Optimising Efficiency in District Cooling Buildings
With urbanisation levels worldwide expected to reach about 2/3 of the population by 2050, District Cooling Systems provide an efficient and sustainable approach for densely populated areas.
How does a District Cooling System work?
Unlike traditional air conditioning systems, which rely on individual units in each building, District Cooling harnesses economies of scale to provide efficient and reliable cooling services to entire districts and it can significantly decrease energy consumption compared to traditional cooling methods, making it a smart choice for environmentally conscious urban planning.
Primary side
The primary side of a District Cooling system encompasses the centralised plant and the infrastructure responsible for producing and distributing chilled water.
Along the distribution network, pumping stations help maintain the flow and pressure of chilled water, ensuring efficient delivery to all connected buildings.
Secondary side
The secondary side of a District Cooling system involves the individual buildings that receive chilled water for cooling purposes. Within each building, heat exchangers are installed to receive water from the District Cooling System.
Customers pay for the volume of chilled water delivered to their building. However, additional charges may apply, including penalties for returning water not aligning with the specified temperature, also known as Low Delta T Syndrome, due to inefficient heat exchange.
Low Delta T Syndrome is a common issue in buildings but can be specifically detrimental in District Cooling Systems
Low Delta T Syndrome is a condition where the temperature difference (ΔT) between the supply and return water in a chilled or hot water system is significantly lower than the design specifications.
This phenomenon can lead to reduced system efficiency, increased energy consumption, and inadequate thermal comfort for building occupants.
By solving Low Delta T Sydrome, you can benefit from
Improved energy efficiency and save costs
When the design delta T is achieved, the system operates as intended, minimizing energy wastage caused by suboptimal conditions. In addition, it helps systems comply with country regulations, avoiding potential penalties and ensuring responsible operation.
Enhanced cooling or heating performance
HVAC equipment such as air handling units or fan coil units can achieve their desired cooling or heating output more efficiently. This ensures that occupants experience consistent and comfortable indoor temperatures throughout the building.
Extended equipment lifespan
When chillers and other cooling components operate under optimal conditions, they experience less strain and wear over time. This reduces the likelihood of breakdowns, extends the maintenance intervals, and ultimately extends the overall lifespan of the cooling system.
Improved energy efficiency and save costs
When the design delta T is achieved, the system operates as intended, minimizing energy wastage caused by suboptimal conditions. In addition, it helps systems comply with country regulations, avoiding potential penalties and ensuring responsible operation.
Enhanced cooling or heating performance
HVAC equipment such as air handling units or fan coil units can achieve their desired cooling or heating output more efficiently. This ensures that occupants experience consistent and comfortable indoor temperatures throughout the building.
Extended equipment lifespan
When chillers and other cooling components operate under optimal conditions, they experience less strain and wear over time. This reduces the likelihood of breakdowns, extends the maintenance intervals, and ultimately extends the overall lifespan of the cooling system.
