CN212645857U - Ultrasonic transducer dynamic performance testing device - Google Patents

Abstract

The utility model discloses an ultrasonic transducer dynamic behavior testing arrangement. The whole waveform of echo signal is analyzed to transducer dynamic behavior test at present, and the cost is higher and have a large amount of redundant data, the lower problem of whole efficiency of software testing. The utility model discloses an airtight pipeline, ultrasonic transducer A, ultrasonic transducer B, switch receiving element, leading difference amplification unit, band-pass filter unit, comparing element, time measuring unit, gain control unit, peak hold unit, echo signal sampling unit. The utility model discloses an inside gas that fills into different components, temperature and pressure of test container simulates ultrasonic transducer's operational environment, and sampling ultrasonic transducer echo characteristic signal, measurement echo arrival time and the current device in operating temperature, pressure isoparametric obtain the dynamic behavior of transducer, realize comprehensive performance test under the different operating modes of transducer.

Description

Ultrasonic transducer dynamic performance testing device

Technical Field

The utility model belongs to ultrasonic transducer detection area relates to an ultrasonic transducer dynamic behavior testing arrangement.

Background

The ultrasonic flow meter generally adopts a time difference method to measure flow, namely, two ultrasonic transducers at the upstream and the downstream respectively transmit ultrasonic signals, and the arrival time of the ultrasonic signals received by the other transducer is measured. Ultrasonic transducers are important sensing components in ultrasonic flow meters, and the performance of the ultrasonic transducers affects the measurement accuracy of the flow meters. Currently, research on the dynamic performance of the ultrasonic transducer focuses on sensitivity and consistency of echo signals, the method compares dynamic performance differences of the ultrasonic transducer by comparing the overall waveform similarity of the echo signals, and the requirements on sampling frequency and calculation cost are high.

Disclosure of Invention

The utility model discloses to prior art's is not enough, has provided a gaseous ultrasonic transducer dynamic behavior testing arrangement, and the device simulates gaseous ultrasonic transducer's different operating mode environment and tests its dynamic behavior, has reduced the sampling data, has reduced hardware cost and transducer dynamic behavior analysis's calculation complexity, has improved gaseous ultrasonic transducer dynamic behavior test efficiency.

The utility model discloses an airtight pipeline, ultrasonic transducer A, ultrasonic transducer B, analog switch, leading difference amplification unit, band-pass filter unit, comparing unit, drive unit, time measuring unit, gain control unit, peak hold unit, echo signal sampling unit, pressure detection unit, temperature detecting element, 485 communication unit and host computer.

Ultrasonic transducer A, transducer B symmetry are installed on airtight pipeline, and pipeline one side can ventilate and can increase the pipeline internal gas pressure, and the opposite side can realize gaseous the release through valve control.

The input end of the ultrasonic transducer A is connected with the input end of a first channel of the analog switch; the input end of the energy converter B is connected with the input end of the second channel of the analog switch; the output end of the analog switch is connected with the input end of the preposed differential amplification unit.

The output end of the preposed differential amplifying unit is connected with the negative input end of the band-pass filtering unit, and the positive input end of the band-pass filtering unit is a reference voltage of 1.5V; the output end of the band-pass filtering unit is connected with the negative input end of the gain control unit, and the positive input end of the gain control unit is a 1.5V reference voltage; the output end of the gain control unit is connected with the positive input end of the comparison unit; the negative input end of the comparison unit is connected with the threshold signal; the output end of the comparison unit is connected with the timing stop pin of the time detection unit.

The input end of the peak value holding unit is connected with the output end of the gain control unit; the output end of the peak holding unit is connected with the analog input pin of the singlechip and the echo characteristic signal sampling circuit; the control end of the peak holding unit is connected with an I/O port of the singlechip.

The input end of the echo characteristic signal sampling unit is connected with the output end of the gain control unit; the output end of the echo characteristic signal sampling unit is connected with the serial input end of the single chip microcomputer.

The input end of the driving unit is connected with a pulse transmitting pin of the time detection unit; the output end of the driving unit is connected with the transducer.

