RU2308007C1 - Device for measuring noise and vibration - Google Patents

Abstract

FIELD: measuring technique.

SUBSTANCE: device comprises measuring phone, unit of amplifiers, unit of filters, power detector, indication unit, control unit provided with the switches and indicators of the level of measured values of noise and vibration, and power source.

EFFECT: enhanced precision.

5 cl, 1 dwg

Description

The invention relates to instrumentation, and in particular to acoustics, in particular to electrodynamic transducers for measuring sound signals and vibration.

The well-known “Noise and vibration meter VShV-003” (passport 5F2.745.009 PS), which contains a measuring microphone, amplifier, octave filters, voltage converter, indicating device, switch and power source. During operation, the selection of all operating modes of the "Noise and Vibration Meter VSHV-003" is carried out manually.

The main disadvantage of the VSHV-003 Noise and Vibration Meter is that the choice of the noise and vibration level measuring range requires the participation of the operator for its visual assessment and manual switching, which does not allow the device to be used in automatic data collection and processing systems for estimating noise levels and vibrations.

Also known is the "Accurate Pulse Sound Level Meter 00 023" (VEB ROBOTRON-MESSELEKTRONIK> OTTO SCHÖN <DRESDEN), the resolution for the measuring means according to ASMW-VM 646 is given under registration number 8.2./367, which is accepted as the closest analogue. "Accurate pulse sound level meter 00 023" contains a measuring microphone, a voltage divider with manual switching, an amplifier block, a filter block with manual selection of the measuring range, a power detector, an indication unit, a control unit with switches and a measured value indicator, a power supply.

In the process of measuring noise and vibration levels, all operations related to the selection of the total gain of the “Accurate pulse sound level meter 00 023”, the frequency range of measurements, as well as the adjustment of the amplification factors of the accurate pulse sound level meter according to the measured value, are performed manually.

The main disadvantage of the "Accurate pulse sound level meter 00 023" is that the choice of the measurement range of the noise and vibration level requires the participation of the operator for its visual assessment and manual switching, which does not allow the device to be used in automatic data collection and processing systems for assessing noise and vibration levels.

The invention is tasked with automating the collection and processing of information about noise and vibration levels.

The problem is solved due to the fact that in the noise and vibration meter, including a measuring microphone, amplifier unit, filter unit, power detector unit, display unit, control unit with switches and an indication of the value of the measured noise and vibration levels, as well as a power supply unit Indication is made in the form of interconnected voltage converter, microcomputer, timer, random access memory and communication means of the noise and vibration meter with an external computer, amplifier block, filter block, power detector block and equipped with registers and connected to the microcomputer of the display unit, while the power detector unit contains a range controller, and the control unit is equipped with a keyboard controller.

An indicator of the magnitude of the measured noise and vibration levels can be made digital.

The indicator of the measured noise and vibration levels can be made in the form of an LED matrix.

The voltage converter can be made in the form of a voltage to frequency converter.

The voltage converter can be made in the form of an analog-to-digital converter.

The measuring microphone can be equipped with a preamplifier.

The invention allowed to obtain a technical result, namely: the ability to automatically reconfigure the range of measurement of noise and vibration levels according to the level of the input sound signal, the ability to automatically switch the frequency reduction of the device, which allows you to automate the collection, processing of information to assess the noise level, for example, when attesting a workstation by security setting.

The drawing shows a structural diagram of the invention.

The structure of the structural scheme of the invention includes: a measuring microphone 1, a block of 2 amplifiers, a block of 3 filters, a block 4 of a power detector, a block 5 of an indication, a block of 6 controls, a block of 7 power.

The amplifier unit 2 consists of several series-connected amplifiers 8 and is equipped with a register (RG) 9 for automatic switching of the gain.

Block 3 filters includes a set of filters A 10, C 11, Lin 12, Inf 13, Oktav 14 and the output buffer stage 15 connected to the output 16 of the key 17. Block 3 of the filters is provided with a register 18.

The power detector unit 4 consists of a signal power detector 19 and a range detector 20. The signal power detector 19 consists of an input attenuator 21, a quadrator 22, a peak detector 23, an OR circuit 24, a buffer stage 25, switchable temporary reduction filters 26, an output multiplexer 27, an output buffer stage 28. The signal power detector 19 and the range detector 20 are controlled by register 29. The range detector 20 consists of a peak detector 30, an effective value detector 31, two comparators 32 and 33, an OR-NOT 34 circuit.

The display unit 5 is made in the form of a control microcomputer 35, a voltage-frequency converter 36, a non-volatile random access memory 37 (hereinafter - RAM 37), a timer-calendar 38, a communication device for the noise and vibration meter with an external computer via the controller 39.

The voltage converter 36 is designed as a voltage to frequency converter.

The voltage converter 36, as one example of a solution, can be made in the form of an analog-to-digital converter.

