SU1742618A1 - Magnetostrictional transducer of linear displacement - Google Patents

Abstract

The invention relates to automation, in particular to devices that convert mechanical movements into a digital code. The purpose of the invention is to improve the noise immunity of the converter by eliminating the influence of synchronous interference. The device measures the distance between the acoustic emitter and receiver located on the evukoprovod according to the transit time of the double acoustic pulses separated by a random time interval, which is defined by a random number generator. Received signals are highlighted against interference using matching schemes. 3 il. (Ls

Description

The invention relates to automation, in particular to devices that convert mechanical movement into a digital code.

A known displacement transducer includes a fixed sound conductor, one end of which is clamped and the other is placed in a damper, serially connected start generator, shaper and recording coil, sequentially connected reading coil, read amplifier and trigger, the second input of which is connected to the trigger generator output. .

The closest technical solution to the present invention is a converter containing a stationary magnetostrictive acoustic duct, the ends of which are connected to dampers, which are successively connected to the recording coil and

a write pulse driver, a read coil connected to a read pulse driver, which is connected to an RS trigger that controls the switching of delay lines at times ti and g. And elements comparing the passage of pulses, a pulse counter and memory element.

The disadvantage of these converters is low noise immunity, due to the fact that when the information signals of the converter coincide with synchronous electromagnetic interference, i.e. multiple to the frequency of the information signals, the converter begins to perceive the interference as a read pulse. This violates the accuracy of the instrument readings.

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The purpose of the invention is to improve the noise immunity of the converter by eliminating the influence of synchronous interference.

The goal is achieved by the fact that in a transducer containing a sound conduit made of magnetostriction material there are two dampers installed at the ends of the acoustic duct, the amplifier-driver of the excitation pulses and connected to its output fixedly installed on the acoustic conductor a magnet mounted on the duct with the ability to move along the duct the receiving coil with a permanent magnet connected to the output of the last amplifier-driver of the receiving signals connected in series to a pulse generator, delay line, switch, second delay line, and second switch, the output of which is connected to the first input of the exciter pulse generator, connected to the output of the first delay line connected in series to the third switch, third delay line, and fourth switch; the output of which is connected to the second input of the amplifier-driver of the excitation pulses, a series-connected reference frequency generator, a pulse counter and a memory unit, an RS flip-flop, The first and second elements And the fourth line of the seed box, the output of the pulse generator is connected to the R-input of the RS-trigger, the output of the receiving signal amplifier is connected to the S-input of the RS-flip-flop and the input of the fourth delay line, the output of which is connected to the information inputs of the pepper and The third switch and the first inputs of the first and second elements are And, and the second outputs of the second and fourth switches are connected to the second inputs of the first and second elements, respectively, and a random number sensor is connected and sequentially connected memory register and multiplexer connected to the output of the first delay line, successively connected fifth switch, five delay lines, sixth switch, third AND element, OR element and sixth delay line, the output of which is connected to the counter reset input, and connected to the output of the first delay line connected in series the seventh switch, the seventh delay line, the eighth switch and the fourth And element, the output of which is connected to the second input of the OR element, the outputs of the first and second elements And cheny respectively to the third and fourth

the inputs of the OR element, the output of which is connected to the control input of the memory unit, the output of the fourth delay line is connected to the information inputs of the fifth and seventh switches, four outputs of the multiplexer are connected to the third inputs of the first and second, third and fourth, fifth and sixth, seventh and eighth switches, output

The RS flip-flop is connected to the control input of the memory register, the output of the pulse generator is connected to the fourth inputs of all switches, the outputs of the sixth and eighth switches are connected to the third and fourth inputs of the excitation pulse driver, the output of the first delay line is connected to the fifth fifth inputs of the first, the third, fifth, and seventh switches, and the outputs of the first and second And elements are connected respectively to the third and fourth inputs of the OR element.

Figure 1 presents the scheme of the proposed Converter; FIG. 2 shows signal timing diagrams; FIG. 3 shows an example of building a switch.

