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Air Receivers

Print Date: 10/20/2017 3:47:37 AM

Description and Overview
An air receiver is probably the most common type of unfired pressure vessel. However, due to minimum size inspection thresholds employed by the vast majority of jurisdictions, many of the smaller air receivers will not qualify for a mandatory inservice inspection. The typical inspection threshold sizes referenced in jurisdictional regulations are 5 cubic feet or 15 cubic feet in volume as long as the maximum allowable working pressure (MAWP) does not exceed 250 psi, or 1-½ cubic feet in volume as long as the MAWP does not exceed 600 psi. The inspector must review the jurisdiction's inspection requirements to ensure compliance with the appropriate size and pressure limitations.

Air receivers are typically constructed in accordance with ASME BPV Code Section VIII, Div. 1, and stamped with either the ASME "U" or "UM" designator. Manufacturers who specialize in air receivers will construct a large number of these vessels in an assembly line process. The Manufacturer's Data Report, for "U" designated vessels, and the Manufacturer's Certificate of Compliance, for "UM" designated vessels, may include multiple vessels. This practice is described in ASME BPV Code Section VIII, Div. 1, paragraph UG-120(a).

While most air receivers are of simple design consisting of a shell and two dished heads, some are designed to incorporate a filter or separator element within the vessel. These vessels may be "T" shaped with one bolted flat head which provides access to the filter or separator element. These uniquely shaped vessels are commonly found in use with large industrial air compressors.

Air receivers will be installed in any facility requiring a reservoir of compressed air. Compressed air uses include:

The design of a compressed air system is dictated in part by the pressure, volume, and air quality (including cleanliness and dryness) needed in any given industry or process. The size of the air receiver in the system is normally based on the volume of air produced by the compressor and the user's desire for a stated capacity in cubic feet per minute (cfm) at a specified pressure. The air receiver helps in maintaining a constant pressure in the system by minimizing the fluctuations of a compressor cycling on and off.

Appurtenances, Settings, and Piping
An air receiver must be protected from over-pressure. This is usually accomplished by means of a spring-loaded pressure relief device. The set pressure of the pressure relief device must not exceed the MAWP marked on the air receiver. The minimum relieving capacity of the pressure relief device must meet the requirements of ASME BPV Code Section VIII, Div. 1, paragraph UG-125. Under most circumstances this would require a pressure relief device with enough relieving capacity to prevent the pressure in the air receiver from rising more than 10% or 3 psi, whichever is greater, above the MAWP marked on the air receiver. For an inspector familiar with boiler nameplates which indicate either the maximum generating capacity of the boiler or the minimum required relief valve capacity, verifying the capacity of a pressure relief device on an air receiver will be more of a challenge. The inspector needs to obtain the output of the compressor(s) supplying the air receiver. This information may be on a label or nameplate on the compressor or it may have to be obtained from the compressor manufacturer's published specifications.

Since air receivers are typically constructed out of carbon steel, they are subject to internal corrosion from water which has condensed from the compressed air. ASME BPV Code Section VIII, Div. 1, paragraph UG-25(f), requires a suitable drain opening in such vessels.

Air receivers with integrally mounted compressors and motors should be installed as recommended by the manufacturer. Since there is usually some vibration produced by a reciprocating-type compressor/motor unit, many manufacturers provide spring-loaded or elastic compound dampers to mount between the floor and the air receiver base.

Clearance measurements, if any, must comply with all jurisdictional and manufacturer requirements.

Most jurisdictions do not require inspection of any piping associated with an air receiver.

Part 1 of the National Board Inspection Code addresses installation requirements and must be followed when mandated by the applicable jurisdiction.

Common Observations and Problems
Internal corrosion, vibration, and external impact damage are the most common problem areas for air receivers.

Unless the air compressor is operating in the driest desert, water vapor in the compressed air will condense to liquid water as the temperature of the compressed air falls. In the simplest system, this happens in the air receiver. In more elaborate systems, the air is conditioned to extract part or almost all of the moisture before entering the air receiver. One compressor manufacturer's informational literature claims the water vapor content at 100°F of saturated compressed air equals about two gallons per hour for each 100 cfm of compressor capacity. Some air receivers are fitted with automatic condensate drains while others rely on a manually operated drain valve. If condensate is allowed to collect in the air receiver, its volume is decreased which can lead to increased cycling by the compressor. The condensate can also carryover through the air distribution lines and cause problems with air powered tools. The most detrimental effect of the condensate is internal corrosion of the air receiver. Since it is internal, it is never seen by the vessel owner and its effects are often discounted or ignored. In severe cases of corrosion, the vessel thickness may have decreased below the minimum wall thickness necessary for the MAWP stamped on the vessel. Under those circumstances, the MAWP can be decreased to a point that is supported by the remaining wall thickness, but in most cases the vessel is removed from service until it is repaired or replaced.

Vibration caused by an integrally mounted compressor/motor unit can cause cracking in the welds attaching the compressor/motor mount to the air receiver or in the welds attaching the base to the bottom of the air receiver. If they occur, the cracks will often "run" or propagate into the vessel material. Vibration damage can also occur where rigid piping is connected to the air receiver.

External impact damage can be caused by vehicles, machinery, or objects hitting the air receiver. One inspector observed a large dent in an external air receiver mounted on a portable air compressor used in a quarry. He was told it was caused by a limestone boulder which fell on the compressor from an upper rock ledge. Hazards can exist almost anywhere.

Most air receivers will show a minimum design metal temperature (MDMT) of -20°F on the nameplate. This should be acceptable under most conditions. However, if the air receiver is installed outside or in an unheated structure in very cold climates, it could be susceptible to brittle fracture.

Upon entering the area where the air receiver is operating, the inspector should perform a general assessment of the air receiver, piping, and associated systems. The inspector should then:

The inspector should perform an internal inspection of the air receiver as required by the jurisdiction. Some air receivers have dedicated inspection openings while others (especially smaller ones) use the inspection openings for the attachment of piping, instruments or similar attachments as allowed by ASME BPV Code Section VIII, Div. 1, paragraph UG-46(f)(7). If an internal inspection is impractical, the jurisdiction may accept thickness readings obtained with an ultrasonic tester compared with original thickness values. The original thickness values can be found on the Manufacturer's Data Report or Manufacturer's Certificate of Compliance. Although the practice is not required by ASME BPV Code, some air receiver manufacturers include the shell and head thicknesses on the nameplate.

Miscellaneous Information
Additional information to aid inspectors of air receivers can be found in the following publications and sources: