What is the difference between COP and EER?

COP measures the efficiency of a system in heating mode. EER measures the efficiency in cooling mode. Both express the ratio between the useful energy produced and the electrical energy consumed.

Air Conditioning Guide 2026 | Cooling Systems, Performance & Decarbonization | Wattnow

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● WATTNOW

Air Conditioning Guide – 2026 Edition

Master your
cooling systems
and decarbonize

Refrigeration cycle, performance indicators (COP, EER, IPLV), refrigerants, VRF technologies, energy audit and decarbonization.

30-60%

of the electricity bill in commercial buildings

−40%

savings via supervision

18 months

average IoT ROI

2027

GWP < 150 mandatory

Start

CHAPTER 1

Fundamentals of Air Conditioning

An air conditioning system is never a standard product

An air conditioning system is a set of components that cools, dehumidifies, filters and circulates air in a space to maintain occupant comfort during hot periods. Each installation is sized for a specific building and use. In France, the air conditioning load represents 30 to 60% of the electricity bill of a commercial building during the summer period.

7basic air treatment processes

3main refrigeration cycle families

4components of the vapor compression cycle

1.1 Comfort air conditioning, process air conditioning

In institutional, commercial and residential buildings, air conditioning systems primarily serve the health and comfort of occupants. This is referred to as comfort air conditioning. In industrial buildings, they serve the manufacturing process as well as operator comfort: this is process air conditioning. Cold rooms, on the other hand, address a third need: the preservation of foodstuffs.

Under these uses, three main technological families coexist. The choice between them depends on cost, the availability of a waste heat source and the target temperature.

Vapor Compression

The most widespread family (95% of installations)
Compressor circulates the refrigerant between high and low pressure
Technical foundation of air conditioners, chillers and heat pumps
Typical COP: 2.5 to 6.2 depending on technology

Vapor Absorption

Compressor replaced by a generator and an absorber
Relevant when a waste heat source is available
Higher initial investment cost but can be amortized
Uses pairs like ammonia-water or lithium bromide-water

Air Expansion

Reserved for niche applications
Aeronautics and cryogenics (very low temperature refrigeration)
Not common in standard building or industry

1.2 The seven basic air treatment processes

Regardless of the climate, any air conditioning system combines up to seven elementary operations. The local climate determines which ones are actually needed. In summer, the key processes are sensible cooling, dehumidification and air cleaning.

Process	Function	Summer priority
Sensible cooling	Removes heat from the conditioned space	High
Dehumidification	Removes water vapor from the air	High
Sensible heating	Adds heat to the conditioned space	Low
Humidification	Adds water vapor to the air	Low
Air cleaning	Removes dust, particles and contaminants	High
Air renewal	Exchanges air between inside and outside	High
Air movement	Controls air circulation in the space	High

1.3 Components of an air handling unit

Behind every breath of conditioned air, a chain of components works in sequence. Understanding this chain means knowing where to look in case of performance drift.

Figure 1: Air treatment chain

📌 The most overlooked point of vigilance: a clogged filter increases the pressure drop throughout the system and degrades the performance of the downstream coils. Regular cleaning and replacement of filters is the most cost-effective maintenance action, and the most frequently postponed.

CHAPTER 2

Types of Systems & Thermal Comfort

Choose the right architecture, before choosing the equipment

Depending on the size, construction and intended operating mode, an air conditioning system belongs to one of five main families. Choosing the wrong architecture costs more than a bad brand choice.

2.1 Five architectures, five logics

Individual system

Window units, split or package air conditioners
Outdoor unit separate from indoor unit
Direct expansion (DX) cooling
Typical capacity: 2 to 15 kWf
Ideal for small spaces and residential

Evaporative cooling

Exploits cooling through water evaporation
No compressor, much lower consumption
Only effective in dry climates (humidity < 60%)
Energy savings: 50 to 80% compared to a conventional system

Thermal storage

Compressors operate during off-peak hours
Chilled water (4-6 °C) or ice stored for peak periods
Always centralized type
Reduces installed cooling capacity by 30 to 50%

Cleanroom

Critical particle control (ISO 14644)
Temperature, humidity, pressure, noise, vibrations
Directly impacts product quality (pharma, microelectronics)
ISO class 5 to 8 depending on needs

Why the central hydronic system changes the scale

2.2 Thermal comfort: a balance, not a temperature

Thermal comfort results from a heat balance between a person and their environment. Many parameters influence the feeling of comfort: activity (metabolism), ambient temperature and humidity, air movement, clothing. Comfort can be achieved at air temperatures between 20 °C and 26.6 °C, and relative humidity between 20% and 70%.

