Reverse Osmosis System
RO systems often fail due to incorrect membrane selection and poor pre-treatment. That means higher costs and constant downtime.
What We Do Differently
- Study Input We study your Water Parameters
- Select membranes and recovery rates based on your use
- Engineered for high energy- efficiency and high- recovery designs
- Add antiscalant dosing and inline flushing for membrane health
- Automate flushing, backwash, and alerts
What You Get with Inovar
Up to 99% TDS removal
Longer membrane life with reduced fouling
Modular RO skids for quick installation
Minimal manual intervention
Smart dashboard with performance logs
Chemical Dosing
Best suited for
Post Treatment for Effluent Treatment Plant
Process industries needing high-purity water
Drinking water systems
RO-based reuse or polishing setups
Desalination and Pre-treatment of ZLD
Boiler feed water
After Installation, We Stay Involved
Membrane cleaning support and schedules
Chemical kits tailored to your water quality
Optional O&M
WhatsApp and remote login support
Performance benchmarking reviews
Everything you need to know about Reverse Osmosis System
Looking to fix or upgrade an existing ZLD system?
We offer audit-based redesigns. After reviewing your system and testing samples, we help you improve recovery, reduce costs, and simplify operations.
Since 2019, Inovar has been leading the way in Reverse Osmosis System
- We design with data, not assumptions
- We engineer for long-term performance, not just installation.
- We don’t cut corners to stay cheap.
- We prioritize total cost of ownership (TCO), not just CapEx.
- We care what happens after handover.
Frequently Asked Questions
What is Reverse Osmosis?
Reverse Osmosis (RO) is a advanced water purification process that uses a semi-permeable membrane to remove up to 99% of dissolved salts, impurities, and contaminants from water. By applying pressure to overcome natural osmotic pressure, RO forces water molecules through the membrane, leaving contaminants behind.
How does an RO system work?
• Pre-filtration: Sediment and carbon filters remove dirt, chlorine, and particles that could damage the RO membrane.
• Reverse Osmosis: Pressurized water passes through the RO membrane, separating pure water from contaminants.
• Drainage: Concentrated contaminants (reject water) are flushed to drain.
• Post-filtration: A polishing filter enhances water taste and quality before delivery.
• Storage: Purified water is stored in a tank for on-demand use.
How do I choose the right RO system?
The ideal system depends on:
• Water Quality: Source water TDS and contaminant levels.
• Daily Water Demand: Capacity required (liters per hour/day).
• Purpose: Drinking water, process water, or ultra-pure water.
• Space and Budget: Footprint and investment constraints.
• Our experts will recommend the best system after a detailed water analysis and needs assessment.
What’s the difference between residential and industrial RO systems in terms of Capacity?
Residential RO: Compact, low capacity (50–400 LPD), point-of-use.
Industrial RO: High capacity (1 m³/hr and above), built for continuous operation, often integrated with
pre- and post-treatment systems.
What is the typical cost of an Reverse Osmosis System?
Costs vary based on:
• Capacity and technology (e.g., standard RO vs. high-efficiency)
• Level of automation
• Materials of construction
• Pre-treatment requirements
• We provide transparent quotes after a site survey and water test.
What maintenance does an RO system require?
• Pre-/Post-Filters: Replace every 6–12 months.
• RO Membrane: Replace every 2–5 years.
• Sanitization: Annual cleaning to prevent biofouling.
• Tank and Line Checks: Ensure pressure and hygiene.
Do you offer maintenance services?
Yes! We provide Annual Maintenance Contracts (AMC) covering:
• Filter and membrane replacements
• System sanitization and performance checks
• Remote monitoring and technical support
How much electricity does an RO system consume?
• Residential RO systems use minimal power (like a small bulb).
• Industrial systems consume more due to high-pressure pumps, but energy-efficient designs with
recovery devices minimize costs.