The enabling pin, the data input pin and the data output pin of the time measuring unit are connected with the I/O port of the single chip microcomputer.

The output end of the temperature detection unit is connected with an I/O port of the singlechip; the output end of the pressure detection unit is connected with the I/O port of the singlechip.

The analog switch model selection chip MAX 4762; the instrumentation amplifier model selection chip AD 8226; the band-pass filtering unit is provided with a model selection chip OPA 837; the comparison unit is provided with a model selection chip OPA 837; the peak holding unit is provided with a model selection chip MAX998 EUT; the echo characteristic signal sampling circuit model selection chips are EPM240T100C5, AD9237 and CY7C1021DV 33; the time measurement unit chip is selected to be TDC-GP 22; the model selection chip of the single chip microcomputer is MSP430F 449.

The utility model discloses a test principle: the arrival time and the frequency of the echo signal are obtained through a time measuring circuit, the time of an echo characteristic signal sampling window is determined in a self-adaptive mode, the characteristic signal sampling is started before the echo arrives, the sampling is stopped after the time measuring unit chip GP22 receives the STOP signal and the receiving of the echo signal is interrupted, and on the premise that the complete echo characteristic signal is obtained, unnecessary sampling is reduced and the crosstalk of noise signals is avoided; the gain control circuit can adjust the peak-to-peak voltage of the echo signal to reach a target value and determine the gain of the echo signal by the resistance value of the digital potentiometer. And step voltage of the echo characteristic signal can be obtained by the echo characteristic signal sampling value. Echo signal gain, frequency and characteristic signal step voltage are realized through 485 communication. The utility model discloses with echo signal gain, frequency and echo characteristic signal step voltage reduced the calculated amount under the prerequisite that dynamic behavior difference is compared between the realization transducer, bring huge facility for transducer dynamic behavior analysis and uniformity evaluation.

The utility model has the advantages that: the utility model can simulate the working condition environments of the gas ultrasonic transducer such as different temperatures, pressures, gas components and the like, and measure the dynamic performance of the gas ultrasonic transducer in different working condition environments; the method can adaptively determine the window time for starting the sampling of the echo characteristic signal by accurately measuring the arrival time of the echo signal, ensure that the sampling circuit of the echo characteristic signal starts the sampling of the signal before the arrival of the echo signal, reduce unnecessary sampling data on the premise of ensuring that the sampling obtains a complete echo characteristic signal, and avoid the influence of noise crosstalk on the analysis of the dynamic performance of the transducer; the echo signal frequency and the echo characteristic signal step voltage are extracted to be used as echo signal characteristics, and the echo signal frequency and the echo characteristic signal step voltage are used as dynamic performance indexes of the transducer together with the echo signal gain value, so that the difference of the dynamic performances of different transducers can be compared efficiently and visually.

Drawings

FIG. 1 is a schematic diagram of an apparatus for testing dynamic performance of an ultrasonic transducer;

FIG. 2 is a schematic block diagram of a dynamic performance testing system for an ultrasonic transducer;

FIG. 3 is an echo signal and an echo signature signal;

FIG. 4 is a single chip unit and an LCD display unit;

FIG. 5 illustrates an analog switch switching circuit and a driving circuit;

FIG. 6 is a pre-amplifier circuit and a band-pass filter circuit;

FIG. 7 is a gain control circuit;

FIG. 8 is a peak hold and threshold compare circuit;

FIG. 9 is a time measurement circuit;

fig. 10 is an echo characteristic signal sampling circuit unit.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

Referring to fig. 1, a measured transducer and a standard transducer are installed in a closed pipeline in a facing mode, the length of the pipeline is 80mm, the diameter of the pipeline is 30mm, air is arranged inside the pipeline, a flange and a valve are installed at the front end and the rear end of the pipeline respectively, pressurization can be achieved, and pins T + and T-corresponding to the ultrasonic transducer to be measured and the standard ultrasonic transducer are connected into a circuit.

