Water Injected Oil Free Screw Compressors – Air Compressor Manufacturers

Oil-flooded screw machines inject oil into the compression chamber, dry oil-free injects nothing and toughs it out on clearances, water-lubricated oil-free injects water. That's the essential difference between the three approaches, simple as that.

Oil-flooded machines still have few ppm residual oil after oil separation; general industrial use doesn't care about that bit of oil. Dry oil-free rotors have clearances down to 0.05mm, surfaces coated with Teflon or ceramic, heat only gets removed through external water jacket or air cooling. Water-lubricated machines spray water into compression chamber; water blocks clearances and carries away heat, but rotors and housing must be stainless or they rust through.

Water-lubricated approach separately

Technology

Water Injection System

Component

Air-Water Separator

Component

Water Cooler Circuit

Water sprays into compression chamber through injection port, mixes with air and gets compressed together, exits into air-water separator where water spins out, water goes through cooler to drop temp and filter to remove contaminants then pumps back for recirculation.

7-10bar

Single Stage

40-50°C

Discharge Temp

~60dB

Noise Level

170-180°C

Dry Machine Temp

Water-lubricated machines can hit 7 bar or even 10 bar single-stage; dry machines at same pressure usually need two stages in series. That difference shows up big in equipment cost and footprint. Reason is water absorbs compression heat, keeps gas temp low so single-stage ratio can go higher. Dry machines have nothing in chamber to absorb heat; temp shoots up, efficiency tanks, can only compress slowly in two stages. Discharge temp from water-lubricated is 40-50°C; dry single-stage is 170-180°C with intercoolers between stages to bring it down. Noise from water-lubricated around 60 decibels; dry 70-80 decibels. That 10-20 decibels near hospitals and office buildings is can install vs can't install difference. Energy efficiency of water-lubricated is same tier as oil-flooded; dry takes hit due to two-stage setup and high-speed operation.

Dry machines have their strengths too. Pressure can go higher; current mainstream water-lubricated products top out around 10 bar, above that only dry or oil-free piston. Maintenance also simpler without liquid in compression chamber, no worrying about water quality stuff.

Water quality management is tied-in homework for water-lubricated machines

Expanding on this because lots of factories trip here after buying water-lubricated machines.

In areas with hard tap water, calcium and magnesium ions scale on heat exchange surfaces. Thicker scale layer, worse heat transfer, discharge temp slowly creeps up, energy use follows. Some factories only discover after two or three years that energy use is noticeably higher than when new; open it up and water circuit is full of white scale. pH skewing acid or alkaline corrodes stainless steel; despite the name, prolonged soaking in wrong water still causes problems, pitting eventually shows up.

Solutions: either install softening equipment to drop hardness, or just use purified water. Circulating water should have conductivity and pH tested regularly; conductivity keeps rising means dissolved solids accumulating, time to change water. pH deviating from normal needs investigation. No standard answer for water change interval; hard water area, machine running hard, maybe every two to three months; good water quality, light use, six months might be fine. Figure out your own pattern. Filter elements in water circuit gradually clog; resistance up, flow down, affects cooling.

Circulating water temp stays 30-40°C year round; warm and humid, bacteria grow easy. Food and pharma industries sensitive to microbial contamination, water circuit disinfection needs taking seriously.

Low temp environments basically rule out water-lubricated machines

Below 5°C, circulating water risks freezing. Northern winters outside, near cold storage, unheated factory buildings; installing preheating adds cost and failure points, better to just pick dry from the start. This constraint must be confirmed first when selecting; temp doesn't work, discussing efficiency and noise later is pointless.

Who typically picks water-lubricated machines

Application

Medical Facilities

Application

Electronics Cleanrooms

Hospital air supply stations need oil-free for ORs and ICUs, plus quiet. 7-8 bar pressure is right in water-lubricated comfort zone. Electronics plant cleanrooms need oil-free mandatory and are energy-sensitive with machines running long, water-lubricated saves power vs dry. Food and beverage filling lines where compressed air touches product can't have oil, managing circulating water properly handles microbial control. Textile plant air-jet looms use big air volumes, need oil-free to prevent oil spots causing fabric defects. Labs can't put noisy equipment next to instruments.

If process has no oil requirement, still pick oil-flooded; cheap, robust, simple maintenance. Need oil-free plus high pressure or environment below freezing, dry machines are the right path. Need oil-free plus care about power bills and noise, pressure not over 10 bar, water-lubricated fits. Both oil-free types with complete filtration and drying downstream can match air quality; Class 0 is result of whole air path working together, not main unit alone deciding.

Maintenance

Check liquid level daily; low level causes discharge temp to climb, severe cases rotor overheating damage. Sudden discharge temp display jump often means something went wrong. Remember to open condensate drain at separator bottom.

Circulating water stuff covered earlier; test conductivity and pH regularly, clean or swap clogged filter elements, listen to pump sound, watch pressure.

Do thorough inspection annually: rotor coating worn through to base, seals aged, water circuit dead corners scaled up.