SU1091075A1 - Device for measuring speed - Google Patents

Abstract

A DEVICE FOR MEASURING THE SPEED, containing a speed converter in the number of electric pulses, connected to one of the inputs of the coincidence circuit, a timer connected to another input of the coincidence circuit, the output of which is connected to a pulse counter, serially connected to RAM, and a decoder, a reset pulse generator, connected between the timer and the pulse counter, as well as a read pulse shaper, connected between the timer and the RAM, which is characterized by the fact that, in order to expand the functionality It is equipped with a multiplier shaper connected between a timer and a pulse counter, the second input of which is connected to the reset pulse shaper, and the third - with a depressor output, the speed converter into the number of electrical impulses is made as a set of sequentially installed along the path reading elements connected with the coincidence circuit through the switch, the control input of which is connected to the decoder, while the first timer input is connected to the output of the reset pulse generator, the second - from the output ode decoder, and the pulse counter; O owl is made on the basis of the shift register.

Description

The invention relates to a measurement technique and can be used to measure the speed of a ride on a magnetic suspension. A device for measuring speed is known, which contains passage sensors that control the operation of the timer, which in turn removes time intervals filled according to the coincident pulse counting scheme received at the pulse counter input, the reset pulse shaper of the counter l. The disadvantage of this device is the hyperbolic dependence of the output signal on the speed and low accuracy, measurement, due to the large indicative time during which the velocity measurement is not performed. The closest to the proposed technical essence and the achieved result is a device containing a speed converter and a coincidence circuit included at its output, a counter, a random access memory and a recorder, and a controlled timer 2 is connected to the second input of the coincidence circuit. A disadvantage of the known device is small measuring range. The purpose of the invention is to expand the functionality of the speed meter. This goal is achieved by the fact that a device for measuring the speed, containing a speed converter in the number of electrical pulses, is connected to one of the inputs of the coincidence circuit, a timer connected to the other matching input, to the output of which. a pulse counter connected in series with the RAM and a decoder, a reset pulse shaper connected between a timer and a pulse counter, as well as a read pulse shaper connected between the timer and RAM, which is additionally equipped with a multiplier connected between the timer and the pulse counter of the multiplier connected, the second input of which is connected associated with the reset pulse shaper, and the third with the decoder output, the speed converter into the number of electrical pulses is made as a set of successively readout elements connected along the path are connected to the coincidence circuit via a switch whose control input is connected to the decoder, the first timer input connected to the output of the reset pulse former, the second to the decoder output, and the pulse counter is register-based. The proposed scheme provides a linear dependence of the output signal on the speed, due to its construction on the principle of a frequency meter. The continuous measurement mode is due to the large pulse duty cycle at the timer output (1.001 and less), as well as the presence in the circuit, RAM. Expansion of the measurement limits is achieved by switching in the process of changing the speed of the number of sensors, time interval and multiplier. The command for re-switching is aborted in the decoder installed at the RAM output. The drawing shows the functional diagram of the device. The device for measuring speed contains a block 1 of reading elements (passage sensors) installed near a profiled surface 2. Block 1, like the whole device, can be installed both on a train and on a canvas. In block 1, various types of sensors (electromagnetic, optical, magnetostrictive, etc.) can be used, rail joints, and bolted joints symmetrically along the track can be used with the profiled surface. The output of block 1 is connected to a switch 3, the task of which is to switch the number of working sensors on a command, the output of switch 3 is connected to the first input of a matching circuit 4, to another input of a matching circuit 4, a timer 5 output is connected. The timer consists of series-connected oscillator 6 pulses : a pulse generator 7, a controlled decoder 8 and a trigger 9, the trigger input is connected to the output of the generator 6, and the reset input is connected to the output of the controlled decoder 8. The output of the coincidence circuit 4 is fed to the input of the counter 10 pulse Oops, made in the form of a shift register, and the output of the counter 10 is set to RAM 11. The output of timer 5 also includes a driver 12 for impulses, the output of which is fed to, another input for RAM 11, a generator 13 of multiple bodies consisting