Most HVAC installation instructions require flowing nitrogen through the copper tube during brazing. This is an important step in producing a quality HVAC system and nitrogen purging and brazing.

Why nitrogen purge?
Oxygen in the air combines with copper to form surface copper oxide. We see this on copper tube as a light to dark brown discoloration. You’ve probably seen ACR/medical gas copper tube supplied from the tube mill nitrogen charged and capped. This is designed to prevent this oxide formation inside the tube. Once the caps are removed and the tube is cut for installation, the nitrogen protection is lost.

At high brazing temperature a heavier black oxide forms (cupric oxide). On cooling this oxide flakes off to form “scale”.

Nitrogen Purging and Brazing
copper tube brazing scale

Figure 1: copper tube brazing scale (click to enlarge)

While mostly cosmetic on the tube exterior, inside the tube the oxide flakes are carried by the refrigerant through the system. This contaminant can restrict flow through small orifices such as metering devices or the pilot valve capillary tube in a reversing valve.

inside oxidation scale from 5/8" tube
inside oxidation scale from 5/8″ tube

Figure 2: inside oxidation scale from 5/8″ tube (click to enlarge)

This problem has long been an issue in brazing HVAC tube. It has become more important with the change from HCFC refrigerants like R-22 that use mineral oil to the new HFC refrigerants (410a) using POE oils. Due to their polar nature, POE oils have a solvent effect and can “scrub” the copper tube walls. Oxide from tube walls and loose scale can circulate through the system.

What’s the procedure?
To prevent oxidation, flow dry nitrogen through the tube during brazing. Nitrogen is inert, (non- reactive), and will displace the oxygen to prevent scale formation.

nitrogen purged tubes at top
nitrogen purged tubes at top

Figure 3: nitrogen purged tubes at top, no nitrogen purge at bottom (click to enlarge)

Nitrogen is typically introduced into the system throughout the Schrader valve (after removing the core), or other system openings.

Harris nitrogen regulator
Harris nitrogen regulator

Figure 4: Harris nitrogen regulator (click to enlarge)

Connect a hose or tube from the nitrogen cylinder to one end of the pipe. The cylinder will be equipped with a regulator or flow control valve. There is no universal requirement for the delivery pressure setting, but the goal is to use low volume/pressure to displace the oxygen. A suggested starting point is 2 -3 CFH or 1.5 – 2 PSI. Some users will set pressure until they feel a slight flow at the exit point on the back of their hand. It’s good practice to initiate flow before heating and continue to flow nitrogen until the part has cooled.

Avoid an excessive flow rate that builds pressure inside the tube. A high flow rate will tend to cool the tube reducing brazing heat efficiency. Excess nitrogen pressure can build up inside the tube and reduce braze alloy penetration. A small hole in a cap at the end of the line will allow the nitrogen to escape.

It’s a good idea to experiment with flow rates by test brazing parts on the bench. Section the finished assemblies and inspect for a clean inner tube wall.

****I was about to write a blog post on proper brazing techniques but ran across this excellent post from Harris Products Group. Their explanation of how and why you must purge with nitrogen is spot on! The original post can be found here

Ron Walker
Ron Walker

After retiring from the U.S. Marines and achieving his B.S. degree, Ron Walker entered the HVAC field. He has been an HVAC technician, service manager, and business owner. Working as a service manager, he spent many years training HVAC technicians to be more technically competent and really understand their trade. His passion for teaching and helping others resulted in the creation of HVAC Training Solutions, LLC.