Hydraulic Fittings and Hydraulic Flanges
Among the basic elements of virtually every hydraulic system is a series of fittings flanges for connecting tube, pipe, and hose to pumps, valves, actuators, and other components.
If the components within hydraulic systems never had to be removed, connections could be brazed or welded to maximize reliability. However, it is inevitable that connections must be broken to allow servicing or replacing components, so removable fittings are a necessity for all but the most specialized hydraulic systems. To this end, fitting designs have advanced considerably over the years to improve performance and installation convenience, but the overall function of these components remains relatively unchanged.
Fittings seal fluid within the hydraulic system by one of two techniques: all-metal fittings rely on metal-to-metal contact, while O-ring type fittings contain pressurized fluid by compressing an elastomeric seal. In either case, tightening threads between mating halves of the fitting (or fitting and component port) forces two mating surfaces together to form a high-pressure seal.
Threads on pipe fittings are tapered and rely on the stress generated by forcing the tapered threads of the male half of the fitting into the female half or component port (Fig. 1). Pipe threads are prone to leakage because they are torque-sensitive—over-tightening distorts the threads too much and creates a path for leakage around the threads. Moreover, pipe threads are prone to loosening when exposed to vibration and wide temperature variations—certainly no strangers to hydraulic systems.
Seepage around threads should be expected when pipe fittings are used in high-pressure hydraulic systems. Because pipe threads are tapered, repeated assembly and disassembly only aggravates the leakage problem by distorting threads, especially if a forged fitting is used in a cast-iron port. Thread sealant compound, a potential contaminant, is recommended for pipe fittings, which is still another reason why most designers consider them to be obsolete for use in hydraulic systems.
Flare-type fittings (Fig. 2) were developed as an improvement over pipe fittings many years ago and probably remain the design used most often in hydraulic systems. Tightening the assembly's nut draws the fitting into the flared end of the tubing, resulting in a positive seal between the flared tube face and the fitting body. The 37-deg. flare fittings are designed for use with thin-wall to medium-thickness tubing in systems with operating pressures to 3,000 psi. Because thick-wall tubing is difficult to form to produce the flare, it is not recommended for use with flare fittings. The 37-deg. flare fitting is suitable for hydraulic systems operating at temperatures from −65° to 400° F. It is more compact than most other fittings and can easily be adapted to metric tubing. It is readily available and one of the most economical.
The flareless fitting (Fig. 3), gradually is gaining wider acceptance in the U.S. because it requires minimal tube preparation. It handles average fluid working pressures to 3,000 psi and is more tolerant of vibration than other types of all-metal fittings. Tightening the fitting’s nut onto the body draws a ferrule into the body. This compresses the ferrule around the tube, causing the ferrule to contact, then penetrate the outer circumference of the tube, creating a positive seal. Because of this, flareless fittings must be used with medium- or thick-walled tubing.
Surprising as it may seem, leakage in hydraulic systems could have been eliminated more than a couple generations ago. Although leak-free hydraulic operation had always been desirable, the need became more acute with higher operating pressures that became necessary during World War II, primarily in the hydraulic systems of military aircraft. Until then, common operating pressures had hovered around 800 to 1,000 psi. The post-war era ushered in systems designed to operate at pressures to 1,500 psi and higher on applications where rapid cycling and high shock pressures were present. It was not long until pressures climbed to 2,500 and 3,000 psi—which certainly are not uncommon today.
Fittings that use O-rings for leak-tight connections continue to gain acceptance by equipment designers around the world. Three basic types now are available: SAE straight-thread O-ring boss fittings, face seal or flat-face O-ring (FFOR) fittings, and O-ring flange fittings. The choice between O-ring boss and FFOR fittings usually depends on such factors as fitting location, wrench clearance, or individual preference. Flange connections generally are used with tubing that has an outside diameter (OD) greater than 7/8-in. or for applications involving extremely high pressures.
O-ring boss fittings seat an O-ring between threads and wrench flats around the OD of the male half of the connector (Fig. 4). A leak-tight seal is formed against a machined seat on the female port. O-ring boss fittings fall into two general groups: adjustable and non-adjustable. Non-adjustable (or non-orientable) fittings include plugs and connectors. These are simply screwed into a port, and no alignment is needed. Adjustable fittings, such as elbows and tees, need to be oriented in a specific direction.