Flowmeter calibration management

Endress+Hauser Australia Pty Ltd
By Ben Keizers and Kyle Shipps*, Endress+Hauser USA
Friday, 05 September, 2014


Failure to calibrate flowmeters can negatively impact performance, while calibrating too frequently can result in excessive costs without providing any benefits. So, the question is, how do you determine if calibration is needed and what the frequency should be?

A flowmeter that is not measuring properly can cause many problems. In a custody-transfer application involving crude oil or natural gas, even the smallest error can cost a customer millions of dollars a year. In a food processing plant, a similar error can adversely affect the quality and safety of food products, resulting in the costs that go along with such failures.

Because flow measurements are so critical to many processes, the industry standard is to calibrate annually, even though that might not be necessary. In many cases, this is done in an attempt to demonstrate to a quality auditor that instruments within the process are under control. For most companies, annual calibration is performed as a traditional ritual with no scientific basis behind it, other than it being the longest duration of time they are willing to risk before finding a potential problem.

In many instances, yearly calibrations are not necessary, as some flowmeters require calibration only once every three or four years depending on the process fluid, operation and criticality. In other cases, a flowmeter may require calibration much more frequently, possibly on a monthly basis, to maintain a safe, efficient or regulatory compliant operation. It’s also important to realise that calibration intervals are not always fixed, meaning that they might fluctuate based on usage or historical performance.

How do you determine when to calibrate a flowmeter? By setting up a calibration plan that follows best practices for flow calibration.

The importance of instrument assessment

The first step in a calibration plan is to perform a plant-wide assessment of all your instrumentation, including flowmeters. To do this, you must first identify and make a list of all the equipment parts and all instrument-related systems. This list should also include details such as description, location information, operating conditions, working range and history, and any other points that provide a better understanding of the part’s function.

The first stage in analysing this data is to identify which instruments are critical to the application, the environment and operator safety. To start, the head of metrology (quality) and head of maintenance - or similar professionals who have the most in-depth knowledge of the process and related instruments - should together determine their knowledge of the process environment, the condition of the installed instruments, the type of maintenance work carried out and, finally, any limitations imposed by the plant in terms of servicing.

After this information is compiled, it is important to start from the finished product - and the tolerance permitted in relation to its quality - and go back through the various stages in the production process. At each stage it is important to assess each instrument and flowmeter in place and ask, does this instrument have an impact on the quality of the product (or intermediary product) on process functioning, or operator safety? The total installed base will determine how frequently to calibrate flowmeters. The next step will be to then set up a calibration plan depending on these factors.

Prioritise your flowmeters

After an installed base audit has been performed, it is important to categorise all flowmeters by critical importance. Flowmeters fall into one of four categories, ranging from critical to noncritical importance.

The first category - flowmeters critical for the product - are those that affect product quality. We start here, because these flowmeters have a direct link to company profits, whether it involves measurement of ingredients in food processing, mixing of chemicals or custody-transfer applications.

The next category - flowmeters critical to the process - are those that can upset the overall plant or other processes (shutting down the entire process) and thus cause inefficiencies and production losses, but have no direct effect on product quality or safety.

Flowmeters critical for safety have a direct impact on operator safety, equipment protection and/or the environment. These flowmeters do not necessarily have to be extremely accurate, but they certainly have to work properly and reliably.

Finally, non-critical flowmeters have no impact on product quality, the overall process, safety or the environment.

After all flowmeters have been identified and classified into these four categories, a maximum permissible error (MPE) is assigned to each device. MPEs define the tolerance for each function being measured. A critical flowmeter will usually have a more stringent MPE than a non-critical flowmeter.

Asset management software

Flowmeter data from the audit should be stored in an asset management, maintenance management or instrumentation management program. One of the major advances in recent years has been the development of instrumentation management software. These systems provide information such as spare parts lists, drawings specific to the flowmeter and original calibration data and certificates (Figure 1).

Figure 1: A technician manages a flowmeter’s calibration data via a software system, such as Endress+Hauser’s CompuCal calibration management system.

Figure 1: A technician manages a flowmeter’s calibration data via a software system, such as Endress+Hauser’s CompuCal calibration management system.

Most flowmeters are calibrated by each manufacturer prior to delivery to the customer, and the calibration data is easily entered into asset management software. Afterwards, when a flowmeter is recalibrated, the device’s calibration history is updated and can potentially be automatically loaded via an electronic calibrator connected to the asset management system.

Diagnostic data from each flowmeter can be read by the automation system or by the asset management system. For example, diagnostic data for a Coriolis flowmeter includes empty pipe detection, sensor drift, sensor error, electronics error, inhomogeneous mixture error, ambient and process temperature errors, and other information. This data can be used to optimise calibration, to diagnose problems and to detect minor issues before they grow into substantial problems.

All flowmeter vendors provide this kind of information in real time, typically via fieldbus. Depending on the fieldbus, flowmeters can also provide diagnostic data directly to technicians in the field. EtherNet/IP, for example, lets devices be polled by a condition monitoring or automation system to determine if there are any diagnostic messages that need to be sent to maintenance personnel as an alert.

Deciding when to calibrate

Setting up a flow calibration plan for individual instruments often requires assistance from the flowmeter manufacturer and a qualified calibration company with industry experience, as they are best qualified to advise on how often a flowmeter should be calibrated in a typical installation. The end user must then use this advice and apply it based on particular service conditions, functions of the meter and their experience.

