DATACENTER TURNKEY SERVICE

Your room. Our datacenter.

Have a building, warehouse, or unused floor? We design, source, build, and commission a production-grade datacenter inside it. One contract. One team. One handover.

01 / TIER 1

Tier 1

99.671% UPTIME

Single path, no redundancy. Cost-optimized for non-mission-critical workloads.

02 / TIER 3

Tier 3

99.982% UPTIME

Concurrently maintainable. Full redundancy for power and cooling. Standard enterprise spec.

03 / TIER 3+

Tier 3+

99.999% UPTIME

Dual power buses to every server, UPS + generator on each. Built for 24/7 AI training.

Request a site survey → See cooling options

WHAT WE DELIVER

End-to-end ownership. One team, one handover.

Building a datacenter usually means coordinating an electrical contractor, a mechanical contractor, an IT vendor, a commissioning agent, and an inspector — five companies, five contracts, five timelines. We handle all five stages under a single contract.

Design

Site survey, load study, Tier-level decision, single-line diagram, MEP layout, BIM model.

Procurement

Direct sourcing of UPS, gensets, switchgear, CRAC/CRV, racks, cabling. No middlemen markup.

Construction

Licensed electricians and mechanical crews. Local code compliance. Daily project reporting.

Commissioning

Level 1–5 commissioning per ASHRAE Guideline 0. Load-bank testing. PUE validation.

Handover

As-built docs, BMS training, runbook, 12-month warranty. Optional ongoing operations support.

You sign one contract. We coordinate everything. If the chiller arrives before the rack PDUs, that's our problem — not yours. If commissioning fails, we own the fix. The Tier-level promise is in writing.

COOLING OPTIONS

Air or water — matched to density.

Cooling choice is dictated by rack density, not preference. Below 40 kW per rack, air cooling wins on simplicity and CapEx. Above 80 kW, liquid is the only physically viable option. We design and install both, and recommend by load profile.

▸ AIR-COOLED

Proven, simple, low overhead.

The traditional choice for general-purpose workloads and AI startups. Easy to maintain, fewer failure modes, lower CapEx. Pairs with Fluorine Pump for free-cooling savings in cool climates.

Per rackUp to 40 kW
GPU density4× 8-GPU H200 SXM servers
PUE (annual)~1.4 standard · ~1.2 with Fluorine Pump
MaintenanceStandard HVAC trades, low SRE overhead

Best fit Mixed enterprise IT, H100/H200 air-cooled servers, AI inference, edge workloads, and any deployment in a cool-climate region where free cooling pays off.

▸ LIQUID-COOLED

Required above 80 kW per rack.

Water removes 90%+ of heat directly from the chip — air cooling can't physically reach this density. The only option for GB200/GB300 NVL72, B300, and other 100 kW+ rack architectures.

Per rackOver 100 kW
GPU density64+ H200 GPUs per rack
PUE (annual)~1.08 typical
MaintenanceSpecialist liquid trades, leak detection, CDU service

Best fit GB200/GB300 NVL72 deployments, B300 OCP racks, large-scale AI training clusters, and any site where rack density beats floor area economics.

▸ FLAGSHIP TECHNOLOGY · FLUORINE PUMP

Free cooling, five months a year.

In autumn and winter, outdoor air is colder than the air your servers exhaust. A Fluorine Pump exploits that gradient directly — no compressor, no chiller, just refrigerant circulating between indoor coils and outdoor condensers. The result: cooling power consumption drops by an order of magnitude during cold months.

01 / SENSE

Outdoor air drops below ~15°C

The CRV unit detects sufficient temperature gradient between indoor return and outdoor air.

02 / SWITCH

Compressor shuts down

The unit transitions out of mechanical refrigeration. The compressor — the largest power draw — goes idle.

03 / PUMP

Refrigerant circulates passively

A small fluorine pump moves refrigerant between indoor and outdoor coils. Heat moves by phase change, driven by the temperature gradient itself.