The magnetostrictive linear displacement transducer contains an acoustic conductor 1 from a magnetostrictive

material, two dampers 2 installed at the ends of the sound duct 1, the amplifier-driver 3 excitation pulses and the coil 4 fixedly mounted on the sound guide 1 connected to its output

excitation with a permanent magnet 5, mounted on the duct 1 with the ability to move along the duct 1 the receiving coil b with a permanent magnet 7 connected to the output of the latter

amplifier-shaper 8 receiving signals, serially connected pulse generator 9, delay line 10, switch 11. second delay line 12 and second switch 13, the output of which

connected to the first input of the amplifier-maker 3 excitation pulses connected to the output of the first delay line 10 are connected in series the third switch 14, the third delay line 15 and the fourth switch 16, the output of which is connected to the second input of the amplifier booster 3 of the excitation pulses connected in series generator 17 reference frequency counter 18

pulses and memory block 19, RS flip-flop 20, first 21 and second 22 elements A and fourth delay line 23, generator output 9 pulses are connected to RS-trigger RS 20, output of form amplifier 8

receiving signals connected to the S-input

RS flip-flop 20 and the input of the fourth delay line 23, the output of which is connected to the information inputs of the first 11 and third 14 switches and the first inputs of the first 21 and second 22 And elements, respectively, and the second outputs of the second 13 and fourth 16 switches, respectively, are connected to the second inputs of the first 21 and the second 22 elements And, respectively, as well as serially connected sensor 24 random numbers, memory register 25 and multiplexer 26 connected to the output of the first delay line 10 are sequentially connected fifth switch or 27, a fifth delay line 28, a sixth switch 29, a third element AND 30, an OR element 31 and a sixth delay line 32, the output of which is connected to the reset output of counter 18, and connected to the output of the first delay line 10 connected in series by the seventh switch 33, the seventh delay line 34 and the eighth switch 35, the outputs of the first 21 and second 22 elements AND respectively are connected to the third and fourth inputs of the OR element 31, the output of which is connected to the control input of the memory unit 19, the output of the fourth delay line 23 is connected to th inputs of the fifth 27 and seventh 33 switches, respectively, four outputs of the multiplexer 26 are connected to the third inputs of the first 11 and second 13, third, 14 and fourth 16, second, 27 and sixth 29, seventh 33 and eighth 35 switches, the output of the RS-flip-flop, respectively 20 is connected to the control input of the memory register 25, the output of the generator 9 pulses are connected to the fourth inputs of all switches, the outputs of the sixth 29 and eighth 35 switches are connected respectively to the third and fourth inputs of the amplifier forming 3 pulses of excitation For example, the output of the first delay line 10 is connected to the fifth inputs of the first 11, third 14, fifth 27 and seventh 33 switches, and the outputs of the first 21 and second 22 AND elements are connected to the third and fourth inputs of the OR 31 element, respectively. 11, 13, 14, 16, 28, 29, 33, 35 can be implemented, for example, according to the scheme shown in FIG. RS flip-flop 20, counter 18, AND 21, 22, 30, 36 elements, OR element 31, storing registers 19 and 25 can be implemented on known integrated microcircuits, a random number sensor 24 can be implemented on a microchip entering into the calculator device MK-61 (Electronics). The Converter operates as follows.

When the generator 9 is turned on, it generates a pulse (Fig. 2, plot a) going to the R input of the RS flip-flop 20 and setting it to the state of logic O. At one time, this pulse goes to the control (R) inputs of the switches 11 13, 14, 16, 27, 29, 33 and 35, setting them to a state where no circuit is connected. The impulse from the generator 9 is fed to the input of the dzt-10 of 24 random numbers, starting it on. number formation. Having generated a number, sensor 24 sends it to write to memory register 25 and further to the inputs of multiplexer 26. At this time, the last 15 generates a pulse on any of its four outputs, sending it to the control inputs of the corresponding switch pair (and in this example, the inputs Y switches 14 and 16). In this case, the switch 14 is connected by 0 signal input

