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Stainless steel membrane modules with insulated piping.

VMD · Technology

Vacuum Membrane Distillation

Vacuum membrane distillation drives separation with a vapor pressure gradient instead of a hydraulic one. A vacuum on the permeate side pulls water vapor through a hydrophobic membrane, leaving everything that is not volatile behind. The result: recovery rates above 95% on feeds that defeat reverse osmosis, with one-third the energy of conventional evaporation.

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What it solves

Performance you can size against.

The outcomes below come from commissioned systems and verified pilots, not theoretical limits. Every number is independently testable on your own feed.

Maximum feed TDS
Up to 250,000 mg/L
Far beyond the 60,000 to 80,000 mg/L practical limit of reverse osmosis.
Water recovery on tested feeds
95 to 99%
Approaching ZLD without the energy of phase change.
Operating temperature
60 to 80°C
Low-grade heat works, including waste heat from upstream processes.
Footprint
1/3 of evaporators
Skid-mounted modules that retrofit into existing facility envelopes.

How it works

The working principle.

A hot, salty feed flows through the lumen of hydrophobic hollow-fiber or flat-sheet membranes. Vacuum on the shell side drops the vapor pressure, drawing water vapor through the membrane pores while liquid water and dissolved solids are blocked by the membrane's hydrophobicity. Vapor condenses downstream as clean distillate. Salts, metals, organics, and suspended solids stay in the brine, which can be cycled back through the loop until the desired concentration is reached.

Process diagram
Custom SVG to be added in design phase

Performance envelope

Specs and operating range.

For preliminary sizing only. Production sizing is always validated against your specific feed.

Recovery
95 to 99%
Maximum feed TDS
250,000mg/L
Permeate quality
<10mg/L TDSIndependently verified on tested feeds.
Operating temperature
60 to 80°C
Operating pressure
Vacuum, 5 to 50mbar
Specific energy
150 to 250kWh/m³Compared to 250 to 600 kWh/m³ for evaporation.
Membrane life (typical)
3 to 5years
Footprint per m³/day
1.5 to 3

How we compare

VMD vs the alternatives.

Where Vacuum Membrane Distillation wins, where it does not, and where the alternatives are honestly the better fit.

Maximum feed TDS

VMD

Up to 250,000 mg/L

Reverse Osmosis

60,000 to 80,000 mg/L

Mechanical Vapor Recompression

Up to 350,000 mg/L

Specific energy

VMD

150 to 250 kWh/m³

Reverse Osmosis

3 to 8 kWh/m³ (low TDS only)

Mechanical Vapor Recompression

20 to 35 kWh/m³

Tolerance to fouling

VMD

High; hydrophobic membrane resists organic fouling

Reverse Osmosis

Low; pretreatment cascade required

Mechanical Vapor Recompression

Moderate; scale management critical

Capex per m³/day capacity

VMD

Mid-range

Reverse Osmosis

Low (when feed permits)

Mechanical Vapor Recompression

High

Best fit

VMD

High-salinity, high-organic, ZLD-bound feeds

Reverse Osmosis

Low-TDS feeds with stable composition

Mechanical Vapor Recompression

Concentrated brines ahead of crystallization

Where it's deployed

Industries that use this process.

Vacuum Membrane Distillation fits some sectors better than others. The industries below are where we have shipped multiple systems.

Oil & Gas

Produced water, frac flowback, solvent recovery.

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Mining

Tailings concentration, lithium recovery, zero liquid discharge.

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Water & Wastewater

Municipal wastewater, leachate, hard-to-treat brines.

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Engineering FAQ

Questions engineers ask.

Five we hear weekly. If you have a different one, send it with your consultation request and we will answer it directly.

Can VMD handle silica?
Yes. Hydrophobic membranes are far less sensitive to silica scaling than RO. We have run feeds with 200 mg/L silica without anti-scalant pretreatment.
What about feeds with hydrocarbons or oil?
Trace hydrocarbons (under 10 mg/L) are tolerated. Above that, we typically include an upstream coalescer or activated carbon column. We pilot every feed before sizing the production system.
How does VMD compare to reverse osmosis on cost?
On low-TDS feeds, RO is cheaper to operate. As TDS climbs above 60,000 mg/L, RO recovery drops sharply and pretreatment cost rises. Above 80,000 mg/L, VMD is usually cheaper on lifetime cost. Above 100,000 mg/L, RO is not an option.
Can the system run on waste heat?
Yes, and many do. VMD operates at 60 to 80°C. Waste heat from compressors, boilers, and process streams in that range can run the system at marginal energy cost.
What is the membrane lifetime?
Typical 3 to 5 years on real industrial feeds. Replacement is module-by-module, not full system, so plants stay online during replacement.

Have a feed that VMD
might fit?

We will pilot before we promise. Send us a sample and a target outcome. If the technology fits, we will tell you what to expect; if it does not, we will tell you that too.

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