Free Cooling with Cooling Towers — Indian HVAC Applications

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Chillers, Pumps & Equipment

Free Cooling with Cooling Towers — Indian Applications

Free cooling — using the cooling tower to provide chilled water without running the chiller compressor — is one of the highest-return energy efficiency measures available in Indian commercial buildings. In cities like Bangalore, Delhi (winter/monsoon), and Pune, ambient wet bulb temperatures fall low enough for several weeks per year to provide meaningful free cooling hours.

1. What is Waterside Free Cooling?

Waterside economiser (WSE) or free cooling uses a plate heat exchanger (PHX) to transfer cooling from the condenser water loop (cooled by the cooling tower) directly to the chilled water loop — bypassing the chiller compressor entirely, or supplementing it at partial capacity.

Mode

Chiller Status

Cooling Tower

Energy Use

Full mechanical cooling

Running at full load

Running normally

High — full chiller kW

Partial free cooling

Running at reduced load

Running — additional heat rejection

Medium — chiller + tower fans

Full free cooling

Off — compressor bypassed

Running at full capacity

Low — only tower fans + pumps

2. Free Cooling Availability — Indian Cities

City

Approx. Free Cooling Hours/Year

Months Available

Notes

Bangalore

800–1200 hours

Nov–Feb, monsoon evenings

Best in India for free cooling

Delhi

400–600 hours

Dec–Feb (nights)

Short winter season

Mumbai

100–200 hours

Jan–Feb (nights)

Limited — humid climate

Pune

500–800 hours

Nov–Feb

Good potential

Hyderabad

300–500 hours

Dec–Feb

Moderate potential

Chennai

50–100 hours

Jan only

Poor — warm humid all year

Kolkata

200–350 hours

Dec–Jan

Moderate

Ahmedabad

300–500 hours

Dec–Feb (dry cold)

Good — dry climate helps

Note: Free cooling hours assume a chilled water supply temperature of 7°C and cooling tower approach of 4°C. Higher chilled water setpoints increase free cooling hours significantly.

3. System Design

3.1 Plate Heat Exchanger Sizing

  • PHX duty = full plant cooling capacity for full free cooling capability
  • Design PHX for 2–3°C temperature approach — chilled water supply temperature achievable = CWT supply + 2–3°C
  • For 7°C chilled water supply: cooling tower must achieve 4–5°C condenser water supply — requires WBT below 0–1°C (not possible in India except high altitude)
  • Practical Indian application: raise chilled water setpoint to 10–12°C during free cooling mode — AHU control valves open wider, still effective for dehumidification at moderate loads

3.2 Control Strategy

  1. Monitor outdoor wet bulb temperature continuously
  2. When WBT drops below threshold (typically 10–12°C for partial free cooling), enable PHX loop
  3. Unload chiller as PHX takes over cooling duty — monitor chilled water supply temperature
  4. If WBT drops further, stage off chiller completely — full free cooling mode
  5. Reverse sequence as ambient warms

4. ROI Calculation — 500 TR Plant, Bangalore

Parameter

Value

Plant capacity

500 TR

Free cooling hours/year

1000 hours (partial + full)

Average chiller power displaced

280 kW

Annual energy saving

2,80,000 kWh

Additional cooling tower fan energy

40,000 kWh

Net annual saving

2,40,000 kWh

Cost saving @ ₹9/kWh

₹21,60,000/year

PHX and pipework capital cost

₹18–25 lakh

Simple payback

10–14 months

5. When Free Cooling is NOT Worth It

  • Chennai, Kochi, and similar coastal humid cities — insufficient cool hours, payback >8 years
  • Buildings with year-round 24/7 high loads (data centres with >95% utilisation) — limited low-load periods
  • Very small plants (<100 TR) — PHX capital cost does not justify the saving
  • Buildings without cooling towers (air-cooled chiller plants) — cannot implement waterside free cooling
© MEPVAULT · India's MEP Knowledge Platform

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