Atmospheric Water Generation

VENTRONAWG

Industrial Atmospheric Water Generation System

A modular, high-capacity water-from-air machine engineered to transform humid ambient air into clean, treated water.

Target capacity 0 L/day

Performance depends on humidity, temperature, airflow, and final engineering validation.

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System overview

Built for decentralized
water production.

VENTRON AWG produces clean water directly from ambient air. Its high-capacity modular mechanical architecture targets up to 6,000 liters per day under suitable operating conditions.

01 6,000

L/day Target Output

02 04

Modular Condensation Sections

03 24/7

Smart Industrial Control

Air to water

How VENTRON AWG works.

Humid air enters through the large X-frame side intake, then moves through filtration, air processing, cooling, and condensation. Below its dew point, airborne moisture becomes liquid water.

01

Air Intake

High-volume ambient capture
Ambient captureVariable-speed EC fans draw humid air through the X-frame face.
02

Filtration

Dust and particle removal
Protected airflowLayered media removes dust and airborne particulates before cooling.
03

Condensation

Air cooled below dew point
Dew-point coolingCoils extract heat until airborne moisture becomes liquid water.
04

Collection

Stainless drain architecture
Gravity collectionCondensate falls into stainless steel trays and the raw-water tank.
05

Treatment

Multi-stage purification
Water treatmentFiltration, UV sterilization, mineralization, and quality monitoring.
06

Storage

Monitored clean water tank
Controlled storageClean water is held in a sensor-monitored hygienic storage tank.
07

Outlet

Pressure-controlled delivery
Pressure deliveryThe outlet pump delivers clean water through the final pressure line.
Ambient RH68% Dew Point23.4°C Airflow92% Water QualityOptimal

Intake architecture

Large X-Frame
Air Intake.

The X-shaped side section is the primary air intake—moving large volumes of air while protecting internal systems through louvers, dust mesh, and filtration layers.

  • High-volume side airflow
  • Protective louver system
  • Dust mesh and pre-filtration
  • Strong visual product identity
  • Industrial-scale air movement
Intake velocity4.8 m/s Filter conditionOptimal
VENTRON / X-FRAME CUTAWAY / REV.02

Air processing

Controlled air processing.

Inside the processing chamber, air passes through filtration and pre-conditioning stages before reaching the condensation modules.

AIR PATH / CHAMBER 01CONTROLLED FLOW
ACTIVE COMPONENT
01 / Pre-filterCoarse particle capture · >100 μm
02 / Dust filterFine particulate protection · ΔP 38 Pa
03 / Carbon + MERVEnhanced air-quality media · Optional
04 / Heat exchangerAir pre-conditioning · Coil 12.6°C
05 / EC fansVariable-speed airflow · 1,240 RPM
Airflow92%Fan speed1,240 rpmPressure drop38 PaFilterOptimal

Captures larger airborne particulates at the first stage.

COARSE CAPTURE / >100 μm

Protects downstream coils and mechanical components.

FINE MEDIA / ΔP MONITORED

Configurable enhanced filtration for site-specific air quality.

OPTIONAL MEDIA / SITE CONFIGURED

Conditions incoming air before the main cooling stage.

THERMAL CONDITIONING / 12.6°C

Electronically controlled airflow tuned to operating conditions.

VARIABLE SPEED / 1,240 RPM

Modular capacity

Four independent
condensation modules.

Four serviceable modules each contribute approximately 1,500 liters per day toward the combined target capacity.

4×1,500 L/day=0 L/day
4 / 4 MODULES ONLINESELECT A MODULE TO SIMULATE SERVICE ISOLATION

RESILIENCE // All four independent modules are producing water at full target capacity.

Thermal separation

Industrial refrigeration architecture.

The refrigeration system supplies the cooling energy required to condense airborne moisture, while physically separating heat rejection from cold air processing.

