, etc., as there are telemetry transmitting stations. .



   To obviate this drawback, so-called cyclic distributions have been devised which reduce the number of devices, but are subject to inconvenient constraints to obtain the synchronization of the distributors (in particular sending of advance pulses).



   The object of the present invention is to significantly reduce the receiving equipment in single-line transmission AC telemetry systems, when the number of telemetry transmitting stations is high and when these measurements are not required. to be transmitted instantaneously

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 taneously.

   It is characterized in that the station receiving said remote measurements essentially comprises a device successively transforming all the measurement carrier frequencies into a single frequency, a single receiver system tuned to said single frequency, indicators with a large time constant. in number equal to the number of telemetry transmitting stations, devices for successively connecting said indicators to said single receiver and such that, for each indicator switched on at a given instant, said device transforming the carrier frequencies is simultaneously tuned to that of these frequencies which carries the measurement intended for said indicator.



   Amplifiers with a large time constant can be omitted. In this case, each measurement value is transmitted by the demodulator of the receiving system directly to an indicating device which itself retains said value, either definitively or temporarily until the next value of the same measurement is received.



   In what follows, with reference to the appended figures, some embodiments of the invention will be described by way of example.



   Fig. 1 is a diagram showing how the invention can be carried out when one is in the presence of transmissions at audible carrier frequencies, these being assigned, for example, to gas measurements, which are generally not sought. to obtain a high transmission speed.



   Fig. 2 shows the use of a multi-color curve recorder.



   Fig. 3 shows the use of indicating devices with blocked needles.



   Referring to fig. 1, we see that on a single line 16, are connected in branch, several transmitting stations 9, 10 ... 14.



  In each station, the frequency characterizing the measurement will vary, for example from f1 to f2, while the transmission carrier frequencies will be F1 for station 9, F2 for station 10, etc., respectively.



   The receiving station according to the invention is made as follows:
A frequency changer 1, consisting for example of a frequency changing lamp, is connected on the one hand to line 16 and on the other hand to a local oscillator 2. This lamp 1 supplies a frequency bandpass filter 3 fixed Fo, which itself transmits the currents having this frequency Fo to a demodulator 4. The latter may, for example, be of the type described in FIG. 4 of French patent no.858.394 of APRIL 25, 1939.



   On the other hand, the receiving station comprises a cyclic distributor 5, for example, a telephone selector with two banks 5a and 5b. The mobile brush of the bank 5a is connected to the local oscillator 2. The mobile brush of the bank 5b is connected to the output of the demodulator 4. The device for the automatic advance of the mobile brushes of the selector 5 is represented schematically by l 'electromagnet 15.



   The fixed contacts of bank 5a are connected to adjustable impedances 8.



   The fixed contacts of the bank 5b are connected to members 6 with a large time constant, for example direct current amplifiers with a large time constant which can be of the type shown in FIG. 2 of French patent n.972.936 of JULY 21, 1948, (set of reference bodies 16, 17, 18, 19 and 20). Each of these members 6 is capable of retaining the measurement value while the selector transmits the other measurement values to the other aforesaid members.



   In the example described here, oscillator 2 is assumed to be of the known resistance-capacitor type, so that the impedances 8 are made up

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 by resistance. These are determined so that each position of the movable brush of the bank 5a corresponds to a value of the frequency of the local oscillator 2, such that for each of the carrier frequencies F1, F2, F3, etc ..., the beats that originate in the frequency changer
1, have the frequency Fo to which filter 3 is tuned.



   For example, if the higher beat frequency is chosen, for the value of resistor 8 connected to the first fixed contact of the bank
5a the corresponding frequency F'1 of oscillator 2 will be such that:
F1 + F'1 = F 0
Likewise, for the value of resistor 8 connected to the second fixed contact of bank 5a, the corresponding frequency F'2 of the oscillator
2 will be such that:
F2 + F'2 = Fo
And so on, for the following fixed contacts of bank a, which are thus each assigned to one of the following carrier frequencies: F3, F4, etc ...

   Likewise, and in the same order, the selector bank 5b being actuated simultaneously with the bank 5a, its first fixed contact will transmit, to the amplifier unit which is connected to it, the measurement transmitted on the frequency F1, its second fixed contact will transmit that transmitted on frequencies F2, and so on.



   According to the invention, all the measurements leave the band-pass filter 3 on the same carrier frequency Fo. They all use the same frequency band f1 to f2. The same assembly, formed by the filter 3 and the demodulator 4, can therefore be used successively, using the various contacts of the selector, for the reception of all the measurements, which is particularly advantageous because this filter and this receiver are expensive devices.



   Of course, the embodiment described above lends itself to various variants, transmissions at audible frequencies can be replaced by high frequency transmissions of any type, mechanical selectors can be replaced by transmissions. fast electronic switches. As will be described below, the devices with a large time constant can be replaced by devices with locked needles, the release of which is obtained by a third bench provided for this purpose on the cyclic distributor. When the rotation of the selectors is rapid, the inertia of the measuring devices will be sufficient to keep the memory of the transmissions, in which case it is no longer necessary to have devices with blocked needles.