04 / SAVE

Cooling power collapses

Total cooling power drops to a fraction of compressor mode. Annual PUE improves dramatically in temperate and cold climates.

~15°C

Activation threshold

Free cooling kicks in when outdoor air drops below the indoor return temperature by enough margin.

~5 mo

Free-cooling window in Quebec

Mid-October to mid-March: roughly five months of compressor-off operation in temperate Canadian climates.

−30%

Annual cooling energy

Typical reduction in cooling-side energy consumption versus year-round compressor operation.

▸ TECHNOLOGY NOTE

Fluorine Pump is a proven, off-the-shelf capability — built into modern in-row CRV units like the Vertiv CR045/CR065 series. We don't claim it as a TGs4 invention. What we deliver is the system-level design: sizing the units correctly for your climate and load profile, integrating them with your BMS, and validating the free-cooling window during commissioning. The benefit is real, but only if the sizing and controls are done right.

WHY A SPECIALIST MATTERS

More than 50% of early-life datacenter failures trace directly to install quality.

70–90%

HVAC defects

of HVAC systems contain at least one installation defect — driving energy use up to 30% above design.

U.S. DOE Review

~57%

Power faults

of industrial electrical faults are loose connections, moisture ingress, and insulation defects — all site workmanship.

IEEE Gold Book

70–80%

MV cable faults

of medium-voltage cable failures are concentrated in field-fabricated terminations and splices, not in the cable itself.

Industry Field Data

Generalist contractors don't know what they don't know. Bushing torque, refrigerant charge, CT polarity, conservator commissioning sequence — the details that decide whether your datacenter hits its PUE target on day one or fights it for ten years.

We've done this enough times to know where the failures hide. That's what you're paying for.

PROJECT TIMELINE

From contract to live load in 16 weeks.

Typical timeline for a 1 MW Tier 3 deployment in an existing building. Larger or higher-Tier projects scale proportionally. Schedule is committed in writing at design freeze.

PHASE

W10

W11

W12

W13

W14

W15

W16

Site survey & design WK 1–3

Procurement WK 2–8

MEP construction WK 4–12

Equipment install WK 9–14

Commissioning WK 13–15

Handover & load-on WK 16

16 weeks vs. 18+ months.

CONCURRENT WORKSTREAMS
FACTORY-PRECONFIGURED MAJOR EQUIPMENT

TRACK RECORD

We've built this before.

A recent enterprise deployment — start to finish, on schedule, on PUE target.

▸ CASE STUDY · SHENZHEN, CHINA

600 kW enterprise AI cluster, delivered in 2 months.

Client: an enterprise AI team with GPUs already on order, an existing warehouse space, and a 60-day window to first training run.

Scope: full Tier 3 design, MV switchgear procurement, UPS & battery sizing, in-row liquid cooling layout, structured cabling, BMS integration, and load-bank validated commissioning. Handed over with PUE inside contractual target on first run.

The same playbook scales to 5 MW and beyond — site survey to live load, one team, one accountability line.

600 kW

IT capacity delivered

2 months

Contract to live load

Tier 3

Concurrently maintainable

Built for these scenarios

▸ 01 / GREENFIELD

Empty warehouse or shell building

You own or lease the space. We bring everything else — design, equipment, install, commissioning.

▸ 02 / RETROFIT

Existing server room upgrade

Aging HVAC, hitting density limits, or moving to liquid for new GPUs. We rebuild around your live operations.

▸ 03 / COLO BUILD-OUT

Multi-tenant facility expansion

Adding a new hall to an existing colo. Code-compliant designs, multi-tenant power and cooling segmentation.

▸ 04 / ENTERPRISE PRIVATE AI

In-house AI infrastructure

Banks, research labs, healthcare — sectors where workloads can't go to public cloud. Tier 3+ as standard.

Got a building? Let's see what fits.

Request a site survey → Talk to engineering

Site surveys within 5 days · Preliminary design in 2 weeks