Referring to fig. 2, the work flow of the whole system is as follows: the time measuring circuit generates a pulse Signal, the voltage T + and the voltage T-are generated after the boost excitation, the transducer is driven, and the original echo signals Signal + and Signal-are received by the opposite transducer. The two transducers are alternately used for transmitting and receiving through an analog switch chip. The signals of Signal + and Signal-are output as V2 through a gain control circuit after being subjected to pre-amplification and band-pass filtering to output a Signal V1, V1. On one hand, the V2 obtains an echo characteristic signal V3 through a peak value holding circuit, the V3 is read through an internal AD of the singlechip, and the gain value of a gain control circuit is fed back and adjusted, so that the peak value of the V2 is controlled at a set value; on one hand, V2 obtains the arrival time t1, t2 and t3 of the echo signal after passing through a time measuring circuit; on the other hand, the signal sampling circuit is opened before the echo arrives, the CPLD controls the AD chip to sample the echo characteristic signal V3 signal, the sampling data is temporarily stored in the hardware storage circuit, and the sampling data is transmitted to the single chip microcomputer MSP430 through the serial port after the sampling is finished. The single chip microcomputer obtains echo signal frequency from echo arrival time t1, t2 and t3, step voltage of the single chip microcomputer can be obtained from echo characteristic signal sampling data, and finally the single chip microcomputer transmits the echo signal frequency, a gain value and characteristic signal step voltage data to an upper computer through RS 485.

Referring to fig. 3, the echo signal is subjected to peak holding by a peak holding circuit to hold the peak voltage of the echo signal, and finally a characteristic signal of the echo signal is obtained, wherein the characteristic signal represents each peak voltage of the echo signal and reflects the voltage change condition of the rising edge part of the echo signal.

Referring to fig. 4, the single chip microcomputer unit adopts MSP430F449, and the LCD display unit adopts a customized liquid crystal display. Pins 1, 60 and 100 of the single chip microcomputer are connected with 3V, and pins 10, 11, 56, 61, 98 and 99 are grounded. The frequency of the crystal oscillator Y1 is 4MHz, the 88 th pin of the singlechip is connected with one end of a capacitor C1 and one end of a crystal oscillator Y1, and the 89 th pin is connected with the other end of the crystal oscillator Y1 and one end of a capacitor C2; the other end of the capacitor C1 and the other end of the capacitor C2 are commonly grounded; the frequency of the crystal oscillator Y2 is 32.768KHz, the 8 th pin of the singlechip is connected with one ends of a capacitor C3 and a crystal oscillator Y2, and the 9 th pin of the singlechip is connected with the other end of the crystal oscillator Y2 and one end of a capacitor C4; the other end of the capacitor C3 and the other end of the capacitor C4 are commonly grounded; the positive electrode of the electrolytic capacitor C5 and one end of the capacitor C6 are connected with 3V, and the negative electrode of the electrolytic capacitor C5 and the other end of the capacitor C6 are grounded. The 95 th pin of the single chip microcomputer is connected with a V3 port; the 79 th pin of the single chip microcomputer is connected with the EN1 port, the 78 th pin of the single chip microcomputer is connected with the EN2 port, and the 77 th pin of the single chip microcomputer is connected with the EN _ R port. The 90 th, 91 th, 92 th, 93 th, 76 th and 87 th pins of the single chip microcomputer are respectively connected with CS1, SCK1, SI1, SO1, RSTN1 and INTN1 ports of SPI (1) communication. The 80 th, 81 th and 82 th pins of the single chip microcomputer are respectively connected with CS2, SCK2 and SI2 ports of SPI (2) communication. The 75 th, 73 th and 72 th pins of the singlechip are respectively connected with RXD2, C _ RST and C _ READ ports of the CPLD. The 62 th, 63 th and 64 th pins of the singlechip are respectively connected with an RS485 communication circuit. The 83 th and 84 th pins of the single chip are connected with a temperature detection circuit. The 85 th and 86 th pins of the singlechip are connected with a pressure detection circuit. The 64 th pin of the singlechip is connected with DE and RE pins of the RS485 communication chip. The 12 th to 35 th pins of the single chip microcomputer are respectively connected with the 1 st to 24 th pins of the LCD, and the 52 th to 55 th pins of the single chip microcomputer are respectively connected with the 25 th to 28 th pins of the LCD. One end of the resistor R1 is grounded, the other end of the resistor R1 is connected with the 57 pin of the single chip microcomputer and one end of the resistor R2, the other end of the resistor R2 is connected with the 58 pin of the single chip microcomputer and one end of the resistor R3, and the other end of the resistor R3 is connected with the 59 pin of the single chip microcomputer.