   Likewise the oscillator and the frequency changer can be included in a single device, etc.



   As already mentioned above, it is possible to eliminate amplifiers with a large time constant. In this case, each measurement value is transmitted by the demodulator of the receiving system directly to an indicating device which itself retains said value either definitively or temporarily until the reception of the next value of the same measurement.



   Referring to fig. 2, we see how we can use a multi-color curve recorder; 4 is the demodulator, 5a is the selector bank which produces by means of the resistors 8 the successive variations in frequency of the local oscillator of the receiving station and 15 is the coil which causes the step-by-step advance of the selector 5a .



   In accordance with the present invention, the bench 5b, the amplifiers 6 and the indicating devices 7 provided in FIG. 1 are replaced by a colored multicurve recorder and a distributor.



   The multicurve recorder is schematically represented by a recording tape 20 mounted on a drum 21, a tape 22 with several

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 colors mounted on two drums 23 and 24, and a needle 25. The tape 22 is arranged between the needle 25 and the strip 20. The member actuating the drum 21 is represented by a coil 26, and that actuating the drums 23 and 24 by a winding 27. Likewise, the winding 26 represents the organ which applies the needle and the tape to the recording tape, an organ 29, such as a spring for example, raising the needle when the action of said winding 28 ceases. Finally, the recorder comprises a movable unit, the winding of which is shown at 30 and which controls the relative position of the needle relative to the recording tape.

   This coil 30 is connected to the demodulator 4.



   The distributor is shown schematically at 31 by a drum comprising a finger 32 forming a movable contact, and by fixed contacts 33, 34 and 35 which are respectively connected to one of the ends of each of the coils 15, 27 and 28. The other ends of each of these coils are connected to the same terminal of an electric source 37, the other terminal of which is connected to the movable contact 32 of the distributor. This distributor is driven by a motor 36.



   The device works as follows:
Under the action of the member 26 suitably connected to an electrical source not shown, the drum 21 unwinds the recording tape 20 at constant speed. On the other hand, the motor 36 drives the distributor 31 in the direction of arrow F. The finger 32 first comes into contact with the fixed contact 33 which supplies the coil 15. The selector 5a switches on one of the resistors 8 thus giving the local oscillator, not shown, a determined frequency for which the demodulator 4 supplies one of the measurement values to be received. Then the movable contact 32 comes into contact with the fixed contact 34, which feeds the coil 27 for a short time, sufficient to advance the tape 22 by an amount such that it brings under the needle 25 the portion. of a certain color, for example, red.

   The movable contact 32 then comes into contact with the stationary contact 35, which supplies the coil 28 for a short time, sufficient for the needle 25 to strike the recording tape 20. The tape 22 being interposed between the tape. needle and said strip, a red dot is marked on said strip. The position of this point on the strip gives, with respect to a zero position, the amplitude of the movement of the needle under the action of the coil 30 of its mobile assembly, that is to say, gives the value of the measurement supplied by the demodulator 4 for the considered position of the selector 5a ..



   When the finger 32 leaves the contact 35, the coil 28 no longer acts on the needle, and the latter rises under the action of the spring 29.



  The device is ready to record a new measurement. The distributor 31 still rotating in the same direction, will again cause the same operations as before: advance of the selector 5a, which sets the local oscillator to a new carrier frequency, advance of the strip 22, which brings under the needle 25, a blue portion for example of this tape, pointed by the needle on the recording tape 20 which gives the value of the measurement supplied by the demodulator 4 corresponding to said new carrier frequency. And so on. The strip 20 therefore presents series of points of different colors. All those of the same color determine a curve, and there are as many curves as there are stations emitting measurements.



   Without departing from the scope of the invention, the selector 5a and the drum 23 can be mounted on the same axis, the winding 27 and the fixed contact 34 then being omitted. Similarly, the colored multicurve recorder can be replaced by a multicurve recorder designed so that the different curves are differentiated from each other no longer by color, but by a different line: dotted lines, broken lines, mixed lines, etc. .. or by writing a reference number next to each point.

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   Fig. 3 shows the use of indicating devices with a blocked needle. In this case, there are as many indicating devices as there are transmitting stations to be received, but in accordance with the present invention, the amplifiers 6 provided in FIG. 1 are deleted and ordinary indicating devices 7 are replaced by indicating devices with a locked needle.
In this figure, 5 is the selector which here comprises three banks;

   a bank 5a which serves to adjust the frequency of the local oscillator by means of the resistors 8, a bank 5b which connects the demodulator 4 to the various indicating devices, which are designated by the references 7, 7 ', 7 ", etc. ., a bench 5c which successively controls the release of the needles of the devices
7, 7 ', 7 "... etc, by means of members schematically represented by the windings 57, 57', 57" ... etc.