of series-connected generator 14 impulses the pulse counter 15 and the controlled decoder 16, the output of which is connected to the shear bus of the counter 10, and the reset pulse generator 17, connected to counters 7, 10 and 15 by its output. The decoder 18 is installed at the output of the RAM 11, which controls the operation of the switch 3 and controlled decoders 8 and 16. The proposed device is built on the principle of a frequency meter, i.e. counts the number of pulses over a known period of time, although, unlike the known frequency metering schemes, the proposed device changes both the time interval and the number of sensors included, i.e. the number of pulses, in the process of changing the speed to extend the measurement limits. Since a change in the time interval (as well as a change in the number of pulses over this interval) leads to a change in the readings of the device without changing the speed, a multiplier is formed in the device to compensate for these changes. The device works as follows. At the initial moment, the first pulse from the generator 6 sets the trigger 9 to the working state, i.e. from this point on, the formation of a time interval begins, which gives permission for the passage of pulses from block 1 through the coincidence circuit 4. Let the time interval be equal to 1 s at the initial speed and up to a certain value. In this case, the switch 3 passes a pulse from all the sensors of the block 1 through the circuit 4 to match the input of the counter 10 pulses. The generator 6 generates pulses with a period of 1 micron, the counter of 7 pulses counts these pulses and upon reaching 1000 ms, i.e. 1 second, triggers a command on trigger 9, which overturns, thereby prohibiting the passage of pulses to the counter 10. With the falling edge of the time interval of 1 second, three blocks 12, 13 and 17 are triggered, which work for 1 ms - pause the two time intervals during which speed measurement takes place. First, a read pulse is generated from the counter 10 in RAM 11 by the driver 12. Next, if there is a control command at the input of the decoder 16, one or several pulses appear at the output of the decoder 18 at the output of the multiplier 13, then a counter pulse 7, 10 is generated and 15. Since the operation of the circuit at the initial speed is considered, there is no command at the output of the decoder 18, therefore, in the next period, the switch 3 connects all the sensors of block 1 to the circuit, timer 5 will form a max. the maximum time interval, and at the output of the generator, the multiplier will be 0. When the pre-selected speed reaches the output of the decoder 18, a command is received that, in the next period, switch 3 will turn off half of the sensors, timer 5 will form twice the time The multiplier actuator implies 2 pulses per counter 10 shear bus, i.e. counter readings will increase 4 times. With a further increase in speed, new commands will appear at the output of the decoder 18, which will switch blocks 3, 5 and 13 accordingly. As the speed decreases, switch 3 will connect an increasing number of sensors to the circuit, timer 5 will form a larger time interval, while the shaper multiplier 13 will increase the smaller multiplier to the counter 10. Thus, in order to extend the lower limit of the velocity measurement, it is necessary to increase both the number of sensors and the time interval during which the number of pulses is counted, which is directly proportional to the speed, and in order to extend the upper limit from 5 109,107 velocity measurements, you must have minimum number of sensors and reduced time interval to the optimal size. The proposed device for measuring speed measures the question of linear dependence of the output signal on speed as a result of the chosen measurement method: this expands the measurement limit by introducing automatic non-switching of the number of sensors, time interval and multiplier; It is possible to continuously measure the speed required for automatic control circuits as a result of the introduction of new connections and blocks, in particular RAM.

Claims (1)

DEVICE FOR MEASURING SPEED, comprising a speed converter to the number of electrical pulses connected to one of the inputs of the matching circuit, a timer connected to the other input of the matching circuit, to the output of which is connected a pulse counter connected in series with RAM and a decoder, a reset pulse shaper, connected between the timer and the pulse counter, as well as a read pulse generator, connected between the timer and RAM, characterized in that, in order to expand the functionality, it It is equipped with a multiplier shaper connected between the timer and the pulse counter, the second input of which is connected to the reset pulse shaper, and the third is connected to the decoder output, the speed converter to the number of electrical pulses is made in the form of a plurality of readout elements connected in series along the path associated with the coincidence circuit through the switch, the control input of which is connected to the decoder, while the first timer input is connected to the output of the reset pulse shaper, the second to the decoder output And a pulse counter is made on the basis of the shift register.