Referring to fig. 5, the voltage is boosted to 20V through the DC/DC circuit, the transducer driving adopts a push-pull driving mode, the pulse signal is generated by the Fire signal generated by TDC-GP22, the pulse frequency and number can be adjusted as required, the pulse signal passes through the analog switch switching circuit and drives the pulse transformer to work through the control switch tube to drive the corresponding transducer, and the secondary side of the transformer is connected in parallel with the transducer. The damping resistor and the matching capacitor are connected in series to the circuit to condition the excitation signal. The waveform of the excitation signal can be adjusted by adjusting the magnitude of the capacitance value to ensure that the excitation signal is approximate to a sinusoidal excitation signal.

During the measurement, the transducers are alternately used for transmitting and receiving by controlling the time sequence of the analog switch switching circuit. The analog switch selects MAX4762 chips. Where EN1 transmits a switch control signal for the corresponding transducer. While transducer a is transmitting, the raw echo signal of transducer B is received. Setting the corresponding switch control Signal EN1 to be at a high level, connecting COM1 with NC1, connecting COM2 with NC2, connecting COM3 with NC3, connecting COM4 with NC4, enabling Fire to enter a driving circuit corresponding to the transducer A, and receiving original echo signals of a Signal + and a Signal-receiving transducer B; similarly, when the transducer B transmits, the original echo signal of the transducer A is received. The corresponding switch control Signal EN1 is set to be low level, COM1 is connected with NO1, COM2 is connected with NO2, COM3 is connected with NO3, COM4 is connected with NO4, Fire enters a driving circuit corresponding to the transducer B, and Signal + and Signal-receive the original echo signals of the transducer A.

Referring to fig. 6, the front differential amplifier circuit adopts an instrumentation amplifier AD620, and the band-pass filter circuit adopts a rail-to-rail low-power-consumption high-speed operational amplifier OPA 837. A1 pin and an 8 pin of the AD620 are connected with a resistor R14, a 4 pin is grounded, a 5 pin is connected with 1.5V, a 6 pin is connected with a V1 port, and a 7 pin is simultaneously connected with 3V.

The band-pass filter circuit designs the center frequency according to the resonance frequency range of the actual transducer. The 2 pin of the OPA837 is grounded, the 3 pin is connected with 1.5V, the 5 pin and the 6 pin are connected with 3V, the 1 pin is connected with one end of a capacitor C12, and the other end of the C12 is connected with a V1 port; one end of the resistor R14 is grounded, the other end of the resistor R14 is connected with one ends of the capacitors C9 and C12 and one end of the resistor R12, and the other ends of the capacitor C11 and the resistor R12 and the capacitor C10 are simultaneously connected with a pin 4 of the OPA 837; the other end of the capacitor C10 is connected with the R11, the C9 and the R13, and the other end of the R13 is grounded.

Referring to fig. 7, the amplifier of the gain control circuit also employs an OPA837 and the digital potentiometer employs MCP 41100. The gain of the circuit is in direct proportion to the resistance value of the digital potentiometer. The single chip microcomputer adjusts the digital potentiometer through the SPI communication interface, changes circuit gain and enables the amplitude of signals to reach a preset size. From this, the signal gain value is:

wherein R is_WBThe resistance value of the digital potentiometer which is used as a feedback resistor in the circuit to participate in gain control is specifically set by a digital quantity D set by a singlechip_nThe specific formula is as follows:

in the formula R_ABThe maximum resistance of the digital potentiometer selected according to the embodiment of the present invention is represented as 100k Ω. The 2 pin of OPA837 is grounded, the 3 pin is connected with 1.5V, the 5 pin and the 6 pin are connected with 3V, the 1 pin is respectively connected with the ports of a capacitor C13, a resistor R15 and a V2, the 4 pin is connected with a resistor R16, the other end of the capacitor C13, the 6 pin and the 7 pin of MCP41100, the other end of R16 is connected with a capacitor C14, the other end of C14 is connected with a port V1, the other end of R15 is connected with the 5 pin of MCP41100, the 8 pin of MCP41100 is connected with 3V, the 4 pin is grounded, the 3 pin is connected with an SI2 port, the 2 pin is connected with an SCK2 port.

