Views: Release Time:2023-03-31
Ultrasonic flow meters, which are a type of volumetric flow meter, are non-intrusive flow sensors that use acoustic vibrations to measure the flow rate of a liquid. There are two types, Doppler and transit time.
Ultrasonic meters are ideal for automated wastewater applications or any dirty liquid which is conductive or water based – but will generally not work with distilled water or drinking water. These flow meters are also ideal for applications where low pressure drop, chemical compatibility, and low maintenance are all requirements.
In 1842, Christian Doppler discovered that a stationary observer perceives a sound to have shorter wavelengths as its source approaches, and longer wavelengths as its source recedes.
This became known as the Doppler effect and explains why one hears rising pitch in the blowing horn of an approaching car. When the car zooms away, the pitch seems to drop. Ultrasonic Doppler flow meters put this frequency shift to work in so-called dirty liquids containing acoustical discontinuities – or suspended particles, entrained gas bubbles, or turbulence vortexes.
Ultrasonic flow meter technology is a non-contact means of measuring the velocity of a fluid. They are clamp-on devices that attach to the exterior of the pipe (and fit a variety of pipe sizes) and enable measurement of corrosive liquids without damage to the ultrasonic sensor. Portable ultrasonic flow meters are available to aid in industrial application.
The two types of ultrasonic flow meters, Doppler and transit time, each function by way of two different technologies. The Doppler ultrasonic flow meter must have particles or bubbles to reflect the ultrasonic signals. Consideration must be given to the lower limits for concentrations and sizes of solids or bubbles, and the liquid must flow at a rate high enough to keep the solids suspended.
When transmitted into a pipe that contains flowing liquid with such discontinuities, an ultrasonic pulse or beam reflects from them with a change in frequency that is directly proportional to the liquid’s flow rate. Thus, the ultrasonic Doppler flow meter calculates liquid flow rate from the velocity of the discontinuities, rather than from the velocity of the liquid.
The basic principle of operation employs the frequency shift (Doppler Effect) of an ultrasonic signal when it is reflected by suspended particles or gas bubbles (discontinuities) in motion. This metering technique utilizes the physical phenomenon of a sound wave that changes frequency when it is reflected by moving discontinuities in a flowing liquid. Ultrasonic sound is transmitted into a pipe with flowing liquids, and the discontinuities reflect the ultrasonic wave with a slightly different frequency that is directly proportional to the rate of flow of the liquid. Current technology requires that the liquid contains at least 100 parts per million (PPM) of 100 micron or larger suspended particles or bubbles.
The Doppler ultrasonic flow meter operates on the principle of the Doppler Effect, which is the physical phenomenon of a sound wave changing frequency. In the case of ultrasonic flow meters, the frequency of an ultrasonic signal changes (Doppler Effect) in direct proportion to the rate of flow of the liquid when reflected by suspended particles or gas bubbles (discontinuities) in motion.
Typically, an ultrasonic Doppler flowmeter consists of a transmitter/indicator/totalizer and a transducer. The user selects a configuration appropriate to the application – taking into account the liquid, the size and concentration of solids or bubbles, the pipe dimensions and the pipe lining. The transmitter’s signal threshold usually adjusts to filter out mechanical and electrical noise.
A high-frequency oscillator in the transmitter drives the transducer, which, in the popular clamp-on design, mounts on the pipe exterior. The transducer generates an ultrasonic signal that passes through the pipe wall into the flowing liquid; the transmitter converts the difference between its output and input frequencies to electronic pulses. Processed, scaled, and totalized, the pulses provide a measurement of flow.
Ultrasonic Doppler flowmeters that clamp onto the outside of a pipe operate non-invasively, without moving parts. They cause no pressure drop, risk no damage from the process liquid, and entail little maintenance. If properly calibrated, they can have ±1% accuracy – however, the pipe wall and any air space between the wall and the liquid can generate signal interference. Moreover, a stainless-steel pipe wall might conduct the transmitted signal to the extent that the reflected signal will seem to undergo a major shift.
Transit time ultrasonic flow meters measure the time difference between when an ultrasonic signal is transmitted from the first transducer until it is received by the second transducer. A differential comparison is made of upstream and downstream measurements. If there is no flow, the travel time will be the same in both directions. When flow is present, sound moves faster if traveling in the same direction and slower if moving against it.
A third ultrasonic flow meter employs cross-correlation between upstream and downstream transducer pairs to compute flow. Some flow meters of this design use microprocessors to switch automatically between “clean” and “dirty” modes based on correlation factors. A single cross-correlation hybrid flowmeter could, for example, monitor flow of either activated or digested sludge. Carefully engineered applications using such flow meters have had reported installed accuracy within 0.5% of reading.
Ultrasonic flow meters are also ideal for applications where low-pressure drop is needed and low maintenance is required. An ultrasonic Doppler flow meter is a volumetric flow meter that is ideal for aerated liquids such as wastewater or slurries. Transit time ultrasonic flow meters are ideal for clean liquid applications such as water and oil.
There are three main types of ultrasonic flow meters. Factors such as the type of output (analog or digital), size of the pipe, minimum and maximum process temperature, pressure, and flow rate can all impact which ultrasonic flow meter is right for your application.
Clamp-on ultrasonic flow meters come in either single or dual-sensor versions. In the single-sensor version, the transmit and receive crystals are potted into the same sensor body, which is clamped onto a single point of the pipe surface. A coupling compound is used to ultrasonically connect the sensor to the pipe. In the dual sensor version, the transmit crystal is in one sensor body, while the receive crystal is in another. Clamp-on Doppler flow meters are subject to interference from the pipe wall itself, as well as from any air space between the sensor and the wall. If the pipe wall is made of stainless steel, it might conduct the transmit signal far enough so that the returning echo will be shifted enough to interfere with the reading. There are also built-in acoustic discontinuities in copper, concrete-lined, plastic-lined, and fiberglass-reinforced pipes. These are significant enough to either completely scatter the transmitted signal or attenuate the return signal. This dramatically decreases flow meter accuracy (to within only ±20%), and, in most cases, clamp-on meters will not work at all if the pipe is lined.
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