ZONE / A

Cold Zone

−°
  • Expansion valves
  • Cooling coils
  • Cold air chamber
ZONE / B

Hot Zone

  • Compressors
  • Condensers
  • Hot-air exhaust

Engineering principleThe hot side is isolated from the air-processing zone to prevent recirculation and preserve efficient water production.

CONDENSATE TRAY
RAW WATER
TANK
LEVEL 72%
SENSOR
ONLINE

Water collection

Stainless steel
water collection.

Condensed water falls into stainless steel collection trays and flows to a raw water tank before sensor-monitored transfer to the treatment system.

  • Stainless steel collection trays
  • Gravity-assisted water flow
  • Raw water collection tank
  • Sensor-monitored transfer
  • Direct treatment routing

Purification

Integrated water treatment.

Raw condensate passes through a multi-stage treatment system before entering clean water storage.

Water qualityOK
  • TDS Monitoring48 ppm
  • UV SterilizationACTIVE
  • Filter StatusOPTIMAL
01

Sediment filtration

02

Carbon filtration

03

UV sterilization

04

Mineralization cartridge

05

Polishing filter

06

TDS / quality monitoring

Clean, treated water ready for controlled storage and outlet pumping.

Pressure delivery

Clean water storage &
pressure delivery.

Positioning the outlet pump close to clean water storage reduces pressure losses and simplifies final outlet routing.

SYSTEM STANDBYHYDRAULIC DELIVERY CIRCUIT / ILLUSTRATIVE VALUES
72%
01 / STORAGE

Clean Water Tank

Sensor-monitored reserve
02 / PRESSURIZE

Close-Coupled Pump

Positioned beside storage
bar04
03 / CONTROL

Pressure Line

Monitored delivery pressure
04 / DELIVERY

Water Outlet

Demand-controlled supply
PumpStandby Pressure0.0 bar Flow0 L/min Tank level72%
Pump routeClose-coupled Pressure lossMinimized Service accessClear

Intelligence

Smart HMI and
IoT-ready control.

Real-time monitoring, diagnostics, production tracking, alerts, predictive maintenance, and water-quality data in one industrial control layer.

  • HMI touchscreen
  • Remote monitoring readiness
  • System diagnostics
  • Predictive maintenance support
VENTRON / CONTROL28 JUN 2026   14:42
DAILY PRODUCTION0 L
MODULE STATUS
M1M2M3M4
AIRFLOW92%
TANK LEVEL72%
WATER QUALITYOPTIMALTDS 48 PPM
MAINTENANCENO ALERTSNEXT SERVICE 312 H

System advantages

Engineered as a complete
water platform.

VENTRON AWG / SYSTEM ARCHITECTURESELECT A SUBSYSTEM TO INSPECT
ENCLOSURE
INTAKE
M1  M2  M3  M4
THERMAL
TREATMENT
HMI
IoT
ACCESS
6,058 mm / SYSTEM LENGTHVENTRON AWG / GENERAL ARRANGEMENT / REV.03

Supporting energy

VENTRON Energy
Ecosystem.

AWG + Solar + Wind + Storage

VENTRON ENERGY is built around atmospheric water generation, supported by a wider energy ecosystem designed to improve resilience, reduce grid dependency, and enable cleaner water production in remote, commercial, and industrial environments.

Supporting energy02

Solar Power

Renewable solar energy integration to support AWG operation and reduce dependency on conventional power sources.

AWG support
Supporting energy03

Wind Power

Wind energy support for hybrid renewable configurations in suitable locations.

AWG support
Supporting energy04

Power Storage

Battery storage systems designed to stabilize power supply and support continuous operation.

AWG continuity

Deployment

Designed for critical
water applications.

For locations where conventional water infrastructure is limited, expensive, delayed, or unreliable.

VENTRON DEPLOYMENT NETWORK8 APPLICATION PROFILES
0102030405060708 ABSTRACT DEPLOYMENT TOPOLOGY / NOT GEOGRAPHIC

The future of water

VENTRON AWG

Modular industrial atmospheric water generation—combining high-volume airflow, controlled condensation, integrated treatment, and smart monitoring for decentralized water production.