Referring to fig. 8, the peak hold circuit employs two low power high speed comparators MAX998 EUT. When the circuit is not in the working state, the EN _ R port is controlled by the single chip microcomputer to close the comparator, so that the power consumption is reduced. When the input voltage rises when the circuit is in an operating state, the diode D1 is conducted; when lowered, diode D1 turns off. The capacitor holds the input voltage peak. After the detection is finished, the MOS transistor T1 is turned on to prevent the capacitor from discharging to influence the next detection. The threshold comparison circuit adopts a low-power-consumption high-speed comparator MAX998EUT, an input signal is compared with a fixed threshold voltage, and a comparison result is output to the time measurement circuit.

2 pins of MAX998EUT (1) are grounded, 3 pins are connected with a V2 port, 5 pins are connected with an EN _ R port, 6 pins are connected with 3V, 1 pin is connected with the anode of a diode D1, 4 pins are connected with one end of a resistor R17, and the other end of R17 is connected with a V3 port; 2 pins of MAX998EUT (2) are grounded, 5 pins are connected with an EN _ R port, 6 pins are connected with 3V, 1 pin and 4 pins are simultaneously connected with a V3 port, and 3 pins are connected with the negative electrode of a diode D1. The source electrode of the MOS transistor T1 is grounded, the grid electrode is connected with the EN2 port, the drain electrode is connected with one end of a resistor R18, the other end of the R18 is simultaneously connected with the pin 3 of the MAX998EUT (2) and one end of a capacitor C15, and the other end of the C15 is grounded; 2 pins of MAX998EUT (3) are grounded, 3 pins are connected with a V2 port, 5 pins are connected with an EN _ R port, 6 pins are connected with a 3V port and 1 pin is connected with an OUT port, 4 pins are connected with one ends of resistors R19 and R20, the other end of the resistor R19 is connected with the 3V port, and the other end of the resistor R20 is grounded.

Referring to fig. 9, the time measuring circuit outputs a trigger signal, receives the output signal of the threshold comparing circuit, obtains the arrival times t1, t2, t3 of the ultrasonic signals, and uploads the arrival times to the single chip microcomputer through the SPI bus. The arrival times t1, t2, and t3 respectively represent the arrival times of the 3 rd, 4 th, and 5 th periodic signals of the echo signal, and the frequency f of the echo signal can be obtained from the formula (1)

On the other hand, the time of arrival t1 can be adaptively adjusted to ensure that the starting time of the echo signal peak holding circuit and the characteristic signal sampling circuit is adjusted before the echo signal arrives, and the STOP1 pin of the TDC-GP21 is connected with one end of the capacitor C16; the pin STOP2 is connected with one end of a capacitor C17; the other end of the capacitor C16 and the other end of the capacitor C17 are connected with an OUT port in common; the Fire _ down pin is connected with one end of a diode D2; the Fire _ up pin is connected with one end of a diode D3; the other end of the diode D2 and the other end of the diode D3 are connected with a Fire port and one end of a resistor R21; the other end of the resistor R21 is grounded; the pin Xin is connected with one end of a capacitor C18, a resistor R22 and a crystal oscillator Y3; the Xout pin is connected with one end of the capacitor C19 and the other ends of the resistor R22 and the crystal oscillator Y3; the frequency of the crystal oscillator Y3 is 4 MHz; the other end of the capacitor C18 and the other end of the capacitor C19 are commonly grounded; the RSTN pin, the SO pin, the SI pin, the SCK pin, the SSN pin and the INTN pin of the chip are respectively connected with an RSTN1 port, an SO1 port, an SI1 port, an SCK1 port, a CS1 port and an INTN1 port of the SPI (1).

