We would like to keep you up to date with the latest news from Digitalisation World by sending you push notifications.
Digital Newsletter
Each week our editor Phil Alsop rounds up the most popular articles, videos and expert opinions. We compile this into a Digital Newsletter and send it straight to your inbox every week.
Digital Magazines
We'll let you know each time a new edition of Digitalisation World is released so that you're always kept up-to-date with the latest and greatest news and press releases.
Video Magazines
The Digitalisation World Video magazine contains the latest Zoom interviews with experts in the industry.
Water chillers account for between 60 and 85% of overall cooling-system energy consumption. Consequently, data centres are designed, where possible, to keep usage of chillers to a minimum and to maximise the amount of available “free cooling”, in which less power-hungry systems such as air coolers and cooling towers can keep the temperature of the IT space at a satisfactory level.
One approach to reducing water chiller energy consumption is to design the cooling system so that a higher outlet water temperature (CHW) from the chillers can be tolerated while maintaining a sufficient cooling effort. In this way, chillers consume less energy by not having to work as hard, and the number of free cooling hours can be increased.
As with any complex system, attention needs to be paid to all parts of the infrastructure, as changes in one area can have direct implications for another. A new White Paper from Schneider Electric, the global specialist in energy management and automation, examines the effect on overall cooling system efficiency by operating at higher chilled water temperatures.
White Paper #227, “How Higher Chilled Water Temperature Can Improve Data Center Cooling System Efficiency”, outlines the various strategies and techniques that can be deployed to permit satisfactory cooling at higher temperatures, whilst discussing the trade-offs that must be considered at each stage, comparing the overall effect of such strategies on two data centres operating in vastly different climates.
Among the trade-offs discussed were the need to install more air-handling units inside the IT space to offset the higher water-coolant temperatures, in addition to the need for redesigned equipment such as coils, to provide adequate cooling efforts when CHW (chilled water temperature) exceeds 20C. The paper also advises the addition of adiabatic, or evaporative, cooling to further improve heat rejection efficiency. Each approach requires an additional capital investment, but results in lower long-term operating expenses due to the improved energy efficiency.
White Paper 227 details two real-world examples in differing climates; the first is in a temperate region (Frankfurt, Germany) and the second in a tropical monsoon climate (Miami, Florida). In each case, data was collected to assess the energy savings that were accrued by deploying higher CHW temperatures at various increments, whilst comparing the effect of deploying additional adiabatic cooling.
The study found that an increased capital expenditure of 13% in both cases resulted in energy savings of between 41% and 64%, with improvements in TCO between 12% and 16% over a three year period.
Another inherent benefit of reducing the amount of energy expended on cooling is the improvement in a data centres PUE (Power Usage Effectiveness) rating. As this is calculated by dividing the total amount of power consumed by a data centre by the power consumed by its IT equipment alone, any reduction in energy expended on cooling will naturally reduce the PUE figure.
The Schneider Electric study found that PUE for the two data centres examined was reduced by 14% in the case of Miami and 16% in the case of Frankfurt.