Calibration frequency depends on the criticality and MPE, as well as the nature of the product being measured, the continuity of the process (continuous use or intermittent use), the need for clean-in-place (CIP) operations, the severity of process impacts, the type of flowmeter (contact or non-contact) and how easy it is to access and remove the flowmeter for calibration.

In some cases, it may only be possible to access a flowmeter during a complete process shutdown; in other cases, a flowmeter might be completely accessible for calibration.

In a new plant, setting the flowmeter calibration frequency is usually based on expected operational parameters and advice from the flowmeter manufacturer and qualified calibration team. But in an existing plant, the frequency of calibration can be based on actual historical experience and previous documented calibration performance with the flowmeters and processes that yield better results. It is important to note that in either case quality, regulatory or safety requirements may dictate a specific calibration interval regardless of the advice from the flowmeter manufacturer or historical data from previous calibrations.

Once a calibration plan has been in effect for a few years, the instrument management software takes on a bigger role. When a calibration is done on a flowmeter, new data is recorded and stored in the database. This data shows the status of the flowmeter before and after calibration, and it may very well indicate that the flowmeter does not require calibration as often as expected.

Where to calibrate?

Depending on the application and the standards involved, flowmeters can require calibration, proving or verification. For calibration, flowmeters are removed from the process and shipped to a calibration facility (Figure 2).

Accredited calibration labs must meet the requirements of ISO/IEC 17025 (an international standard that defines the quality and technical requirements for calibration laboratories) to ensure traceability to the governing national metrology institute in your country.

Figure 2: At a certified flow calibration rig, flowmeters are calibrated to meet applicable standards.

Figure 2: At a certified flow calibration rig, flowmeters are calibrated to meet applicable standards.

Accreditation of a calibration laboratory’s proficiency is performed by third-party accrediting bodies. Laboratories that have achieved ISO/IEC 17025 accreditation have published defined scopes of accreditation, which illustrates their range of calibration capability.

Calibration can also be done at the user site, using a portable flow rig (Figure 3). A portable rig does not provide the same accuracy as a calibration lab, but it can calibrate instruments to within ±0.25% or better, depending on the specifics of the flowmeter under calibration.

Portable flow calibration rigs offer convenience and speed. Depending on plant topology, many measuring points can be quickly calibrated with minimal interruption to a process. This helps to minimise downtime or shutdown of the process, especially when fast turnaround and keeping production up and running is most crucial.

Portable flow rigs can handle flowmeters up to a maximum of DN50 (5 cm) with results traceable to recognised standards, and the turnaround time is reduced to hours versus days or weeks when the meter is removed from site and sent to a calibration laboratory.

Figure 3: A portable flow calibration rig performs on-site flowmeter calibration.

Figure 3: A portable flow calibration rig performs on-site flowmeter calibration.

Flow proving

Portable calibrations can also include flow proving. Flow proving is typically performed by the oil and gas industry on devices used for hydrocarbon custody transfer. In proving, a transfer standard is installed inline with the flowmeter under test on process fluid under process conditions. Specific requirements for test methods and for documented results are required in the oil and gas industry. Transfer standards can be master meters, piston, small volume, ball or bidirectional provers. During proving, the flowmeter under test is compared to the transfer standard and an external meter factor is determined, based on the unit under test’s repeatability. Proving differs from calibration in that it’s typically in situ testing under process conditions.

Verification

It is important to distinguish that unlike calibration, verification aims to provide evidence that a flowmeter fulfils certain technical requirements of functionality as defined by the manufacturer. It is usually a very detailed functional test to confirm sensor or transmitter stability and produces a qualitative outcome. Electronic verification consists of the flowmeter and a verification system (Figure 4).

A verification system acquires a number of flowmeter parameters related to the flowmeter response. These values are evaluated by a dedicated algorithm in the verification system and the system parameter reference values. The result will deliver the current status of flowmeter functionality. The final outcome is a qualitative assessment report based on a pass-fail criterion such as process impacts, drift or hardware failures. The concept of verification must define the long-term stability of the test system, the stability of internal references and metrological traceable factory references for user confidence. In many cases, verification can be performed on less critical meters or as a means to extend the calibration frequency.

Figure 4: On-site flow verification performed with a test and simulation device - removal of the instrument from the pipe is not required.

Figure 4: On-site flow verification performed with a test and simulation device - removal of the instrument from the pipe is not required.

A clamp-on ultrasonic flowmeter can also be used to check a flowmeter’s operation. While a clamp-on ultrasonic flowmeter typically has only 2-5% accuracy, comparing the ultrasonic flow measurement to that of the installed flowmeter can provide some level of confidence that the meter being tested is operating properly. Such a test is often performed in concert with verification on very large flowmeters in water and wastewater applications, or on other flowmeters that are difficult to remove for full calibration testing.

Conclusion

Thanks to advances in flowmeter diagnostics and instrument management software, the increasing availability of nearby calibration labs and portable calibration rigs, and the willingness of instrument vendors to help users with calibration, setting up a flow calibration plan based on best practices is much easier than in the past.

Once set up, the flow calibration plan will improve operations and save money by making sure all flowmeters are calibrated only when necessary.

*About the authors

Ben Keizers is the Product Business Manager for Services and has worked for Endress+Hauser USA for over six years.

Kyle Shipps is the Calibration Manager for Endress+Hauser USA and has worked in the Service Department for 13 years.

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