RU33242U1 - TIME INTERVAL METER - Google Patents

Abstract

A time interval meter, characterized in that it contains two input differential dividers, two trunk receivers, two optocouplers, three autonomous power supplies, a crystal oscillator, a microcontroller, an indication unit, two output pulse shapers with LEDs, while the output of the first differential divider is electrically connected with the input of the first trunk receiver, the output of the first trunk receiver is electrically connected to the input of the first optocoupler isolation, the output of the first optocoupler the language is electrically connected to the INTO interrupt input of the microcontroller and the input of the output output pulse shaper with an LED, the output of the second differential voltage divider is electrically connected to the input of the second main receiver, the output of the second main receiver is electrically connected to the input of the second optocoupler, the output of the second optocoupler is electrically connected to the input interrupt INT1 of the microcontroller and the input of the driver of the output stop pulse with the LED, the input of the microcontroller is electric it is connected to the toggle switch for specifying the measurement ranges, and the input of the reference frequency of the microcontroller is electrically connected to the output of the crystal oscillator, the output of the microcontroller is electrically connected to the input of the display unit, and the RESET button is electrically connected to the reset input of the microcontroller, to the reset input of the driver of the output output pulse with the LED with a reset input of the output stop pulse shaper with an LED, and the autonomous power supply from the first source is connected to the first differential divider

Description

TIME INTERVAL METER

The utility model relates to measuring equipment, namely to time interval meters, designed to measure the temporal parameters of fast-moving physical processes and can be used in mining and other industries.

It should be noted that there are many instruments and devices that at different times were used to measure the temporal parameters of fast-moving physical processes.

Known adaptive time interval meter (RF patent No. 2043648, MKI G04F10 / 04, 1991), comprising a pulse generator, a control unit, a pulse counter, an information receiving unit, input buses, an FR element, a shift register, a controlled frequency divider, an installation bus, a source single signal and code bus.

Known high-speed vernier time interval meter (RF patent No. 2127445, MKI G04F 10/04, 1997) containing a reference generator, input device, first and second vernier meters, trigger, sectioned delay line with n - 1 outputs, a latching and control unit.

A device for multi-channel measurement of time parameters (RF patent No. 2180450 MKI G04F 10/04, 1999), containing a clock, a memory device, two counters, one of which is addressable, two RS-trigger, multi-channel source of time intervals, two elements And , an OR-NOT element, a recording device with parallel input-output of information and a control input, two elements NOT, element 2 "2-OR, element 2 2-OR-NOT, differential voltage comparator, physical quantity sensor, three resistors, diode, condens Torr, the keys to the control input, the launcher bus read control bus, the bus voltage reference.

The disadvantages of the devices described above include their lack of noise immunity, due to the reasons set forth below. In accordance with safety requirements, the test site for pyrotechnic products is located at a distance from several meters to tens of meters to the place where

MKI G04F 10/04

placed instrumentation. When testing pyrotechnic products, powerful electro-magnetic disturbances occur. Known instruments for measuring time intervals are not designed to work with measuring circuits of such a length and with exposure to electromagnetic disturbances of this magnitude. These devices cannot work with sensors such as:

-pressure with an electromagnetic creeper;

bursting wire;

-ionization;

-other low-impedance voltage pulse shapers;

without some refinement, they do not control the resistance value of the sensor with measuring circuits, which is relevant for such a length of the measuring circuit and the possibility of their being damaged by “triggered products. All this leads to unstable operation of devices, i.e. to prematurely stop or not to start the device (the so-called “not-serif”). Considering that testing of some products is carried out in a single embodiment, and the cost of repeating testing of other products can be hundreds of thousands of rubles, the development of new devices designed to measure time intervals is still relevant.

The task to which the proposed technical solution is directed is to create a new device designed to measure time intervals and to increase the reliability of measuring time intervals of pyrotechnic products.

To solve the problem in the proposed time interval meter, which contains two input differential dividers, two trunk receivers, two optocouplers, three autonomous power supplies, a crystal oscillator, a microcontroller, an indication unit, two pulse shapers of the output signals, the output of the first differential divider is electrically connected to the input of the first trunk receiver, the output of the first trunk receiver is electrically connected to the input of the first optocoupler isolation, the output of the first opto hydrochloric junction connected to the input and the microcontroller interrupt INTO input of the output trigger pulse to the LED, the differential output of the second voltage divider electrically connected to the main input of the second receiver, the second output of the main electrically connected to the receiver

the input of the second optocoupler isolation, the output of the second optocoupler isolation is connected to the interrupt input INT1 of the microcontroller and the input of the output stop pulse generator with an LED, the input of the microcontroller is electrically connected to the toggle switch for setting the measurement ranges, the input frequency of the microcontroller is connected to the output of the crystal oscillator, the output of the mythocontroller is electrically connected to the input display unit. The RESET button is electrically connected to the reset input of the myth controller, with the reset input of the driver of the output trigger pulse with an LED

and with the reset input of the output stop pulse generator with an LED. Autonomous power supply from the first source is connected to the first differential divider, to the first main receiver, to the first optocoupler isolation, autonomous power from the second source is connected to the second differential divider, to the second main receiver, to the second optocoupler isolation, autonomous power from the third source is connected to quartz generator; to the mythocontroller, to the display unit; to the driver of the output pulse start with the LED, to the driver of the output pulse stop with the LED.