In summer, humidity control is crucial: excessively high relative humidity (> 70%) prevents sweating and worsens the feeling of heat. Effective dehumidification is therefore essential for summer comfort.

Psychrometric term	Definition	Typical summer value
Dry-bulb temperature	Measured by a standard thermometer	22-26 °C
Wet-bulb temperature	Measured by a thermometer with a wet wick	16-20 °C
Relative humidity	Ratio of actual water vapor / water vapor of saturated air	40-60% RH

📌 Psychrometry is the common language of cooling: any sizing, regulation or audit decision is read on a psychrometric chart. Without mastering these concepts, it is impossible to correctly interpret a field measurement.

Exclusive content

The 6 chapters that turn reading into an action plan

Refrigeration cycle and performance indicators, quantified savings levers, refrigerants, VRF and chiller technologies, audit methodology and decarbonization.

Chapter 3: Refrigeration cycle & performanceCompressor, condenser, expansion valve, evaporator, COP, EER, IPLV

Chapter 4: Energy saving leversVAV, free-cooling, variable speed drives, chiller replacement

Chapter 5: RefrigerantsODP, GWP, CFC alternatives, absorption systems

Chapter 6: Advanced technologiesVRF, chillers, thermal storage, BMS

Chapter 7: Audit methodology & decarbonizationField checklist, low-carbon design

Chapter 8: FAQ & glossaryFrequently asked questions, expert lexicon

Immediate & free access

Reserved for building and industry professionals

Access confirmed!

CHAPTER 3

Refrigeration cycle & performance indicators

The vapor compression refrigeration cycle powers the majority of air conditioning equipment. Understanding it is the key to interpreting a data sheet, a supervision alert or a performance discrepancy in the field.

Figure 2: Vapor compression refrigeration cycle

3.1 Subcooling and superheat

The fluid leaving the condenser is generally subcooled below the saturation temperature, which increases the refrigerating effect. At the compressor suction, the vapor is slightly superheated to ensure dry compression. These two settings are performance levers.

Subcooling: the higher it is, the greater the refrigerating effect (typically 3 to 5 °C)
Superheat: typically 5 to 10 °C, protects the compressor from liquid slugging

3.2 Performance indicators

Indicator	Formula	Usage	Typical value
COP	Refrigerating effect (kW) ÷ input work (kW)	Manufacturer's reference conditions	2.5 to 6.2
EER	Refrigerating effect (BTU/h) ÷ electrical power (W)	Compressors, packages	8 to 20
IPLV	0.01·A + 0.42·B + 0.45·C + 0.12·D	Weighted performance at 100/75/50/25% load	3.5 to 8.5
kW/ton	Input work (kW) ÷ refrigerating effect (ton)	Consumption per ton of refrigeration	0.4 to 2.0

IPLV = 0.01 × (100%) + 0.42 × (75%) + 0.45 × (50%) + 0.12 × (25%)

📌 Why IPLV matters more than nominal EER: equipment spends most of its time at partial load (between 40 and 80% load). IPLV reflects operational reality, not just full-load performance.

3.3 Three compressor families

Reciprocating (piston)

Capacity: 0.5 to 200 ton
Low initial cost, frequent maintenance
Ideal for small installations

Centrifugal

Capacity: 90 to 2,000 ton
Very efficient at full load, compact
Less efficient at partial load (except with inverter)

Screw

Capacity: 20 to 1,000 ton
Compact, lightweight, quiet
Efficient at both partial and full load

CHAPTER 4

Energy saving levers

An air conditioning system is custom-designed for a specific use: its audit is just as specific. The general methodology combines two complementary axes: reducing the load at source and optimizing operation.