(informational) to the output of the delay line 10, and the first output of the switch 16 is connected to the input of the amplifier-Forming 3 excitation pulses. At this time, the 5 m pulse going from the generator 9 and delaying on the delay line 10 (Fig. 2, plot b) goes to the third input of the shaping amplifier 3 and to the information inputs of the switches 11, 14, 27 and 33. 0 But in this case, only the switch 14 passes a pulse to the input of the delay line 15 mA time. The rest of the switch switches do not pass. Two pulses of 5s arrive at the input of amplifier 3: from the output of the delay line 10 and from the first output of the switch 16. They differ from each other at time t2. With the passage of pulses under the magnet 5 through the coil 4 in the duct 1, two similar mechanical impulses arise. After time, two current pulses occur in coil 6 (FIG. 2, plot d), which are passed to the S input of the RS flip-flop 20, set it to the logical 1 state. The RS flip-flop 20 5 generates a pulse that hits the control register entry 25 memory. At the same time, the latter sends to the inputs of the multiplexer 26 a number, which it recorded from the sensor 24 random numbers. , 0 The multiplexer 26 again generates a pulse on one of the four outputs so that the control pulse goes to the control inputs of the switches 14 and 16, while the switch 14 is disconnected from the output 5 of the delay line 19 and connected to the output of the delay line 23, and the switch 16 switches from the first output to the second, i.e. connects to the second input of the element 22. The two pulses coming from the amplifier maker 8 through the delay line 23 arrive at the input of the switch 14, the first inputs of all the elements AND, the fourth inputs of the switches 11, 27 and 33 are disconnected from the output of the delay line 23. The switch 14 transmits both pulses, delaying them by time 12 on the delay line 15, which passes through the switch 16 to the second — the input of the AND element 22 (FIG. 2, plot e). moreover, the first impulse of the received tutu is delayed by time 2 and coincides with the second impulse of the tutu, which came from the delay line 23. In this case, the AND 22 element sends a pulse to the input of the IL-31 element. And the 21, 30 and 36 elements of the pulse to the input of the OR element 31 are not sent. If at least one signal is present at the input, the OR element 31 generates a pulse going to the control input of the memory element 19 and through the delay line 32 to the control input of the pulse counter 18. On command, register 19 copies the number accumulated in counter 18 since the start of conversions (from the moment a pulse arrived from the output of the delay line 10 to the third input of the shaping amplifier 3). This number is proportional to the displacement being measured. A fast pulse from the delay line 32 (for a time shorter than the pulse period from the generator 17) resets the accumulated number in the counter 18.

The conversion cycle is completed and may be repeated first upon receipt of a clock pulse from the generator 9.

The advantage of the converter is that the interference pulse is read out, since the latter with very low probability can follow in a packet at intervals ti, t .... The delay times ti, t., Gz, t4 are selected from a number of prime numbers ( 1, 3, 5, 7 ...) to eliminate the influence of synchronous noise and their harmonics. The code on the storage register changes continuously as the X movement changes.

Thus, the proposed design improves the noise immunity of the conversion by reducing the effect of synchronous interference.

Claims (1)

A magnetostrictive linear displacement transducer, comprising a sound conductor made of a magnetostrictive material, two dampers installed at the ends of a sound wire, an amplifier forming a drive pulse and connected to its output fixedly installed on a sound conductor with a permanent magnet mounted on the sound conductor with the possibility of moving along the acoustic duct the receiving coil with a permanent magnet, connected to the output of the last amplifier-form tel of receiving signals, series-connected pulse generator, line delay, the switch, the second delay line and the second switch, the output of which is connected to the first input of the driver excitation pulse amplifier, connected to the output of the first 0 delay lines connected in series the third switch, the third delay line and the fourth switch, the output of which is connected to the second input of the pulse-shaping amplifier; 5, serially connected reference frequency generator, pulse counter and reg, RS-trigger, first and second elements AND and the fourth delay line, the output of the impuls generator 0 is connected to the R-input of the RS-flip-flop. the output of the receiving signaling amplifier is connected to the S-input of the RS flip-flop and to the input of the fourth delay line, the output of which is connected to the information inputs of the first and third switches and to the first inputs of the first and second elements And, and the second outputs of the second and fourth switches are connected to the second inputs of the first and second elements AND, respectively, characterized in that, in order to improve the noise immunity, it is equipped with serially connected random number sensor, a storage register and a multiplexer, connected5 to the output of the first delay line, serially connected by the fifth switch, the fifth delay line, the sixth switch, the third AND element, the OR element and the sixth delay line, 0 whose output is connected to the reset input of the counter, and connected to the output of the first delay line in series by the seventh switch, the seventh delay line, the eighth switch and the fourth AND element, the output of which is connected to the second input of the OR element, the outputs of the first and second elements 14 are connected respectively to the third and fourth inputs of the element 0 OR. the output of which is connected to the control input of the memory unit, the output of the fourth delay line is connected to the information inputs of the fifth and seventh switches, four outputs of the multiplex 5 are connected to the third inputs of the first and second, third and fourth, fifth and sixth, seventh and of the eighth switch, the output of the RS flip-flop is connected to the control input of the memory register, the output of the pulse generator is connected to the fourth inputs of all the delay lines connected to the fifth switch, the outputs of the sixth and eighth-d am first, third, nth and seventh comparators are connected to the respective comparators, and the outputs of the first and second Responsibly to the third and fourth elements And are connected respectively to the inputs of the amplifier-former 5 to the third and fourth inputs of the element excitation pulses, lane output.  2 .. mes. yig.1 AND UN Addr entrance Fig.Z