Flow
Measurement

High quality flowmeters for practically every application.

Flowmeters for Liquids, Gases and Steam

Endress+Hauser offers one of the widest Flowmeter ranges available, utilising many important measuring principles, for measuring the ﬂow of liquids, gases, and steam in almost every industry sector and application.

Applications include environmental protection, safety, quality control, and process optimisation of processes. As all the flow meter products we sell are manufactured by Endress+Hauser, you can have confidence in their quality.

Plus, you’ll benefit from our unrivaled industry knowledge and product selection expertise. We also offer comprehensive ongoing support to ensure you have the back up you need for the complete lifecycle of the product.

To speak to a member of our team about your requirements, please call us today on +64 9 415 5110.

Widest Range of Flow Measuring Devices

Electromagnetic flowmeters – suitable for liquids that are electrically conductive. Examples include water, wastewater, alkalis, acids, milk, chemicals, and more, with features suitable for a wide range of applications.
Coriolis mass flowmeters – flow meters that measure using the Coriolis principle that allows simultaneous measurement of density, mass flow, viscosity, and temperature. Our products are used in a variety of industries including food and beverage, chemical, life science, oil and gas, and more.
Vortex flowmeters – often used in utilities for measuring steam, gases, and demineralised water in all industries.
Ultrasonic flowmeters – non-intrusive flow measurement of liquids and gases using ultrasonic waves. Options include clamp-on and inline sensors. Clamp-on sensors are well suited for economical measurement in large water pipes and for verification of other flowmeters.
Thermal mass flowmeters – increasingly used in gas metering applications for gases such as carbon dioxide and compressed air. They are often a more effective solution to more traditional techniques of measuring.
Differential pressure measurement – suitable for a wide range of flow measurement applications including liquids, gases, and steam when used together with a pitot tube or annubar.

Electromagnetic

Proven flow measuring technology for all electrically conductive liquids in every industry.

Electromagnetic flow meters have been used throughout industries for more than 60 years.
These meters are applicable for all conductive liquids, such as water, acids, alkalis, slurries, and more. Typical applications are monitoring of liquids, filling, dosing, and precise measurement in custody transfer. Endress+Hauser has manufactured more than two million mag meters since 1977.

Electromagnetic flow measuring principle:

Faraday’s law of induction states that a metal rod moving in a magnetic field induces an electrical voltage. This dynamo principle also governs the way electromagnetic flow meters work. As soon as the electrically charged particles of fluid cross the artificial magnetic field generated by two field coils, and the electric voltage is induced. This voltage, tapped by two measuring electrodes, is directly proportional to the velocity of flow and thus to the flow volume.

Electromagnetic

Benefits:

Virtually independent of pressure, density, temperature, and viscosity
Even fluids with entrained solids can be metered (e.g. ore slurry, or pulp)
Wide range of nominal diameters (DN2 … DN2400)
Free pipe cross-section: CIP/SIP cleanable, piggable
No moving parts, maintenance-free

For additional information please feel free to contact our team directly.

Coriolis

Simultaneous measurement of mass flow, density, temperature and viscosity

Simultaneous measurement of mass flow, density, viscosity, and temperature opens entirely new perspectives for process control, quality assurance, and plant safety.

Coriolis flow measuring principle:

Each Coriolis flowmeter has one or more measuring tubes that an exciter causes to oscillate artificially. As soon as the fluid starts to flow in the measuring tube, additional twisting is imposed on this oscillation due to the fluid’s inertia. Two sensors detect this change of the tube oscillation in time and space as the “phase difference”. This difference is a direct measure of the mass flow.

In addition, the fluid density can also be determined from the oscillation frequency of the measuring tubes. The temperature of the measuring tube is also registered to compensate for thermal influences. The process temperature derived from this is available as an additional output signal.

Benefits:

Universal measuring principle for liquids and gases
Multivariable measurement – simultaneous measurement of mass flow, density, viscosity, and temperature
High measuring accuracy: Typically, ±0.1%, optionally ±0.05% with special
calibration
No inlet/outlet runs required
Measuring principle independent of the physical fluid properties and the flow profile

For additional information please feel free to contact our team directly.

Vortex

Robust and universally applicable for liquids, gases, and steam

Vortex flowmeters are used in all industries to measure the volume flow of liquids, gases and steam. Applications in the chemicals and petrochemical industry for example, in power generation and heat-supply systems involve widely differing fluids: saturated steam, superheated steam, compressed air, nitrogen, liquefied gases, flue gases, carbon dioxide, demineralised water, solvents, oils, boiler feedwater, condensate etc.