Referring to fig. 10, the single chip starts sampling of the CPLD echo characteristic signal before the arrival of the echo, and the CPLD samples the voltage at a high speed through the ADC and stores the voltage in the data storage chip. And after sampling is finished, the complete echo characteristic waveform is stored in the data storage chip, and the CPLD module reads data in the data storage chip and transmits the data to the single chip microcomputer. The peak step voltage of the echo signal can be easily obtained from the sampling data of the echo characteristic signal. The CPLD chip in the signal sampling circuit is selected to be EPM240T100C5, and the ADC sampling chip is selected to be AD 9237; the data storage chip is selected to be CY7C1021DV 33.

Pins 52-58, 61, 66-73 of the CPLD are respectively connected with pins A0-A15 of an address bus of the data storage chip; pins 74-78 and 81-87 of the CPLD are respectively connected with pins S0-S11 of a data bus of the data storage chip; pins 29, 30 and 33 of the CPLD are respectively connected with pins 6, 17 and 41 of the data storage chip; the 34 th pin of the CPLD is connected with the RXD2 port; the 35 th pin of the CPLD is connected with the C _ READ port; the 36 th port of the CPLD is connected with the C _ RST port; pins 3-8 and 15-20 of the CPLD are respectively connected with pins S0-S11 of the ADC chip; the 2 nd pin of the CPLD is connected with the CLK pin of the ADC chip; the 62 th pin of the CPLD is connected with a 50MHz active crystal oscillator to obtain an operating clock; a pin 29 of the high-speed ADC is connected with one end of a capacitor C21 and one end of a resistor R23; the pin 30 of the high-speed ADC is connected with the other end of the capacitor C21 and one end of the resistor R24; the other end of R24 is connected with 3V; the other end of the resistor R23 is connected with one end of the capacitor C20; the other end of the capacitor C20 is connected with one end V3 of the resistor R25; the other end of the resistor R25 is connected to ground.

The single chip microcomputer transmits the gain and the frequency of the echo signal and the step voltage of the echo characteristic signal through the RS485 signal, and the gain and the frequency and the step voltage of the echo characteristic signal are used as evaluation basis to realize the evaluation of the dynamic performance of the transducer.

The test principle of this embodiment is as follows: one end of the standard transducer is excited by the driving signal, the tested transducer receives the echo signal and generates an electric signal at one end, the echo signal is received by the control change-over switch, the signal is subjected to differential amplification to remove common-mode noise, and then the signal is subjected to band-pass filtering and gain control circuit to obtain a target echo signal. On one hand, the echo signal after filtering and amplification obtains echo signal characteristic signal voltage through a peak holding circuit and an echo characteristic signal sampling module, and on the other hand, the echo signal obtains echo signal arrival time and echo signal frequency after passing through a time measuring circuit. The echo signal is controlled by a peak hold and gain control circuit, the signal is held within a target voltage range and a gain value thereof is obtained. The method comprises the steps of adaptively determining the window opening time of echo characteristic signal sampling according to the arrival time of an echo signal, enabling a sampling circuit to open the echo characteristic signal sampling just before the echo arrives, stopping sampling after the echo signal arrives and generates an OUT signal, reducing unnecessary sampling and avoiding crosstalk of noise signals. When the echo characteristic signal sampling is completed, the sampling circuit sends the characteristic signal sampling data to the single chip microcomputer, and the voltage value of the echo characteristic signal can be obtained according to the sampling data. And finally, the singlechip transmits the gain, the frequency and the voltage of echo characteristic signals and the temperature and pressure data of the environment in the device to an upper computer through a 485 circuit. And the upper computer receives data and takes the gain value, the frequency and the voltage of the echo signal characteristic signal as evaluation basis to realize the comparison of the dynamic performance between the transducers.

