Process cooling designed to stabilize quality and reduce downtime exposure
Cooling architecture directly affects cycle repeatability, part quality, and line availability. We start from thermal load profile, process tolerances, and facility constraints.
Stable process parameters
Selection is tied to operating range and load dynamics, not nominal values alone.
Lower downtime risk
Rollout planning includes critical continuity points for safe startup and operation.
Clear investment decisions
We show which parameters are ROI-critical and which can be phased without control loss.
Industries we select cooling for
We focus on processes where medium temperature directly affects quality and production efficiency.
Plastics processing
Chillers and mold thermoregulation for injection lines
Metalworking
Process cooling for CNC machines and spindles
Food & beverage
Cold chain and warehouse temperature stabilization
Pharma
Reactor cooling and controlled-environment zones
Electronics
Heat dissipation from soldering and testing processes
Small temperature drifts can increase scrap, stretch cycle time, and reduce planning predictability. This is why we assess whole-system behavior, not only chiller power ratings.
In the partner model we structure scope, recommend delivery variants, and coordinate implementation so your team gets one coherent technical decision path from pre-sales to acceptance.
For lifecycle sustainability, we align choices with efficiency references (including ASHRAE 90.1) and current EU F-gas regulatory direction, helping avoid short-lived technical decisions.
Validate cooling selection for your process
We prepare technical variants matched to your load profile and facility conditions.
Book a callScope is configured to process logic and implementation constraints, not catalog templates.
- Thermal-load and temperature-requirement analysis
- Variant selection: chillers, thermal control, integration options
- Utilities and environmental-constraint verification
- Rollout and acceptance control plan
- Partner-model implementation coordination
- Post-start parameter-stabilization support
- 1Technical call and confirmation of the business objective
- 2Input-data collection with facility constraints review
- 3Recommended delivery variant and rollout plan
- 4Execution coordination, acceptance, and operational support
Cooling in numbers
24h
Response time to new request
4
Quality control stages in selection
~40%
Of industrial energy used by HVAC
IEA, 2023
2050
EU F-gas phase-out year for GWP>150
EU F-gas Regulation
The better operating conditions are described, the faster recommendations can be narrowed to viable solutions.
- What is being cooled and the daily/shift load profile
- Required medium-temperature range and tolerance limits
- Ambient conditions, installation space, acoustic limits
- Available power and technical infrastructure
- Priorities: quality stability, throughput, energy cost, serviceability
Cooling choices are aligned with process needs, energy-efficiency frameworks, and environmental regulation trends.
- ASHRAE 90.1
Energy-efficiency standard used as reference point for buildings and system design.
- EU F-gas Regulation
EU framework shaping refrigerant policy and implementation constraints.
- IEA - Space Cooling
Global demand and efficiency trends in cooling technologies.
- TEDESolutions Cooling Catalog
Product-group overview and baseline technical parameters.
Typical questions cover ownership split, rollout pace, and how to handle modernization scenarios.