Part VII: How Bubbles In a Control Valve Affect the Downstream Flowmeter

Oct. 7, 2014

Local pressure inside the control valve may fall below the vapor pressure and create bubbles that may not condense when pressure is recovered downstream of the control valve.

David W. Spitzer

RELATED: Read Part I in the "Troubleshooting Operational Issues" Series

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The following article is the latest in a series based on troubleshooting a mysterious unit shutdown due to flowmeter performance problems.

The problem: Liquid ammonia entering a unit with gas bubbles that caused an ultrasonic flowmeter to break its ultrasonic circuit, measure zero flow, and scram (shut down) the reactor. Installing a jacketed pipe to cool the stream reduced the number of scrams. Installing a larger cooler and/or insulating the 200 meters of upstream piping were not viable options.

Investigation of the ammonia tank farm controls revealed a local pneumatic pressure control loop that adjusted the pressure in the ammonia pipe leaving the tank farm. The control loop effectively functioned as would a pressure-reducing valve. The apparent purpose of this loop was to limit the liquid ammonia pressure to the plant.  

Remember that the vapor pressure of ammonia (and hence the pressure in the ammonia tank) changes significantly with the ammonia temperature. In cold and hot weather, the ammonia tank could exhibit pressures as low as 6 and as high as 10 to 12 bar, respectively.
 
Adjusting the pressure controller setpoint at the maximum desired pressure, the control valve will tend to be more closed in warm weather and more open in cooler weather. Therefore, in warm weather, the control loop presents more of a restriction to the ammonia flow and tends to create a larger pressure drop across the control valve. As a result, not only is the control valve discharge pressure closer to the vapor pressure in warm weather (because its setpoint is only slightly above the tank pressure in warm weather), but the local pressure inside the control valve may fall below the vapor pressure and create bubbles that may not condense when pressure is recovered downstream of the control valve. These bubbles—created by the control valve—can then travel down the pipe and affect the ultrasonic flowmeter in the unit downstream.  

What would you do to resolve this problem?

RELATED: Read Part VIII in the "Troubleshooting Operational Isssues" Series

RELATED: Read Part IX in the "Troubleshooting Operational Isssues" Series

RELATED: Read Part X in the "Troubleshooting Operational Isssues" Series

David W. Spitzer is a regular contributor to Flow Control magazine and a principal in Spitzer and Boyes, LLC offering engineering, seminars, strategic, marketing consulting, distribution consulting and expert witness services for manufacturing and automation companies. Spitzer and Boyes is also the publisher of the Industrial Automation Insider. Mr. Spitzer has more than 35 years of experience and has written over 10 books and 300 articles about flow measurement, instrumentation and process control. 

Mr. Spitzer can be reached at 845 623-1830 or www.spitzerandboyes.com. Click on the “Products” tab to find his “Consumer Guides” to various flow and level measurement technologies.

About the Author

David W. Spitzer

David W Spitzer’s new book Global Warming (aka Climate Change): An Understandable Data-Driven Explanation and Pathway to Mitigation (Amazon.com) adds to his over 500 technical articles and 10 books on flow measurement, instrumentation, process control and variable speed drives. David offers consulting services and keynote speeches, writes/edits white papers, presents seminars, and provides expert witness services at Spitzer and Boyes LLC (spitzerandboyes.com or +1.845.623.1830).

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