Indian Data Centre Cooling — CRAC vs CRAH vs Immersion + PUE Strategy

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Indian Data Centre Cooling — CRAC vs CRAH vs Immersion + PUE Strategy

By MEPVAULT Editorial Team · MEP Consultant · HVAC / Data Centre · 11 May 2026

Reading time ~ 10 min · Originally published: 09 May 2026 · Last revised: 11 May 2026

For a 5 MW Mumbai hyperscale facility, traditional CRAC delivers PUE 1.7, CRAH-CHW 1.45, in-row + airside economiser 1.3, liquid immersion 1.08. The PUE delta from 1.3 to 1.08 saves ~10 GWh/yr per 5 MW but costs ₹20-30 Cr in capex premium — only justified for GPU/AI workloads. For mainstream commercial DC, the right target is PUE 1.3 via in-row containment + 14 °C CHW + airside economiser. Three architectural decisions that lock PUE for life.

Indian data centre cooling — the PUE arms race

Indian data centre capacity has expanded ~5× over 2020-2026, driven by hyperscale cloud, regulated payments infrastructure, and government cloud mandates. For a 1 MW IT load facility in Mumbai-Hyderabad-Chennai (the three big hubs), four cooling architectures compete: traditional CRAC (DX), CRAH (chilled-water), in-row + airside economiser, and liquid immersion. Each lands at a different annual PUE (Power Usage Effectiveness = total facility power / IT power).

// FIG · MEPVAULT Data centre cooling — CRAC vs CRAH vs immersion (1 MW IT load) 0.0 9.2 18.5 27.7 37.0 46.2 Scaled 1.7 1.45 1.3 1.08 PUE (annual) 2.5 3.5 4.2 8.5 Capex (₹ Cr/MW) 30 42 28 15 Footprint (m²/MW) 4 4 4 5 Reliability (1-5) CRAC (DX-coupled) CRAH (CHW-coupled) In-row + airside econ Liquid immersion SOURCE: ASHRAE TC 9.9 Thermal Guidelines 5th ed; AHRI 1361 (CRAC); Indian DC industry data 2024 · plotted 2026-05-11

Four architectures — by-the-numbers comparison

Architecture PUE annual Capex (₹ Cr/MW IT) Footprint (m²/MW) Reliability Best fit
CRAC (DX, perimeter) 1.6-1.8 2.2-2.8 28-32 High Small DC ≤ 500 kW + edge
CRAH (chilled water, perimeter) 1.4-1.5 3.0-4.0 38-45 High Mid + large DC; mainstream
In-row CRAH + airside economiser 1.25-1.35 4.0-4.5 25-30 High Hyperscale + > 5 MW
Liquid immersion (2-phase) 1.03-1.10 8-10 12-18 Very high HPC / AI / GPU cluster only
Direct-to-chip cold-plate 1.10-1.15 7-9 20-25 Very high GPU + ML workloads

Why PUE 1.3 is the right Indian commercial target — not 1.05

Liquid immersion delivers PUE 1.08 but costs ₹8-10 Cr/MW capex vs ₹3.5-4 Cr for CRAH + airside economiser. The PUE delta of 0.27 (1.3 vs 1.03) on a 5 MW facility saves ~10 GWh/year = ₹85 lakh annually at ₹8.5/kWh. The capex delta is ₹20-30 Cr for the immersion solution. Payback > 25 years on energy alone — only justified if the IT workload requires immersion (high density GPU/ML > 50 kW/rack) for technical reasons.

A 5 MW Mumbai hyperscale facility — design choice

System Capacity Configuration Capex (₹ Cr) Annual energy (GWh) PUE achieved
Chillers + cooling towers 2 × 3,000 TR + 4 × 1,500 TR cooling tower N+1 redundancy 12 13.5
CRAH units (in-row) 30 × 60 kW + 12 × 100 kW Hot-aisle/cold-aisle containment 5 7.0
Airside economiser (DOAS) 5 × 30,000 m³/h economiser AHU Outside-air pre-cool when ambient < 22 °C 3 Reduces above by 1.2 GWh
UPS + STS 2 × 2.5 MVA UPS + STS N+1 8 3.5
Total 28 + IT 21.3 + 32 (IT) 1.33

5 MW IT load × 8,760 hours = 43.8 GWh IT consumption. Plus 21.3 GWh facility = 65.1 GWh total. PUE = 65.1 / 43.8 = 1.49. After in-row containment + airside economiser optimisation, achieved PUE settles at 1.33 on annual basis (Mumbai climate gives ~28 % free-cool hours).

Three architectural decisions that lock PUE for the building life

  1. Cold-aisle / hot-aisle containment — solid roof + end-of-aisle doors. Without containment PUE drops by 0.10-0.15. Mandatory specification.
  2. Chilled water supply temperature — 14 °C (vs 7 °C traditional) for CRAH. Allows chiller to run higher COP + enables airside economiser more hours. Coordinate with rack inlet specification (recommended 27 °C max per ASHRAE TC 9.9 Allowable A1).
  3. Free-cooling sequence design — partial (waterside economiser) when ambient WB < 16 °C + full (airside economiser bypassing chiller) when ambient DB < 22 °C. The control sequence must be commissioned, not just installed.

References

  1. ASHRAE TC 9.9 Thermal Guidelines for Data Processing Environments (5th Edition), ASHRAE Atlanta 2021.
  2. ASHRAE Datacom Series — Best Practices for Data Center Energy Efficiency, ASHRAE 2022.
  3. AHRI Standard 1361:2021 — Performance Rating of Computer and Data Processing Room Air Conditioners.
  4. Uptime Institute Tier Classification System (Tier I-IV), Uptime Institute.
  5. TIA-942-C:2024 — Telecommunications Infrastructure Standard for Data Centers.
  6. ANSI/BICSI 002-2019 — Data Center Design and Implementation Best Practices.
  7. The Green Grid PUE Whitepaper (latest edition) — definition and measurement of PUE.
  8. Indian Data Centre Industry Report 2024 — KPMG India + NASSCOM cross-reference data.

// About the Authors

MEPVAULT Editorial Team — A team of practising MEP consultants based in India. ISHRAE-affiliated; FSAI-aligned.

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