To sum up, the utility model discloses an inside gas that fills into different components, temperature and pressure of test container simulates ultrasonic transducer's operational environment, and the dynamic property of transducer is obtained to operating temperature, pressure isoparametric in sampling ultrasonic transducer echo characteristic signal, measurement echo arrival time and the container, realizes comprehensive performance test under the different operating modes of transducer. The utility model discloses at first before echo signal reachs self-adaptation open sampling circuit sample echo characteristic signal, reduced the sampling frequency requirement on the basis of obtaining echo characteristic; and secondly, the signal gain value, the echo characteristic signal voltage and the frequency are used as indexes for comparing the dynamic performance difference of the transducer, so that the calculated amount is reduced on the basis of realizing the echo signal waveform characteristic analysis, and great convenience is brought to the dynamic performance analysis and consistency evaluation of the transducer.

Claims (5)

1. The utility model provides an ultrasonic transducer dynamic behavior testing arrangement, includes airtight pipeline, ultrasonic transducer A, ultrasonic transducer B, analog switch, leading difference amplification unit, band-pass filter unit, comparing element, drive unit, time measuring unit, gain control unit, peak hold unit, echo signal sampling unit, pressure detection unit, temperature detecting element, 485 communication unit and host computer, its characterized in that:

the ultrasonic transducers A and the ultrasonic transducers B are symmetrically arranged on the closed pipeline, one side of the pipeline can be ventilated and can increase the air pressure in the pipeline, and the other side of the pipeline can realize the release of the gas through the control of a valve;

the input end of the ultrasonic transducer A is connected with the input end of a first channel of the analog switch; the input end of the energy converter B is connected with the input end of the second channel of the analog switch; the output end of the analog switch is connected with the input end of the preposed differential amplification unit;

the output end of the preposed differential amplifying unit is connected with the negative input end of the band-pass filtering unit, and the positive input end of the band-pass filtering unit is a reference voltage of 1.5V; the output end of the band-pass filtering unit is connected with the negative input end of the gain control unit, and the positive input end of the gain control unit is a 1.5V reference voltage; the output end of the gain control unit is connected with the positive input end of the comparison unit; the negative input end of the comparison unit is connected with the threshold signal; the output end of the comparison unit is connected with a timing stop pin of the time detection unit;

the input end of the peak value holding unit is connected with the output end of the gain control unit; the output end of the peak holding unit is connected with the analog input pin of the singlechip and the echo characteristic signal sampling circuit; the control end of the peak holding unit is connected with an I/O port of the singlechip;

the input end of the echo characteristic signal sampling unit is connected with the output end of the gain control unit; the output end of the echo characteristic signal sampling unit is connected with the serial input end of the single chip microcomputer;

the input end of the driving unit is connected with a pulse transmitting pin of the time detection unit; the output end of the driving unit is connected with the transducer;

the enabling pin, the data input pin and the data output pin of the time measuring unit are connected with the I/O port of the singlechip;

the output end of the temperature detection unit is connected with an I/O port of the singlechip; the output end of the pressure detection unit is connected with the I/O port of the singlechip.

2. The device for testing the dynamic performance of the ultrasonic transducer according to claim 1, wherein: the preposed differential amplification unit adopts an instrument amplifier AD620, and the band-pass filtering unit adopts a rail-to-rail low-power-consumption high-speed operational amplifier OPA 837.

3. The device for testing the dynamic performance of the ultrasonic transducer according to claim 1, wherein: the gain control unit adopts a rail-to-rail low-power-consumption high-speed operational amplifier OPA837, the digital potentiometer adopts MCP41100, and the gain value is in a direct proportion relation with the resistance value of the digital potentiometer.

4. The device for testing the dynamic performance of the ultrasonic transducer according to claim 1, wherein: the echo signal sampling unit adopts two low-power-consumption high-speed comparators MAX998EUT, wherein the output end of one comparator is connected to the positive input end of the other comparator through a diode D1.

5. The device for testing the dynamic performance of the ultrasonic transducer according to claim 1, wherein: the comparison unit adopts a low-power-consumption high-speed comparator MAX998EUT, the input signal is compared with the fixed threshold voltage, and the comparison result is output to the time measurement unit.

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