Air supply, Air inlet & priming – SANDPIPER ET3 - M User Manual

Model ET3-M Type 1 Page 4

et3dl1sm-rev0614

AIR SUPPLY

Air supply pressures cannot exceed 125 psi (8.61 bar). Connect the pump air inlet

(see Fig. 1) to an air supply of sufficient capacity and pressure required for desired

performance. When the air line is solid piping, use a short length of flexible hose (not

less than ¾" [19mm] in diameter) between pump and piping to eliminate strain to pipes.

AIR INLET & PRIMING

For start-up, open an air valve approximately ½ to ¾ turn. After the unit primes, an air

valve can be opened to increase flow as desired. If opening the valve increases cycling

rate, but does not increase flow rate, cavitation has occurred, and the valve should be

closed slightly.

For the most efficient use of compressed air and the longest diaphragm life, throttle

the air inlet to the lowest cycling rate that does not reduce flow.

A NOTE ABOUT AIR VALVE LUBRICATION

The SandPIPER pump’s pilot valve and main air valve assemblies are designed

to operate WITHOUT lubrication. This is the preferred mode of operation. There may

be instances of personal preference, or poor quality air supplies when lubrication of

the compressed air supply is required. The pump air system will operate with properly

lubricated compressed air supplies. Proper lubrication of the compressed air supply

would entail the use of an air line lubricator (available from Warren Rupp) set to deliver

one drop of 10 wt., non-detergent oil for every 20 SCFM of air the pump consumed at its

point of operation. Consult the pump’s published Performance Curve to determine this.

It is important to remember to inspect the sleeve and spool set routinely. It should

move back and forth freely. This is most important when the air supply is lubricated. If a

lubricator is used, oil accumulation will, over time, collect any debris from the compressed

air. This can prevent the pump from operating properly.

Water in the compressed air supply can create problems such as icing or freezing

of the exhaust air causing the pump to cycle erratically, or stop operating. This can be

addressed by using a point of use air dryer (available from Warren Rupp) to supplement a

plant’s air drying equipment. This device will remove excess water from the compressed

air supply and alleviate the icing or freezing problem.

ESADS: EXTERNALLY SERVICEABLE AIR

DISTRIBUTION SYSTEM

Please refer to the exploded view drawing and parts list in the Service Manual

supplied with your pump. If you need replacement or additional copies, contact your

local Warren Rupp Distributor, or the Warren Rupp factory Literature Department at the

number shown below. To receive the correct manual, you must specify the MODEL and
TYPE information found on the name plate of the pump.

MODELS WITH 1" SUCTION/DISCHARGE OR LARGER, AND

NON-METAL CENTER SECTIONS

The main air valve sleeve and spool set is located in the valve body mounted on the

pump with four hex head capscrews. The valve body assembly is removed from the

pump by removing these four hex head capscrews.

With the valve body assembly off the pump, access to the sleeve and spool set is

made by removing a retaining ring (each end) securing the end cap on the valve body

assembly. With the end caps removed, slide the spool back and forth in the sleeve.

The spool is closely sized to the sleeve and must move freely to allow for proper pump

operation. An accumulation of oil, dirt or other contaminants from the pump’s air

supply, or from a failed diaphragm, may prevent the spool from moving freely. This can

cause the spool to stick in a position that prevents the pump from operating. If this is

the case, the sleeve and spool set should be removed from the valve body for cleaning

and further inspection.

Remove the spool from the sleeve. Using an arbor press or bench vise (with an

improvised mandrel), press the sleeve from the valve body. Take care not to damage

the sleeve. At this point, inspect the o-rings on the sleeve for nicks, tears or abrasions.

Damage of this sort could happen during assembly or servicing. A sheared or cut

o-ring can allow the pump’s compressed air supply to leak or bypass within the air

valve assembly, causing the pump to leak compressed air from the pump air exhaust

or not cycle properly. This is most noticeable at pump dead head or high discharge

pressure conditions. Replace any of these o-rings as required or set up a routine,