Figure 3: Energy audit methodology

4.1 CAV or VAV

A constant air volume (CAV) system always delivers the same air volume, regardless of the load. At partial load, it wastes energy by reheating the cooled air. A variable air volume (VAV) system delivers a variable air volume at constant temperature, significantly reducing waste. Converting a CAV fleet to VAV is a recognized energy saving measure, with typical gains of 20 to 40% on fan consumption.

4.2 Variable frequency drives (VFD)

📊 Example: 50 hp fan with VFD

A 50 hp fan operates 10 h/day, 250 days/year. At full speed, the annual cost is €5,559 (at €0.18/kWh). With a VFD and a realistic operating range (25% at 100%, 50% at 80%, 25% at 60%), the annual cost drops to €3,113.

€2,446annual savings

18-24 monthsreturn on investment

44%consumption reduction

4.3 Free-cooling

Free-cooling produces chilled water without running the compressor, by using cool outside air. In a data center in mainland France, free-cooling represents 50 to 75% of the annual time, i.e. 30 to 50% energy savings on cooling production.

Direct free-cooling: dedicated heat exchanger, chiller off
Indirect free-cooling: condenser cooling, chiller modulated
Integrated free-cooling: additional module on air-cooled chiller

📌 To remember: free-cooling is now a standard in data centers and large commercial buildings, no longer an option. It can be combined with thermal storage to further optimize consumption.

4.4 Replacing an existing chiller

📊 Replacement of an 800 kW chiller

An existing 800 kW chiller with an average seasonal COP of 3.5 is replaced by a chiller of the same capacity with an average seasonal COP of 4.5. Electricity cost: €0.18/kWh. Equivalent full-load operating hours: 1,000 h/year.

50,800 kWhenergy savings/year

€9,144financial savings/year

< 2.5 yearsreturn on investment

Before any replacement, five settings should be checked on the existing chiller:

Set the chilled water to the highest possible temperature (increases COP)
Lower the condensing water temperature (water-cooled condenser)
Increase the heat exchange surface of the evaporator and condenser
Enlarge refrigerant lines to reduce pressure drops
Treat condensing water to prevent scaling

CHAPTER 5

Refrigerants & environmental impact

The refrigerant absorbs and transmits heat in the vapor compression cycle. Its decisive properties are the pressure-temperature relationship, chemical stability, toxicity, ozone depletion potential (ODP) and global warming potential (GWP).

Refrigerant	Formula	ODP	GWP	2026 status
CFC-12	CF₂Cl₂	1	10,600	Banned
HFC-134a	CH₂FCF₃	0	1,300	Phase-out in progress
HFC-152a	CH₃CHF₂	0	120	Promising alternative
HC-290 (propane)	C₃H₈	0	3	Strong growth (limited charge)
HC-600a (isobutane)	C₄H₁₀	0	3	Domestic refrigerators
R454B	HFO/HFC	0	466	Main transition 2024-2030
R1234ze	HFO	0	< 1	Long-term reference > 200 kWf

HFC-134a, the most common: requires hygroscopic synthetic oils, therefore stricter maintenance. Its GWP of 1,300 makes it less and less competitive compared to low GWP refrigerants like R454B or R1234ze.

PFAS uncertainty: a major strategic risk. HFOs (R1234ze, R454B) are classified as PFAS by OECD. The European restriction dossier could, in its strictest version, lead to the progressive ban of HFOs by 2027-2030. Must be considered now in any long-term planning.

5.1 Vapor absorption

The vapor absorption system is appealing for its low operating cost and environmental friendliness, as soon as a waste heat source is available (industrial waste heat, cogeneration, solar thermal). The compressor is replaced by a generator (desorber) and an absorber. The most commonly used pairs are:

Ammonia-water: for negative cooling, robust, but toxic
Lithium bromide-water: for positive cooling, safer, but requires a high generation temperature (80-120 °C)

CHAPTER 6

Advanced technologies: VRF, chillers & BMS

6.1 VRF: one outdoor unit, individualized needs

A variable refrigerant flow (VRF) system uses multiple evaporators of different capacities and configurations, enabling individualized comfort control, simultaneous heating and cooling according to zones, and heat recovery between zones. VRF saves 11 to 17% energy compared to conventional units.

