Avoid Costly Fabrication Mistakes

As the vessel’s diameter, weight or length increase, shipping costs can become an overriding factor on which fabricators you invite to bid. Vessels more than 16-ft. diameter can only be trucked a short distance economically; hauling by either rail, barge, or shop fabricated in pieces and field assembled becomes the norm. Between 12-ft. and 16-ft diameters, it becomes very situational, so chose your bidders wisely. Moving a large vessel from the fabricator’s shop through a city to a major interstate or river can cost $10,000/mile and usually the most direct route can’t be taken. Factor in geographic location. It’s easier to ship wide loads in Western U.S. states than in the more congested Northeast.

3. Move carefully with used and relocated vessels. Several suppliers specialize in used equipment; check the classified ads in Chemical Processing and other magazines. Such vessels can be purchased at a discount and are available for your inspection if desired. Also, some operating companies often consolidate operations into a single location, which can lead to relocating vessels and other major equipment across state lines. When relocating a used ASME-code vessel to your state, first check with the office of the Chief Boiler Inspector in your state capital. Many state laws require pre-approval and inspection by that office before a vessel can enter the state. Failure to comply with state law carries monetary penalties.

4. Pay attention to internal coils. Internal coils can be included as part of an ASME vessel but aren’t required to be code stamped. It’s good practice to include internal coils in the pressure vessel scope so that strict quality control procedures are followed and third party inspections are performed. Internal coil failure can lead to forced shutdown, off-spec product quality and possibly safety concerns.

For internal coils, specify butt-type joints with 100% radiography and avoid internal flanges, threads, couplings and socket-type joints. Fillet welds, which are associated with socket joints, are more prone to fatigue failures and aren’t easily radiographed. Return bends (180 deg.) and coils bent from pipe improve reliability by minimizing internal welds and fittings, which are the primary cause of coil failure. A heavy corrosion allowance is suggested. A coil will be buoyant if steam is used as a heating medium (because its specific gravity is less than that of the product); so, design for both hold-down and thermal growth.

5. Understand the role of code inspectors. Vessel inspections are performed in the shop by Code Authorized Inspectors, commonly referred to as AIs. They aren’t employed by the fabricator or vessel owner but by the fabricator’s insurance company or, sometimes, by the local jurisdiction (i.e., state or city government). Their purpose is to confirm vessel safety — not absolute quality — by ensuring the fabricator has followed the rules and procedures of the ASME code. They check to ensure the materials, welding and testing meet the rules of the code for which the vessel was designed and major dimensions, such as vessel diameter and overall length.

It’s up to the owner or designer to perform quality checks. AIs don’t check for all nozzle locations or measure support lug location or many of the minor dimensional requirements (e.g., nozzle projection) needed for your project. They don’t check for special surface finishes, internal or external coatings or contractual requirements written in requisitions and purchase orders. They will check for special testing and examination requirements if specified on the fabrication drawings. If dimensional accuracy or special coatings and finishes are essential for your project, it behooves you to schedule shop inspections.

6. Address documentation and archiving. How many times have you needed to replace a 20-plus-year-old vessel and worried about finding adequate documentation in the company files? Often only a drawing can be located; the code calculation, material certifications and testing records are long gone. The good news is that a vessel’s drawing is enough for a fabricator to provide you with an adequate bid — keep in mind, though, many of the fabrication practices and materials of the past are now obsolete. If documentation can’t be found, there are alternatives you can explore in lieu of starting from scratch.

Perhaps the original fabricator still has the print. For ASME-stamped equipment, fabricators are required to retain what’s called the “Manufacturer’s Data Package” for five years, though many will hold on to this information much longer. However, over the last 20-plus years, substantial consolidation and attrition have reshaped the vessel industry. So, while it’s worth trying, realistically you may find recovering information this way futile.

Your last chance for digging up old information is contacting the National Board in Columbus, Ohio. Besides training and accrediting code inspectors and auditing code stamp holders, it stores decades of manufacturers’ data reports (U-1 forms). A data report is much like the birth certificate of the vessel; it provides a wealth of information, such as major dimensions, materials of construction, shell and head thicknesses, nozzle construction, radiography and hydrotest pressure. To find out if the U-1 form is available, first check the vessel’s code nameplate in the field. If there’s a NB number stamped on it (or on the drawing), simply call the National Board, provide this number and the manufacturer’s name, and within days, for a nominal fee (i.e., $20 to $50), you’ll have the data form faxed to you. (Same day service is available for a small additional fee.)

Such difficulties teach an important lesson. Be sure when purchasing vessels to include any special information (e.g., company purchase order, equipment number, special heat treatment or nondestructive evaluation) somewhere on the drawing because 20-plus years from now, a drawing may be all your successor is able to locate. Also, register and archive your vessel with the National Board — most states require registration [1], but it’s good practice even where not mandated. The cost is typically less than $50 and your fabricator will handle the registration.

7. More (radiography) is less (metal). The continuing climb in alloy prices necessitates a paradigm shift in thinking. It’s becoming more economical to specify more radiography (i.e., X-raying), not so much for joint quality but to reduce wall thicknesses.

Vessel data sheets require the engineer to specify the amount of radiography required for the service. Typically the choices are “full,” “spot” or “none.” This tells the fabricator how much X-raying it should estimate for the job but, more importantly, it affects the required shell and head thicknesses based on ASME code rules. The ASME Code recognizes two types of “full” radiography, RT-1 and RT-2. RT-2 vessels provide the best balance in terms of risk and design economy [2].

“Full radiography” indicates to the fabricator that “all” pressure-retaining butt joints in the main vessel (excluding small diameter and thin wall nozzles) are to be X-rayed. This can be costly but actually can provide substantial savings when fabricating vessels from expensive materials by avoiding any penalty in vessel shell/head thickness. In ASME Code terms, this amount of X-raying is referred to as “RT-1” (Figure 2) and is stamped as such on the code nameplate.

Full radiography often is confused with 100% radiography, with the later requiring X-raying of all butt welds, including small diameter and thin wall nozzles. Lethal services require 100% radiography. A savvy designer knows the difference and may specify 100% in non-lethal services where process reliability is crucial (e.g., continuous processes vs. batch) or where accessibility to certain joints will be restricted and hamper future repairs (e.g., jacketed designs).

“Spot radiography” is a common choice in the chemical industry for normal service fluids. It involves a 6-in. shot for every 50-ft. of weld seam at locations specified in the code and incurs only a slight, 15%, wall thickness penalty. ASME designates this as “RT-3.” On small and low hazard vessels, often no radiography or “none” is specified; this will increase the wall thickness another 15% (i.e., 30% thicker than for full X-ray).

RT-2, which is a hybrid between RT-1 and RT-3, seldom is specified by owners but offers economic advantages by permitting thinner wall vessels (Table 1). All long seams are fully X-rayed (similar to RT-1) and the longer circumferential seams are only spot X-rayed (similar to RT-3) with one extra quality shot at the T-junctions (Figure 2). Why RT-2? The long seam is stressed two times higher than circumferential seams for most vessels where wind load doesn’t govern design (i.e., vessels under 50-ft. tall). So, have your fabricator quote an optional price for RT-2 on vessels constructed of alloy materials. A vessel engineer can work you through the rules.