   The distributor used in this case is shown schematically at 31 by a drum comprising a finger 32 forming a movable contact, and by fixed contacts 33, 34. The fixed contact 33 is connected to one of the ends of the coil 15 and the contact 34 to the mobile brush of the bench 5c. This distributor is driven by a motor 36. Its movable contact 32 is connected to the pole of an electric source 37, the other pole of which is connected to the other end of the coil 15, as well as to the other ends of the coils 57. , 57 ', 57 "...



   The device works as follows:
Under the action of the motor 36, the distributor 31 rotating in the direction of the arrow F first brings its finger 32 into contact with the fixed contact 33 which supplies the winding 15 for a short time during which the moving brushes of selector 5 rotating by a certain angle which causes the following operations:
Bank 5a switches on one of the resistors 8 which sets the frequency of the local oscillator to a value allowing reception of one of the transmitting stations.



   The bank 5b switches on the indicator device, for example 7 ′ relating to said transmitter station, that is to say connects this device 7 ′ to the demodulator 4.



   The bench 5c connects to the contact 34 of the distributor 31 the member 57 'for unlocking the device 7'.



   Then, the distributor 31, continuing its rotational movement, for a short time brings its finger 32 into contact with the fixed contact 34, which supplies the winding 57 ', which releases the needle of the indicator 7'. . This free hand then indicates the value of the measurement supplied by the democulator 4.



   The distributor 31 continuing to rotate, as soon as the finger 32 leaves the fixed contact 34, the coil 57 'ceases to act. The pointer of the indicator 7 'is blocked in the position in which it indicates the value of the measurement supplied by the demodulator 4 from said transmitter station determined by the bank 5a.



   The distributor 31 continuing to rotate, the same operations are repeated, the bank 5a determining the reception of the measurement from a new transmitter, the bank 5b connecting a new indicator device, 7 "for example, the bank 5c preparing the measurement. The power supply to the release device 57 "relating to the indicator 7". This release device 57 "is effectively powered as soon as the contact 32, 34 is established. At this moment the indicator 7 "indicates the value of the measurement supplied by the demodulator 4 coming from the new transmitter. Then the contact 32,34 is broken and the needle of the indicator 7" is blocked. And so on for each of the measurement transmitting stations. Then the cycle begins again.



   The value of the measurement received from any transmitting station is

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 therefore kept by the indicating device relating to this station for the time necessary for the reception by the other indicating devices of the measurement values from the other transmitting stations.


    

Claims (1)

ABSTRACT. 1.- Improvements to alternating current telemetry systems in which carrier frequencies of various values transmit, on a single line, the same frequency band characterizing the measurements, these improvements being characterized in that the station receives Before said telemetry essentially comprises a device successively transforming all the measurement carrier frequencies into a single frequency, a single receiver system tuned to said single frequency, indicators with a large time constant in a number equal to the number of stations. telemetry transmitters, devices for successively connecting said indicators to said single receiver and such that, for each indicator switched on at a given instant, said device transforming the carrier frequencies, be tuned simultaneously to that of these frequencies which carries the measurement intended for said indicator. 2.- The device successively transforming all the carrier frequencies into a single frequency, comprises a frequency changer in which all the carrier frequencies interfere with the frequency emitted by a local oscillator, the latter being successively and periodically adjusted to as many values that there are carrier frequencies, each of these values being such that with the corresponding carrier frequency, the result is a frequency always of the same value, whatever that of said corresponding carrier frequency. 3. - The local oscillator is of the capacitor-resistance type, and its frequency is regulated by the variation of the resistance. 4.- The single receiver system, tuned to the frequency delivered by the device according to paragraph 2 and always having the same value, essentially comprises a filter allowing the only aforementioned frequency to pass, and a demodulator transforming the frequencies characterizing the measurements into a current, or a voltage, continuous, proportional to said frequencies characterizing the measurements. 5.- The devices according to paragraph 1, for successively connecting the indicators to the demodulator according to paragraph 4, and for simultaneously tuning the device, according to paragraph 2, to the carrier frequency of the measurement to be received, are made up of by the two banks of a rotary selector acting directly, or indirectly, one bank successively connecting said demodulator to the various indicators, the other bank successively connecting the resistors according to paragraph 3, to the local oscillator according to paragraph 2, the resistance, on the one hand, and the indicator, on the other hand, which are thus switched on at any instant, being both related to the same carrier frequency, that is, that is, to the same transmitting station. 6. - Each measurement value is transmitted by the demodulator of said receiving system to an indicating device which itself keeps said value either definitively or temporarily until the next value of the same measurement is received. 7.- Device characterized in that a single indicator device is provided, the latter being of the recording type and comprising appropriate organs for differentiating the notations of the measurements coming from the various transmitting stations and in that a distributor is provided which successively controls the adjustment of the local oscillator and in the appropriate order the actuation of the various organs of the recording apparatus. 8.- Device characterized in that there are devices with blocked needle, in a number equal to that of the transmitting stations to be received, <Desc / Clms Page number 7> and in that a distributor is provided which controls the adjustment of the local oscillator and the switching on of an indicating device, then the temporary release of the needle from the latter.