Going Round in Circles: Titan Enterprises Explains the Working Principles of the Pelton Wheel and Other Turbine Flow Meters
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Turbine flow design has changed little since their invention in the eighteenth and nineteenth centuries due to the simplicity and power of these devices to extract energy from the movement of a flowing water source.
Turbine flow meters are one of the most commonly used and simplest methods of measuring liquid flow, from water and beer to aggressive chemicals, including ultra-pure water. The variety of turbine flowmeters are based on the mechanics – the physical orientation of the turbine in relation to the fluid flow.
Turbine flowmeters work in two primary ways:
1. Analogous to a propellor or windmill – Axial turbine
2. Analogous to a water wheel – Radial turbine
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Subscribe for FREETurbine flowmeters measure the flow rate of a fluid within a pipe or process line by utilising a rotor or turbine that rotates on an axis as the fluid moves across its blades. As the turbine rotates, each blade of the turbine passes a sensor which outputs a pulse signal. The speed at which the turbine rotates is directly proportional to the volumetric flow rate and the number of pulses the total volume passed.
In an axial turbine, the fluid flows along the rotation axis where the fluid enters and exits in the same direction, the fluid striking the angled turbine blades.
In contrast, fluid flowing through a radial turbine strikes the plain blade in the direction of the tangent or 90° to the rotational axis (hence also referred to as tangential flow).
Titan Enterprises released its first flowmeter sensor in 1981, a turbine device based on the Pelton Wheel design and working principles of the radial turbine.
The Pelton wheel, conceived by Lester Pelton in the 1870’s, is an energy extraction device. Its working principle and design are simple: characterised by a series of distinctive reaction cups, to extract as much energy as possible from the moving liquid, typically to generate electricity. These cups or buckets efficiently capture the momentum of high-velocity water jets, inducing an impulsive force. This force makes the turbine rotate and the rotating shaft runs a generator to produce electricity. As the energy available is only kinetic energy, the Pelton wheel is an example of an impulse turbine.
Such impulse turbines do not require an enclosed case, whereas Radial flow turbines have very different requirements. They must operate in an enclosed pressure chamber and have a linear velocity to flow rate characteristics. Early flowmeters were designed using radial flow onto blades (without reaction cups) with single or multi-jets of liquid. In the last seventy years or so, as accurate measurement of lower flow became a requirement, smaller meters were produced and became known as the generic Pelton wheel flow meter we know today where a single jet impinges a flat blade in an enclosed chamber. There are many design variations of these devices to ensure the best overall performance is attained. The most common system is to simply point a jet radially at a turbine and place the outlet directly opposite the inlet. The turbine has multiple flat blades, from 3 to many more. Titan has utilised up to 12 blades in order to increase the resolution on custom-designed OEM turbine flowmeters, thus improving the accuracy of low volume dispense.
Axial flow turbines are typically larger and have a higher flow throughput. Generally more efficient at moving large volumes of air or fluid at lower pressures, they are more suitable for large-scale, high-speed applications where high flow rates and low pressure drops are of prime importance. As such conventional axial turbines are commonly used in thermal power plants, propulsion aircraft engines, wind turbines, and cooling fans for electronics and HVAC systems. Complex designs, manufacture and maintenance of axial turbines can be costly and challenging, becoming increasingly difficult to manufacture as size is reduced and bearing drag becomes more significant.
On the other hand, radial turbine flowmeters are better suited for applications requiring low flow rates, typically seen in medical applications and laboratory work.
Whilst offering many advantages and ideally suited to handling clean fluids, the turbine flowmeter has one Achilles’ heel: it is very sensitive to changes in liquid Reynolds Number; a product of viscosity and density, therefore temperature and, for gas fluids, pressure. Turbine flow devices perform most efficiently with turbulent flow of liquid through the meter. Laminar flow and viscous drag can disrupt the dynamic behaviour of this type of flowmeter which ultimately affect the accuracy of flow measurements. To mitigate this effect, Titan use a hexagon-shaped chamber which permits the formation of vortices that reduce the drag and assist the linearity into the laminar flow region.