Vortex flow measuring principle:

The measuring principle is based on the fact that turbulence forms downstream of obstacles in the flow. Inside each vortex flowmeter, a bluff body is therefore located in the middle of the pipe. As soon as the flow velocity reaches a certain value, vortices form behind this bluff body, are detached from the flow, and transported downstream. The frequency of vortex shedding is directly proportional to the mean flow velocity and thus to volume flow. The detached vortices on both sides of the bluff body generate alternately a local positive or negative pressure that is detected by the capacitive sensor and fed to the electronics as a
primary digital, linear signal.

Benefits:

Universally suitable for measuring liquids, gases, and steam
Largely unaffected by changes in pressure, density, temperature and viscosity
High long-term stability: no zero-point drift and lifetime calibration
Large turndown of typically 10:1 to 30:1 for gas/steam, or up to 40:1 for liquids
Wide temperature range: -200 to +400°C (+450°C on request)

For additional information please feel free to contact our team directly.

Thermal Mass

Direct mass measurement of industrial gases, compressed air, and aqueous fluids

Whenever high turndown or low-pressure losses are important in gas metering applications in any industry, thermal mass flow meters offer a real alternative to traditional measuring techniques, whether for process control, consumption and supply monitoring, detecting leaks, or monitoring distribution networks. Using insertion versions, it is also possible to measure gas flows in very large pipelines or in rectangular ducts.

Thermal mass measuring principle:

This measuring principle is based on the fact that heat is drawn from a heated body when a fluid flows past. A thermal flow meter contains two PT100 temperature sensors for this purpose. One sensor measures the current fluid temperature as a reference. The second sensor is heated and has a constant temperature differential relative to the first sensor at “zero flow”. As soon as the fluid begins to flow in the measuring tube, the heated temperature sensor cools off due to the fluid flowing past – the higher the flow velocity, the greater the cooling effect. The electric current required to maintain the temperature differential is thus a direct measure of mass flow.

Benefits:

Direct measurement and display of mass flow and fluid temperature
No pressure or temperature compensation required
High turndown (100:1)
Excellent low-end sensitivity
Quick reaction to fluctuations in flow

For additional information please feel free to contact our team directly.

Ultrasonic

Versatile and economical flow measurement of gases and liquids

Using ultrasonic waves, the volume flow of a wide variety of gases and liquids can be measured reliably, independent of electrical conductivity, pressure, temperature or viscosity.

Ultrasonic flow measuring principle:
Swimming against the flow requires more power and more time than swimming with the flow.

This simple fact is the basis for ultrasonic flow measurement according to the “differential transit time” method. This method uses two sensors, set opposite each other in the measuring tube. Each sensor can alternatively transmit and receive ultrasonic signals, while simultaneously measuring the signal transit time. As soon as the fluid in the tube starts to flow, the signals are accelerated in the direction of the flow but delayed in the opposite direction. This differential transit time, measured by the two sensors, is directly proportional to the flow rate.

Benefits:

Measurement independent of pressure, density, temperature, conductivity and viscosity
Free pipe cross-section, no pressure loss
No moving parts, minimum maintenance, and upkeep
Long service life, no abrasion or corrosion from the fluid
In-line or clamp-on design for stationary or temporary flow measurements

For additional information please feel free to contact our team directly.

Flow Switches

Calorimetric Flow Switches

Safe monitoring of flowrates with no moving parts

Calorimetric (Thermal) Flow Switches offer the benefit of no moving parts and practically no pressure loss. They are used for monitoring and displaying the relative mass flow rates of liquid media in the range from 0.03 to 3 m/s. Endress+Hauser supplies the following models for standard and hygienic applications:

Flowphant T DTT31 − with threaded connections or compression fitting
Flowphant T DTT35 − with process connections for hygienic applications

Measuring principle:

The Flowphant measures the mass flow of a liquid medium using the calorimetric measurement method. The calorimetric measuring principle is based on the cooling of a heated temperature sensor. Heat is removed from the sensor by forced convection due to medium flowing by. The extent of this heat transfer depends on the flow velocity of the medium and the difference in temperature between the sensor and the medium (King’s Law). The higher the flow velocity or the mass flow of the medium, the greater the temperature sensor cooling.

Applications:

Monitoring of cooling water circuits of pumps, turbines, compressors and heat exchangers
Monitoring of pump functions
Leak monitoring in process pipes
Monitoring of lubrication circuits
Filter monitoring in the beverages industry

Benefits:

Virtually zero pressure loss
FieldCare for quick configuration and reliable storage of device settings
Optional: 4 to 20 mA analogue output for outputting the flow as a percentage
Optional: second switch output or 4 to 20 mA analogue output for temperature monitoring
Onsite function check and process information with a digital display on the device
Top housing section which can be rotated 310° and rotatable display mean measured values can be read in all installation positions
Marine approval
3-A mark and EHEDG certificate for DTT35

Please note the EMC also supply the Weber Flow-Captor range of calorimetric flow switches

For additional information please feel free to contact our team directly.