Variable Refrigerant Flow

Variable Refrigerant Flow (VRF) System uses refrigerant as a heating and cooling medium. They offer individualized climate control to different zones, adjusting refrigerant flow based on specific requirements. VRF enhances energy efficiency by minimizing energy waste and enables simultaneous heating and cooling in different building areas. This flexibility makes VRF systems suitable for diverse spaces, promoting optimal comfort and energy conservation.

It is composed of:

• VRF Condenser Unit

• VRF Terminal Unit

The 'Select HVAC Template' form provides options to allow you to configure the system with:

• A single VRF Condenser Unit connected to multiple VRF Terminals Units or multiple VRF Condenser Units connected to VRF Terminal Units

• Choice of Spaces for VRF Terminal Units

VRF Metered Outputs

Zone Sizing

Zone sizing determines peak heating and cooling loads for each zone by simulating extreme design days, the hottest day for cooling and coldest day for heating, rather than full annual periods. The outputs include design load in kW and required supply airflow in L/s for each zone. Peak occurrence timing varies depending on orientation and internal gains. A sizing factor, typically between 1.15 and 1.25, is applied as a safety margin.

For VRF systems, these results reveal load diversity since different zones peak at different times. This allows the outdoor unit to be downsized using coincidence factors, which is essential for heat recovery VRF design that enables simultaneous heating and cooling.

Zone Meters

Zone meters are virtual sub-meters that track energy flows within each zone throughout the annual simulation, providing monthly summaries. They track two categories: electricity meters record electrical demand in kWh for fans and terminal units (representing utility costs), while supplied energy meters track the thermal energy in kWh delivered for heating and cooling (the useful output).

Each meter records total monthly energy in kWh, peak instantaneous power in kW, and the timestamp when peak occurs. You can use this data to compare zones and identify consumption patterns, assess efficiency by comparing electrical input to thermal output, and validate that load diversity and part-load performance match expectations.

Plant Meters

Plant meters track the central equipment, which for VRF systems means the outdoor condensing units serving all zones. The system separates tracking for cooling and heating: VRF Condenser Cooling Electricity shows summer peaks occurring in mid-to-late afternoon, while VRF Condenser Heating Electricity shows winter peaks in early morning hours.

These meters provide monthly energy totals and peak demands, revealing the coefficient of performance under real conditions, total building HVAC electrical demand, and validation of outdoor unit sizing against rated capacity.

Fan System Model

The fan system model simulates fan performance in VRF terminal units, calculating airflow delivery and power consumption. During zone sizing, it establishes the Design Maximum Air Flow Rate in L/s (the capacity needed for peak cooling load) and the Design Electric Power Consumption in kW (power required at maximum airflow, which scales with zone size).

During the simulation, fans modulate to match actual loads, consuming less power at part-load conditions than at design maximum.

Zone HVAC Terminal Unit VRF

The terminal unit is the indoor unit serving individual zones, containing a coil, fan, and controls. It modulates refrigerant flow to meet zone loads. Key design parameters include the Design Supply Air Flow Rate in L/s (airflow during cooling, heating, and ventilation-only modes) and the Design Outdoor Air Flow Rate in L/s (minimum ventilation airflow for air quality).

During operation, the unit modulates refrigerant flow via expansion valves, adjusts fan speed, introduces specified outdoor air, and cycles between modes as needed.

Coil Cooling DX VRF

The cooling coil provides modulating capacity through variable refrigerant flow. Design parameters from zone sizing include the Design Size Rated Air Flow Rate in L/s (volumetric airflow across the coil), Design Size Gross Rated Total Cooling Capacity in kW (total heat removal including both sensible and latent), and Design Size Gross Rated Sensible Heat Ratio or SHR (the fraction devoted to sensible versus latent cooling, typically around 0.80, meaning 80% sensible and 20% latent).

The key characteristic here is that the coil modulates refrigerant flow to match loads at part-load conditions, avoiding the on/off cycling you'd see with fixed-capacity systems.

Coil Heating DX VRF

The heating coil provides modulating capacity using heat pump technology, extracting heat from outdoor air. Design parameters include the Design Size Rated Air Flow Rate in L/s (airflow across the coil during heating) and Design Size Gross Rated Heating Capacity in kW (total heat delivery capacity).

These values typically mirror the cooling coil values, indicating balanced design. Keep in mind that performance decreases as outdoor temperature drops.

Air Conditioner VRF

This is the complete outdoor unit system serving all indoor units, including variable-speed compressors, outdoor coil, fans, and controls. Design parameters include the Design Size Rated Total Cooling Capacity in kW (maximum heat rejection capacity), Design Size Rated Total Heating Capacity in kW (maximum heat delivery capacity), Resistive Defrost Heater Capacity (melts frost on the outdoor coil during heating in cold conditions), and Design Size Evaporative Condenser Air Flow Rate in L/s (airflow across the outdoor coil).

An important concept is diversity sizing. The outdoor unit may be sized smaller than the total indoor capacity since zones don't peak simultaneously, which optimises cost and efficiency. During operation, the system continuously modulates compressor speed, adjusts refrigerant distribution, cycles fans, and executes defrost cycles as needed.