Figure 4: Flexibility of a VRF system

6.2 Chillers (chilled water groups)

A chiller (chilled water group) is a thermodynamic machine that produces chilled water (5 to 18 °C) to supply cooling coils, radiant ceilings or process heat exchangers. It becomes essential when:

The capacity exceeds 100 kWf
Distribution distances are long (> 150 m)
Operation must be centralized
F-Gas requirements weigh on the DRV option

In 2026, the chiller market is marked by three converging transitions: refrigerant transition (low GWP), energy transition (partial load modulation) and digital transition (systematic IoT supervision).

6.3 BMS: the backbone of control

The building management system (BMS) monitors and regulates several systems at an optimal level: HVAC, electricity, security, maintenance. Protocols to impose in specifications:

BACnet/IP: for HVAC equipment (chillers, controllers)
Modbus RTU/TCP: for electricity meters and drives
MQTT + TLS: for cloud data collection
OPC UA: for integration with industrial systems

CHAPTER 7

Audit methodology & decarbonization

7.1 Field audit checklist

Operation & schedules

Reduce operation when space is unoccupied
Turn off unoccupied areas (vestibules, meeting rooms)
Adjust pre-cooling schedules

Setpoints & control

Adjust thermostats according to season (summer: 24-26 °C)
Calibrate them regularly
Install an enthalpy-based economizer cycle

Recovery & insulation

Heat recovery wheel: 50 to 70% energy recovered
Insulate ducts and chilled water pipes
Avoid thermal bridges

Basic maintenance

Clean coils
Replace filters (every 3-6 months)
Repair duct leaks

7.2 Decarbonization

Adopting decarbonization technologies can save 30 to 40% of a building's total energy. The priority levers for air conditioning are:

Free-cooling: maximum use of cool outdoor air
Natural refrigerants: R290 (propane), R744 (CO₂), R717 (ammonia)
Heat recovery: desuperheater for DHW
IoT supervision: continuous commissioning, drift detection
Thermal storage: load shifting to off-peak hours

🌱 Rule of thumb: A 1 °C decrease in condensing temperature improves COP by 2 to 4%. A 1 °C increase in evaporating temperature improves COP by 2 to 4%. In summer, these two levers are crucial for maintaining efficiency.

CHAPTER 8

FAQ & glossary

FAQ

COP, EER or IPLV: which one to look at first? IPLV weights performance at 100/75/50/25% load: it is the most representative indicator of actual operation, as equipment spends most of its time at partial load.

VAV or CAV for a new project? VAV minimizes waste at partial load. Retrofitting an existing CAV system to VAV is generally cost-effective, with 20 to 40% gains on fans.

When to replace a chiller? Check the basic settings (water temperature, condensation). If the seasonal COP remains low compared to a newer unit (COP 4.5+), the ROI is typically between 2 and 5 years.

Which refrigerant to choose in 2026? R454B or R1234ze depending on capacity and manufacturer. Anticipate PFAS by prioritizing natural refrigerants (R290, R744, R717) on long-term projects.

What is the ROI for IoT supervision? 18 to 36 months in average commercial buildings, 6 to 18 months in critical sites (data center, hospital). Covered by 15 to 40% of Energy Savings Certificates.

Glossary

COP: Coefficient of Performance = Refrigerating effect ÷ compression work
EER: Energy Efficiency Ratio = Refrigerating effect (BTU/h) ÷ electrical power (W)
IPLV: Integrated Part Load Value: Weighted performance at 100/75/50/25% load
ODP: Ozone Depletion Potential
GWP: Global Warming Potential
CAV: Constant Air Volume
VAV: Variable Air Volume
VRF: Variable Refrigerant Flow
BMS: Building Management System
Free-cooling: Cooling production without a compressor using outside air
Subcooling: Liquid cooled below its saturation temperature
Superheat: Vapor heated above its saturation temperature
Dry bulb / wet bulb: Temperatures measured with and without a wet wick

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