How to Improve Chiller Efficiency in Existing Industrial Plants (Without Replacement)

Industrial Chiller

Rising electricity costs in Malaysia have made chiller efficiency a top concern for facility managers. Yet many plants assume that significant efficiency gains require full chiller replacement.

In reality, many existing water-cooled chillers still have recoverable efficiency — if the right optimisation strategies are applied.

This guide explains how to improve chiller efficiency in existing industrial plants, focusing on practical actions that deliver measurable results.

Why Many Older Chillers Are Still Recoverable

Chillers rarely become inefficient overnight.
Efficiency loss usually happens gradually due to:

Fouled heat exchangers
Degraded bearings and seals
Poor water quality
Control system drift
Suboptimal operating practices

Before replacement is considered, efficiency recovery should be evaluated.

Common Efficiency Killers in Water-Cooled Chillers

Heat Exchanger Fouling

Even light scaling or biofouling increases approach temperatures, forcing compressors to work harder.

Supporting article:
The Importance of Water Treatment for Chilled Water Systems.

Mechanical Wear

Worn bearings, seals, and impellers increase internal losses and reduce compression efficiency.

Poor Condenser Performance

Cooling tower inefficiencies directly increase chiller power consumption.

Control & Sensor Drift

Inaccurate sensors lead to incorrect loading, short cycling, and poor part-load performance.

Mechanical Improvements That Recover Efficiency

Heat Exchanger Restoration

Tube brushing or chemical cleaning
Retubing for severely degraded bundles
Tube material upgrades (where applicable)

These actions often deliver immediate efficiency improvement.

Bearing & Seal Restoration

Reduces friction losses
Improves compressor stability
Lowers oil contamination risk

This is especially critical for centrifugal chillers.

Control & Operational Optimisation

Chilled Water Temperature Reset

Many systems operate at unnecessarily low setpoints, increasing compressor lift.

Condenser Water Optimisation

Optimising condenser water temperature improves chiller efficiency but must be balanced against cooling tower performance.

Guidelines from ASHRAE highlight the importance of integrated system optimisation rather than isolated adjustments.

Load Management

Operating chillers closer to their optimal efficiency range often yields significant energy savings.

Cooling Tower & Water Quality Impact

Cooling tower performance directly affects chiller efficiency.

Key factors include:

Proper airflow
Clean fill media
Balanced water distribution
Effective water treatment

The International Energy Agency consistently identifies heat rejection efficiency as a critical contributor to HVAC energy consumption.

When Optimisation Is No Longer Enough

Optimisation may no longer be cost-effective when:

Structural components are degraded
Refrigerant is obsolete
Efficiency recovery is marginal
Failure risk outweighs savings

At this stage, overhaul or replacement evaluation is necessary.

Supporting article:
Chiller Preventive Maintenance Checklist for Facility Managers

A Practical Efficiency Improvement Checklist

Before replacing a chiller, confirm whether:

Heat exchangers are clean and efficient
Bearings and seals are within tolerance
Sensors and controls are calibrated
Cooling tower performance is optimised
Operating setpoints are justified

Many facilities recover 5–20% energy savings through optimisation alone.

Conclusion: Efficiency Improvement Is Often the First Best Step

Replacing a chiller is a major investment.
Improving efficiency in existing systems is often:

Faster
Less disruptive
More cost-effective

A structured optimisation approach helps facility managers reduce energy cost, extend chiller life, and delay capital expenditure. It is highly-recommended for facility managers to have a full understanding of the complete chiller maintenance knowledge before improving the efficiency of a chiller.