Industrial Ultrasonic Flow Meter System Theory
Ultrasonic flow meters are volumetric flow meters that are used to measure the flow rate of liquids, gases, or steam. They are commonly found in oil and gas, pharmaceutical, and food and beverage industries. Flow meters use time of flight or doppler techniques to measure flow rate.
Flow meters that use the time of flight principle have a pair, or multiple pairs, of transducers. The transmit time of the ultrasonic waves is measured in both directions and from this the flow rate can be calculated. This technique typically requires a relatively pure medium, with <5% particles. Accuracies of <1% are achievable.
Using the doppler approach, ultrasonic pressure waves are reflected off of moving particles in the flow. The velocity of these particles creates a doppler shift in the echo signal, which is used to determine the flow rate. This measurement approach is typically limited to 3% accuracy in real-world implementations.
An ultrasonic flow meter consists of power supplies, transducer excitation, signal conditioning, ADCs, processing, a display, a keypad, and multiple communication options, such as 4 mA to 20 mA, HART, RS-485, and wireless.
This solutions guide will focus on ultrasonic flow meters based on the time of flight principle. The signal chain below is best suited for applications requiring higher performance, especially those with multiple pairs of transducers. As well as the need to achieve high measurement accuracy, these designs often have significant space constraints.
In liquid ultrasonic flow meters, a 1 MHz ultrasonic frequency is common. The accuracy of the system is directly related to the relative accuracy of the upstream and downstream time of flight measurements. For this reason, an FPGA is generally used to control the timing of the transmit and receive pulses. Careful attention must also be paid to any possible variations in latency of the transmit and recieve signal paths.
Another important aspect is the high gain required by the receive signal chain. This gain needs to be dynamically adjustable for different flow conditions and pipe sizes, typically in the range of 60 dB or higher, thus requiring a low noise receive signal chain path.
The transducer excitation can be either be on/off or a waveform generator may be used. A waveform generator typically adds cost and complexity, but provides greater control of the output signal allowing for an even more accurate and robust flow meter design.
The signal processing requires considerable filtering and FFT analysis to determine a precise time-stamp for the receive signal, which can be done using a DSP processor that can also support the required interface protocols.
Nº de pieza | Descripción | |
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AD5681RBCPZ-1RL7 Analog Devices Inc. |
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AD5420AREZ-REEL7 Analog Devices Inc. |
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AD9705BCPZ Analog Devices Inc. |
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AD5681RBRMZ Analog Devices Inc. |
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AD9106BCPZ Analog Devices Inc. |
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AD5420AREZ Analog Devices Inc. |
Adquisición de datos - Convertidores digitales a analógicos (DAC), IC DAC 16BIT 1CH SER 24TSSOP | RFQ |
AD9629BCPZ-80 Analog Devices Inc. |
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AD9629BCPZ-40 Analog Devices Inc. |
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AD9670BBCZ Analog Devices Inc. |
Adquisición de datos - Circuitos frontales analógicos (AFE), IC AFE 14BIT 8CH W/DIG DEMOD BGA | RFQ |
ADT7320UCPZ-R2 Analog Devices Inc. |
Temperature Sensors, Transducers, SENSOR TEMPERATURE SPI 16LFCSP | RFQ |
ADT7320UCPZ-RL7 Analog Devices Inc. |
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ADF7242BCPZ-RL Analog Devices Inc. |
CI de transceptor RF, IC RF TXRX+MCU 802.15.4 32-WFQFN | RFQ |
ADF7023-JBCPZ Analog Devices Inc. |
CI de transceptor RF, IC RF TXRX+MCU ISM<1GHZ 32-WFQFN | RFQ |
ADF7023BCPZ Analog Devices Inc. |
CI de transceptor RF, IC RF TXRX+MCU ISM<1GHZ 32-WFQFN | RFQ |
ADF7242BCPZ Analog Devices Inc. |
CI de transceptor RF, IC RF TXRX+MCU 802.15.4 32-WFQFN | RFQ |
ADM2582EBRWZ-REEL7 Analog Devices Inc. |
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ADM2582EBRWZ Analog Devices Inc. |
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ADM2587EBRWZ Analog Devices Inc. |
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ADM2587EBRWZ-REEL7 Analog Devices Inc. |
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