The control unit 6 includes groups of keys: a group of keys 40 for selecting an octave band, a group of keys 41 for a temporary cast (keys Slow, Fast, Imp), a group of keys 42 for a frequency cast (keys A, C, Lin), a group of keys 43 for selecting a mode ( keys Izm, Stop, Zap, Manual / Auto). The control unit 6 also contains a pointer 44 of the measured noise and vibration levels, made digitally in the form of a liquid crystal (hereinafter LCD) display, and includes a keyboard controller 45 for controlling the process of reading the state of the keys and displaying information on the LCD display. The control unit 6 is connected to the controller module 45 of the keyboard via a serial interface.

The pointer 44 of the measured noise and vibration levels, as one example of a solution, can be made in the form of an LED matrix.

The power supply unit 7 is an adapter for the mains voltage and the battery voltage to the required values of the power supply voltage of the device and has the modes +15, -15, +5, Dgr, Agr.

The measuring microphone 1 is equipped with a preamplifier 46.

The operation of the noise and vibration meter, an example of which is shown in the drawing, is as follows.

In the amplifier block 2, the microphone signal is amplified, which, depending on the level of the measured noise, can vary from 10 μV to 10 V. The gain in the amplifier block 2 can be varied in steps in accordance with the specified gain code. The gain values vary between 1-10 ⁵ . The gain value is switched automatically. The digital gain code is set in register 9, via data bus 46. The gain code is generated in the microcomputer 35, based on the level of the measured signal. The gain is switched in steps of 20 dB. The step size is selected taking into account the peak factor of the signal, which was taken equal to 3.3, which corresponds to white noise, and also taking into account the minimum and maximum values of the device. The range of measurements of noise and vibration levels is 5 steps and is 100 dB. Upon detection of the fact that the measured signal goes beyond the set measurement range, a new measurement range is searched in accordance with the following algorithm: in the case of a weak signal, the gain increases by one step, in case of overload, the gain decreases by one step. If in this case the signal also falls outside the range, the gain stage is searched by sequentially sorting the bits of the gain code (similar to the method of bitwise balancing).

Block 3 filters filters the output signal of block 2 amplifiers in accordance with the selected frequency response A 10, C 11, Lin 12, Inf 13, Oktav 14. The choice of filtering mode is carried out by switching one of the filters to the output buffer stage 15 using an electronic key 17, controlled by a code stored in register 18. The central frequency of the octave filter 14 is set by the code of the register 18 and can correspond to the frequency characteristics of A 10, C 11, Lin 12, Inf 13, Oktav 14. The central frequency of the octave filter 14 can take values 16, 31.5, 63, 125, 250, 500, 1000, 2000, 4000, 8000, 12500 Hz. The octave filter 14 is controlled by electronic switches located in it, which switch reactivity, which determine the center frequency of tuning the octave filter 14 to any of the above frequencies. The output signal of the filter unit 3 is fed to the power detector unit 4. The schematic diagram of the filters was developed in accordance with existing standards and corresponds to the first class of accuracy.

The power detector unit 4 operates as follows:

Range detector 20 generates signals INT (interrupt), Low (small signal), High (overload). These signals are supplied to the display unit 5. They signal the output of the signal taken from the unit 2 of the amplifiers beyond the measurement limits and indicate either an overload of the amplifier (High) or a small signal (Low). The INT signal is obtained as a function of OR NOT 34 of these signals and has an active low level. The output signal of the amplifier unit 2 is supplied to the peak detector 30 and to the detector 31 of the effective value. The output voltage of the effective value detector 31 is supplied to a comparator 32, where it is compared with a reference value. If the output voltage of the detector 31 of the effective value becomes less than the reference (0.5 V), the output of the comparator 32 is set to log.1 (signal Low). The comparator 32 has a hysteresis (0.2 V), when the comparator 32 is triggered, the threshold rises. The Low signal is fed to one of the inputs of the OR-NOT 34 circuit, which generates an INT signal. The signals Low and INT also come to the display unit 5, to report the need for tuning the amplification of the unit 2 amplifiers in a larger direction (to the next stage of amplification). If the signal becomes excessively large, a High signal is generated. The output voltage of the peak detector 30 is supplied to another comparator 33, where a comparison is made with the reference voltage (10 V). In the event of an overload, the voltage of the peak detector 30 exceeds the reference value; at the output of the comparator 33, the log level is set. This signal (High) is fed to the input of the second OR-NOT 34 circuit and also leads to the formation of the INT signal. The High signal is sent to the display unit 5 together with the INT signal, indicating the need for tuning the amplification of the unit 2 amplifiers in a smaller direction (to the previous gain stage). Similarly, the comparator 33 has a hysteresis (2 V) necessary for the stable determination of overload. When the comparator 33 is triggered, the threshold decreases. The peak detector 30 and the effective value detector 31 are reset by a common output line (range change - RST) of the register 29, the state of which is changed by the indication unit 5 at the time of amplification tuning of the amplifier unit 2.