The essence of the model is illustrated by the basic block diagram of a time interval meter, which is depicted in the Figure.

The connections between the elements included in the block diagram are described below.

The sensor input, Input1, is electrically connected to the differential voltage divider 1, and the sensor input, Input 2, is electrically connected to the differential voltage divider 2. The output of the differential voltage divider 1 is electrically connected to the input of the trunk receiver 3, and the output of the differential voltage divider 2 is electrically connected to the input of the main receiver 5. The output of the main receiver 3 is electrically connected to the input of the optocoupler isolation 4, and the output of the main receiver 5 is electrically connected to the input of the optocoupler ki 8. The optocoupler isolation output 4 is electrically connected to the INTO interrupt input of the microcontroller 9 and electrically connected to the input of the output pulse generator 13 from the sensor connected to Input The output of the output pulse generator 13 is electrically connected to the OUTPUT1 connector, and electrically connected to the indication of the passage of the start pulse (Light-emitting diode). Measuring instruments (trigger input) can be connected to the OUTPUT1 connector: oscilloscope with memory, frequency counter, etc. Exit

W) bm

optocoupler isolation 8 is electrically connected to the interrupt input INT1 of the microcontroller 9 and electrically connected to the input of the output driver of the stop pulse 11 from the sensor connected to Input 2. The output of the output generator of the stop pulse 11 is electrically connected to the OUTPUT2 connector, and is electrically connected to the indication of the passage of the stop pulse (LED). Measuring instruments (input stop) can be connected to the OUTPUT2 connector: oscilloscope with memory, frequency counter, etc. The output of the crystal oscillator 16 is electrically connected to the frequency input of the microcontroller 9. The output of the microcontroller 9 is electrically connected to the display unit 14. The RESET button 12 is electrically connected to the reset input of the microcontroller 9, with the reset input of the output pulse shaper

stop 11, and with the reset input of the driver of the output pulse of triggering 13. The toggle switch for measuring ranges 10 is electrically connected to the input of the microcontroller 9. The power source 15 is electrically connected to the crystal oscillator 16, with the microcontroller 9, the indicating unit 14, the pulse shaping signal of the trigger 13, stop 11 and with an indication of the passage of pulses start, stop (LEDs). The power source 6 is electrically connected to the differential voltage divider 1, with the main receiver 3 and the optocoupler isolation 4. The power source 7 is electrically connected to the differential voltage divider 2, with the main receiver 5 and the optocoupler isolation 8.

The technical result achieved by using the claimed utility model consists of:

to increase the reliability of measuring the time intervals of the operation of pyrotechnic products;

the ability to work with all of the above sensors and to monitor the resistance value of the sensor with measuring circuits.

The relative position of the elements of the time interval meter and the presence of the above relationships between the elements affects the achievement of a technical result.

The presence of differential dividers 1 and 2 at the inputs allows the use of sensors without additional refinement, monitoring the resistance of connected sensors with measuring circuits, which helps to avoid errors when measuring time intervals with faulty measuring lines and sensors.

The use of trunk receivers can increase noise immunity when receiving a signal from a long measuring line.

The presence of optocoupler isolation allows you to decouple the sensors and input signal processing units between each other and from the measurement unit (mythocontroller, crystal oscillator), indicators and output pulse shapers with LEDs. This increases the noise immunity of the device from interference on earth tires.

The presence of three power supplies that are not galvanically connected to each other allows eliminating the galvanic connection of power and increasing the noise immunity of the device along the power supply circuits.

The device can be represented in three blocks:

1. a processing unit for the correspondence of the measuring lines and the sensor to the required range and generation of the INTO trigger signal for the time interval measurement circuit;

2. a processing unit for matching the measuring lines and the sensor to the required range and generating a stop signal INT1 of the time interval measurement circuit;

3. block of measurement, indication of the time interval and output pulse shapers with LEDs.

It should be noted that each of these units has its own power supply, which are not galvanically connected to each other, which increases the noise immunity of the power supply circuits.

The principle of operation of the time interval meter is as follows.

The digital time interval recorder is an automatic electronic time interval meter with noise-protected inputs INPUT1) and INPUT2, designed to work with sensors of various types with a measuring line length of up to 15 meters. The device allows you to measure time intervals in the range from 1 μs to 99.999 s.

As sensors for starting and stopping the countdown of time intervals, sensors with an internal resistance of up to 50 Ohms can be used, including:

-indicators of pressure pulses with an electromagnetic transducer (such as acoustic willow. from 1V. to 5V);

-ionization (higher. from 1V. to 5V);

-other low-impedance voltage pulse shapers with an amplitude of 1V. up to 5V.

The value of the time intervals are displayed on a digital five-digit display. The symbols are also displayed on the board:

-willingness to work - everything

- violation of contact or excess of the sensor resistance with measuring circuits higher

500m - all "b;

- overflow of the counter of an interval of time - all "LJ.

