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Turndown Ratio and Metering Pumps

Turndown Ratio and Metering Pumps

Metering pumps are reciprocating positive displacement chemical dosing devices with the ability to vary capacity manually or automatically as process conditions require.These pumps are used in applications requiring highly accurate, repeatable and adjustable rate of flow.

mRoy Metering Pump
Proteus Metering Pump
Centrac Metering Pump

Related product with turndown capabilities



Metering pumps are characterized by their ability to meet specific performance requirements concerning linearity, steady state accuracy, and repeatability. Turndown (the adjustable range of a metering pump) and Accuracy are the key to defining the quality and performance of a metering pump.

 

Turndown Ratio is the rated capacity divided by the minimum capacity that can be obtained while maintaining specified steady state accuracy and linearity.

 

Example
Rated Capacity: 50 Gallons per Hour
Minimum Capacity: 5 Gallons per Hour
Turndown: 50 / 5 = 10
Turndown Ratio: 10:1

 

In the above example, the turntown ratio is 10:1. If minimum capacity was 0.5 GPH, the turndown ratio would be 100:1. However, defining turndown without accuracy is meaningless.

 

Consider the same pump rated at 50 GPH maximum capacity. If you don't define accuracy, technically the pump can be turned down to 0 GPH, in which case the value is infinite.

 

Defining Accuracy requires two inputs:

  • The percentage range expressed as a ±value
  • A qualifier that actually defines what true value is of the stated percentage

 

Metering pumps usually have an accuracy of ±1%. Manufacturers use full range/scale, steady state at set point or repetitive as a qualifier to define accuracy. Steady state at set point is the only useful qualifier of the accuracy percentage range for a metering pump. Let us look at each qualifier in detail and why steady state at set point is the best qualifier.

 

Full Range or Full Scale Accuracy
Uses the maximum capacity of the pump as a valve. In our example above:

  • Accuracy of ± 1% of full scale
    ○ 1% of full scale = 0.5 GPH
  • Accuracy at 100% capacity setting (50 GPH)
    ○ 50 GPM ± 0.5 GPH
    ○ 0.5 / 50 = 1% of set point
  • Accuracy of 10% capacity setting (5 GPH)
    ○ 5 GPH ± 0.5 GPH
    ○ 0.5 / 5 = 10% of set point

 

Full scale accuracy is not very accurate. From our 50 GPH example above, 1% of full scale = 0.5 GPH. No matter where we set the pump’s capacity, its flow specification allows an error of plus or minus 0.5 GPH, which in total is actually twice that because it’s ±. So the error range is 1 GPH.

 

When the pump is set at 100% capacity, it is an easy to understand calculation because it equals ± 1%. However when the pump is set at 10% capacity, the allowable variation is still equal to 1% of the maximum capacity. So the user expects 5 GPH, but with a possible ± error of 0.5 GPH. The actual allowable deviation, by specification, is now ± 10% of the pump's set point – an error range equal to 20% of the pump's setting. This is not metering pump accuracy. To achieve accuracy the Steady State at Set Point must be set.

 

Steady State at Set Point Accuracy
Uses the current capacity setting of the pump as the value. From above example:
At 100% capacity setting, 1% = 0.5 GPH
At 10% capacity setting, 1% = 0.05 GPH

 

Steady state accuracy is the only useful accuracy for a metering pump. It’s measured at the pump’s current capacity setting. The value of the flow changes based on the capacity setting because the percentage is based on the setting, not the maximum pump rating.

Chart 1 steady state accuracy

Chart 1 shows the upper and lower limit of a metering pump with ± 1% steady state accuracy. The margin for acceptable deviation is very narrow – and that’s a true controlled volume metering pump as defined by hydraulic institute, ANSI, and API.

 

Repetitive Accuracy
Repetitive accuracy has 2 meanings:

  • Accuracy of the pump continuously operating at the same capacity setting
  • Accuracy of the pump at a specific setting when capacity is changed, and then returned to the original setting

 

Repetitive accuracy is also often misused. It’s not really an overall statement of pump accuracy that would be tied to turndown. It’s only relationship to turndown is that the repetitive accuracy only applies within the turndown range.

 

The purpose of a metering pump is to deliver predictable flow at a capacity setting, so definition 2 applies. Definition 1 means very little because it does not really challenge the pump's ability to be predictably accurate over its full range. That is why definition 1 is often applied to pumps that are not really metering pumps. API and other standards organizations define ± 3% as the specification for repetitive accuracy, and expect the pump will be tested according to definition 2.

 

In conclusion, it should be clear that you cannot separate turndown from accuracy, and that steady state accuracy is the only form of an accuracy statement that has values in a metering pump application. It is measurable, verificable, and adds value to the pumping system.

 

A true controlled volume metering pump meets stringent agency standards for turndown and steady state accuracy.

 


Learn the Proper Way to Measure a Metering Pump’s Turndown

What is turndown and how is it accurately measured? Download our educational white paper to learn why knowing the true turndown of a pump is essential, especially when it comes to metering pumps. Milton Roy’s experts will not only explain the proper ways of measuring turndown, but they will also tell you about the turndown myths you should avoid.


Learn more

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