The input signal of the signal power detector 19 is the output signal of the filter unit 3. This signal is fed to the input attenuator 21, which provides the values of the amplification factors K = 1 and K = 10. These gains are controlled by register 29. The output signal of the attenuator 21 is fed to the input of a quadrator 22, the output of which is a signal proportional to the instantaneous power of the measured noise. The output signal of the quadrator 22 is supplied to the peak detector 23 and to the filters 26 temporary reduction. The peak detector 23 provides a rise time constant of 0.1 s. The output voltage of the peak detector 23 is supplied to the output multiplexer 27. At the other input of the output multiplexer 27, voltage is supplied from the temporary reduction filters 26. Temporary cast filters 26 are an RC filter with a switchable resistor. Switching is performed using the line "mode" (Slow / Fast) register 29. The time constant, thus, can be 0.5 s or 1 s, which corresponds to the time characteristics of Fast and Slow, respectively. Filters 26 temporary reduction contain a buffer stage 25, eliminating the influence of subsequent circuits on the operation of block 4 of the power detector. The signals of the peak detector 23 and the temporary reduction filters 26 are supplied to the two inputs of the output multiplexer 27. The output multiplexer 27 provides a choice between the signal of the peak detector 23 and the signals of the temporary reduction filters 26, which is used to switch between the temporal characteristics of Imp and Slow / Fast. The output multiplexer 27 is controlled by the register 29. The signal of the output multiplexer 27 through the output buffer stage 28 enters the display unit 5. The peak detector 23 and the temporary reduction filters 26 are reset by the same signal as the peak detector 30 and the effective value detector 31 in the range detector 20, at the moments of switching between measurement ranges. The peak detector 23 is controlled by a signal obtained as a function of the operation of the OR circuit 24, which receives the signal RST and the ClearPik signal (reset of the peak detector 23). The ClearPik signal is taken from one of the output lines of the register 29. The ClearPik pulse is set by the indicating unit 5 when the Imp key of the key group 41 of the temporary reduction unit 6 is pressed.

The display unit 5 is used to automatically set the gain of the amplifiers, control the operation modes of other units in accordance with the set measurement mode, calculate and write measured values to the non-volatile memory (RAM 37), read the pressed keys from the control unit 6, and control the display of the measurement mode and values measured values on the pointer 44 the values of the measured noise and vibration levels. The input signal taken from the power detector unit 4 is supplied to the voltage-frequency converter 36 (hereinafter referred to as the IFF 36). In the microcomputer 35, the number of pulses generated by the IFF 36 in 0.1 s is determined. The results of ten frequency measurements are averaged, and the obtained value is converted into the sound pressure (sound) level. Automatic setting of the measuring range is carried out using signals "overload" - "small signal" generated by block 4 of the power detector. In this case, a gain value of the amplifier unit 2 is selected such that both signals are in an inactive state. Non-volatile random access memory 37 and a timer-calendar 38 allow you to save data about the measured values with reference to the time and date of measurement. The controller 39 of the serial port allows the exchange of data with an external computer and allows you to work under the control of IBM PC.

The control unit 6 carries out data exchange via a serial interface, controls the display of data on an intelligent LCD display, and also periodically polls the keyboard of the control unit 6 through the keyboard controller 45. When a key of any group of keys is pressed, a request signal is generated to the display unit 5 and the code of the pressed key is transmitted to it. The front panel has twenty-eight keys. Various groups of keys that control the time, frequency characteristics of the noise and vibration meter, operation modes (automatic measurements, manual control, calibration, etc.) are located in accordance with their functional purpose and ergonomic requirements.

The power supply unit 7 provides the necessary voltage to all the units of the noise and vibration meter.

The invention allowed to obtain a technical result, namely: to automate the collection and processing of information about noise and vibration levels.

The technical result obtained allows to exclude constant operator participation for visual assessment and manual switching of the choice of the measurement range of noise and vibration levels and allows the device to be used in automatic data collection and processing systems for assessing noise and vibration levels, for example, when certifying a workplace according to safety parameters of level exposure noise and vibration.

Claims (6)

1. The noise and vibration meter, including a measuring microphone, amplifier unit, filter unit, power detector unit, display unit, control unit with switches and an indication of the measured noise and vibration levels and a power supply unit, characterized in that the display unit is made in the form of interconnected voltage converter, microcomputer, timer, random access memory and communication means of the noise and vibration meter with an external computer, amplifier block, filter block, power detector block are equipped with registers and are connected with a microcomputer display unit, while the power detector unit contains a range controller, and the control unit is equipped with a keyboard controller. 2. The meter according to claim 1, characterized in that the indicator of the measured noise and vibration levels is digital. 3. The meter according to claim 1, characterized in that the indicator of the measured noise and vibration levels is made in the form of an LED matrix. 4. The meter according to claim 1, characterized in that the voltage Converter is made in the form of a voltage to frequency Converter. 5. The meter according to claim 1, characterized in that the voltage Converter is made in the form of an analog-to-digital Converter. 6. The meter according to claim 1, characterized in that the measuring microphone is equipped with a preamplifier.