The LEDs for passing the start pulse (OUTPUT1) and stop (OUTPUT2) light up when the sensors at INPUT1 and INPUT2 are triggered. OUTPUT1 and OUTPUT2 is used to connect control devices during metrological verification of the device.

The utility model is illustrated by an example of candy execution.

In this case, the operation of the time interval meter is described by the example of testing a detonating cord for the mining industry. On a detonating cord, at a certain distance from each other, two discontinuous sensors are mounted, which are usually two metal wires.

The sensors are connected to measuring lines, the length of which can be several meters. The sensor that will be broken first when it reaches the shock wave is connected to INPUT1, the second sensor to INPUT2. In this example, the response time of the detonating cord segment is in the range of 10 to 20 microseconds. The toggle switch sets the measuring ranges of time intervals 10 is set to the position corresponding to the desired measurement range. In this example, this is ms./sec. (1 - 99.999 μs).

After pressing the RESET button, the microcontroller 9 monitors the integrity of the sensor circuits:

- if the resistance of the measuring lines and sensors does not exceed 50 Ohms on the digital display 14 “Oh, the LEDs for the passage of the start pulse (OUTPUT1) and stop (OUTPUT2) do not light, and on the OUTPUT1 and OUTPUT2 the logical voltage is set to“ 1 (2.4-4-4 5B), while

the microcontroller reads the position of the toggle switch 10 and sets the internal counter for a given range of time interval;

- if the resistance of the measuring lines and sensors exceeds 50 Ohms on a digital display 14

the symbols “L” are displayed, the LEDs for the passage of the start pulse 13 (OUTPUT1) and stop 11 (OUTPUT2) are on, and a logical “O (0-0.4V) voltage is set at OUTPUT1 and OUTPUT2.

When the sensor is triggered at INPUT 1, the main receiver 3 and the optocoupler isolation 4 generate a start pulse at the INTO interrupt input of the microcontroller 9. The microcontroller 9 starts the internal counter, to which the pulses come from the crystal oscillator 16. On the digital display 14 in the left-most digit “Oh, which signals the process of measuring the time interval. The LED of the passage of the start pulse 13 lights up and at the OUTPUT, a voltage drop from 2.4 V to 0.4 V is formed, which can be used to start the control device.

When the sensor is triggered at INPUT2, the main receiver 5 and the optocoupler isolation 8 generate a stop pulse at the interrupt input INT1 of the microcontroller 9. The mythocontroller 9 stops the internal counter, reads information from it, processes and displays on the digital display 14. The LED for passing the stop pulse 11 lights up and at OUTPUT2 a voltage drop from 2.4 V to 0.4 V is formed, which can be used to stop the control device.

If the sensor connected to INPUT 2 does not work within 1 - 99.999 microseconds. or 1ms. - 99.999s. (determined by the position of the toggle switch) on the digital display 14 symbols cLJ are displayed, which means the counter is overflowed. The LED for the passage of the stop pulse 11 does not light up, and a voltage drop is not formed at OUTPUT2.

Thus, as can be seen from the presented example, the claimed utility model, when used, allows to achieve the previously indicated technical result.

Currently, according to the proposed technical solution, several instances of the time interval meter have been manufactured, which have been tested at test stations of plants producing pyrotechnic products for the mining industry. The data was highly appreciated for their technical characteristics when working with this type of product.

Claims (1)

A time interval meter, characterized in that it contains two input differential dividers, two trunk receivers, two optocouplers, three autonomous power supplies, a crystal oscillator, a microcontroller, an indication unit, two output pulse shapers with LEDs, while the output of the first differential divider is electrically connected with the input of the first trunk receiver, the output of the first trunk receiver is electrically connected to the input of the first optocoupler isolation, the output of the first optocoupler the language is electrically connected to the INTO interrupt input of the microcontroller and the input of the output output pulse shaper with an LED, the output of the second differential voltage divider is electrically connected to the input of the second main receiver, the output of the second main receiver is electrically connected to the input of the second optocoupler, the output of the second optocoupler is electrically connected to the input interrupt INT1 of the microcontroller and the input of the driver of the output stop pulse with the LED, the input of the microcontroller is electric it is connected to the toggle switch for setting the measuring ranges, and the input of the microcontroller's reference frequency is electrically connected to the output of the crystal oscillator, the output of the microcontroller is electrically connected to the input of the display unit, while the RESET button is electrically connected to the reset input of the microcontroller, to the reset input of the output pulse generator of the trigger with an LED and with a reset input of the output stop pulse shaper with an LED, and the autonomous power supply from the first source is connected to the first differential divider , to the first main receiver, to the first optocoupler isolation, the autonomous power supply from the second source is connected to the second differential divider, to the second main receiver, to the second optocoupler isolation, and the autonomous power from the third source is connected to the crystal oscillator, to the microcontroller, to the display unit, as well as to the driver of the output pulse of the start with the LED and to the driver of the output pulse of the stop with the LED.