Grab sampling—also known as spot sampling, laboratory sampling, field sampling, and closed-loop sampling—involves the manual collection of a sample of fluid in a pipeline, tank, or system and its transportation to a laboratory for qualitative analysis. The right grab sampling equipment can obtain representative fluid samples to verify and confirm several aspects of processes for Northern California plants.
To obtain a meaningful and representative sample depends highly on the equipment selected, panel design, and proper collection of the fluid. Below we detail the basics of grab sampling and best practices for equipment design, cylinder selection, and sample collection.
| Click to Watch How to Develop the Right Grab Sampling System for your Plant |
While there are many different styles of grab sampling systems, we categorize them into two categories:
Grab sampling is often a critical function for Northern California plants and can be used for sampling storage tanks, long transport lines, process lines, flare emissions, and process analyzers for:
Grab sampling and online analyzers both have their advantages and disadvantages depending on the application, process conditions, and time constraints. Let’s take a look into the pros and cons of grab sampling as it compares to online analyzers.
Grab Sampling Advantages:
Grab Sampling Disadvantages:
When designing grab sampling equipment, there are a number of things to keep in mind. Detailed below are general guidelines for grab sampling, design considerations, sample container selection, and best practices for sample collection.
When sampling from a pipeline, it is important to ensure that the sample is representative, meaning it actually reflects the characteristics of the process. This can be achieved by avoiding phase changes in the sampling system and during transport as well as using probes to sample the center third of the pipe vs. the wall of the pipe.
While grab sampling is inherently not as timely as an online analyzer installation, timeliness is still important. Transport time from the process to the panel and sampling container should be minimized. The time from process to the panel can determine what process corrections should be made based on the results.
A sample can be representative, but may be in the wrong state and thus cannot be injected into the analyzer. Conversely, the sample may be old and non-representative of the process flow due to dead leg contamination, but in the correct state for analysis. It may provide results that may be interpreted as accurate, but they aren’t.
Flush time is the amount of time required to flush out old fluid from supply lines to allow a fresh sample to be captured in the sample container. It is a measure of time required to move the sample from the sample tap to the container and is a function of flow rate and system volume. Utilizing panels with a continuous flow, the transportation line to the sample panel is always flowing and is returned to the process, yielding two significant benefits:
It should be noted that flushing and continuous flow are different from purging. Purging utilizes a secondary fluid, typically nitrogen, to flow through the panel for cleaning purposes. Purging is often done when a sample is toxic or a sample is a warm liquid that may cool and solidify, clogging the lines.
It is critical to prevent volatile liquids from vaporizing, due to fractionation. Similarly, it is important to prevent condensation in gas samples. Thus,
Sample container selection depends heavily on sample toxicity, budget, sample pressure, and sample volatility. Sample cylinders are more suitable for gases, toxic samples, or samples which must be maintained at a specific pressure to maintain process conditions. Bottles are more suitable for nonvolatile liquids. The matrix below shows general guidelines for selecting a sample container.
When using sample cylinders for grab sampling, there are a few basic rules to follow in addition to proper sampling procedures:
Similarly, when using bottles for grab sampling, best practices include:
With sample cylinders, there is always a concern with the over-pressurization of the container. For liquid samples, an outage tube is often used to create a vapor space, thus protecting the cylinder from over-pressurization due to thermal expansion of the liquid. For either gases or liquids, rupture discs and relief valves are typically used to prevent over-pressurization. However, it should be noted that rupture discs and relief valves should not be used for sampling applications involving a toxic fluid.
Whether you need to install a new custom-configured grab sampling system—or optimize your current system to better inform the process—Swagelok Northern California has you covered. With our proven industry expertise, superior component quality, and industry-leading assembly services, we are your top choice for grab sampling equipment. To learn more about our custom configurable grab sampling panels and sample cylinders, contact our team or download our presentation and watch the webinar replay below.
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To find out more about how Swagelok Northern California can help you select the right grab sampling equipment for Northern California plants, contact our team today by calling 510-933-6200.
Morgan holds a B.S. in Mechanical Engineering from the University of California at Santa Barbara. He is certified in Section IX, Grab Sample Panel Configuration, and Mechanical Efficiency Program Specification (API 682). He is also well-versed in B31.3 Process Piping Code. Before joining Swagelok Northern California, he was a Manufacturing Engineer at Sierra Instruments, primarily focused on capillary thermal meters for the semiconductor industry (ASML).