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Dealing with Hotspots in Datacenters Caused by High-Density Computing Peter Hannaford Director of Business Development EMEA.

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Presentation on theme: "Dealing with Hotspots in Datacenters Caused by High-Density Computing Peter Hannaford Director of Business Development EMEA."— Presentation transcript:

1 Dealing with Hotspots in Datacenters Caused by High-Density Computing Peter Hannaford Director of Business Development EMEA

2 InfraStruXure™ for Data Centers Thermal Management  The increase in power densities in modern electronics is having a direct impact on the environment housing them  Thermal management of equipment housed in an enclosure is fast becoming the most serious risk to availability in today’s Mission Critical Facilities (MCF)  Cooling high power density equipment demands a far more accurate method of controlling air movement in an MCF

3 InfraStruXure™ for Data Centers Cooling the server

4 InfraStruXure™ for Data Centers Cooling the cabinet

5 InfraStruXure™ for Data Centers Cooling the data center

6 InfraStruXure™ for Data Centers 300 cfm One 300 cfm(141.6 lps) vented tile per rack Typical Raised-Floor Airflow

7 InfraStruXure™ for Data Centers Grate tile Perf tile Blade Servers Standard IT Equipment With Effort Typical Capability Extreme Impractical 12 10 8 6 4 2 0 0 100 200 300 400 500 600 700 800 900 1000 [47.2] [94.4] [141.6] [188.8] [236.0] [283.2] [330.4] [377.6] [424.8] [471.9] Floor Tile Cooling Ability 300-500 cfm Rack Power (kW) that can be cooled by one tile with this airflow

8 InfraStruXure™ for Data Centers Rack Cooling using Sub-Floor Airflow

9 InfraStruXure™ for Data Centers Implement Hot Aisle / Cold Aisle Racks face same direction Most rack-mounted servers draw air in the front and exhaust at the rear Exhaust air mixes with cold air with no aisle separation Racks facing each other Reduced temperature in cold aisle Reduced air mixing Higher return air temperatures to CRAC

10 InfraStruXure™ for Data Centers Effect of Adding Blanking Panels Without Blanking Panels With Blanking Panels

11 InfraStruXure™ for Data Centers Install Airflow Assisting Devices  Fan-tray devices, such as APC’s Air Distribution Unit, draw air from sub-floor plenum to create cold air curtain between front door and server inlets.  Rack densities increase to 3 kW  For higher densities replace rear door of rack with APC’s Air Removal Unit to draw air in horizontal plane from cold aisle into server inlets  Rack densities increased to 7kW

12 InfraStruXure™ for Data Centers In-Row Cooling

13 InfraStruXure™ for Data Centers High Density Cooling Enclosure

14 InfraStruXure™ for Data Centers 4 x 100kW AHU Air Flow Rate: 16,000 CFM (7550L/s) Supply Temp: 17.3degC 84 NetShelter VX racks 3kW Loading per rack Server Air Flow Rate: 160 CFM /kW 75.5L/s per kW 96 Floor Tiles 40% Open Area Ratio 4 x Structural Columns Geometry: Dimensions: 16.15m x 11.65m x 3.5m Floor Area:188 m 2 Floor Void Depth: 0.5m Raised Floor to Ceiling: 3.0m Cold Aisle Hot Aisle Case Study

15 InfraStruXure™ for Data Centers Phase1 Legacy Configuration Temperature at 1.8m Above Raised Floor Level Void Pressure 0.25m from Floor Y Velocity through Floor Tiles At 1.8m above raised floor level, some of the cabinets in the top two rows are seeing inlet temperatures of up to 28 o C. Slight ingress of warm are is occurring through the gaps in the third row.

16 InfraStruXure™ for Data Centers 12 x FM IR units Volume Flow Rate: 6,500CFM (3068L/s) Supply Temp: 20.0degC 104 NetShelter VX racks 3kW Loading per racks Server Flow Rate: 160cfm /kW 75.5L/s per kW Phase1 In Row Configuration 4 x Structural Columns Geometry: Dimensions: 16.15m x 11.65m x 3.5m Cold Aisle Hot Aisle Cold Aisle FM In Row design increases space utilisation to 104 racks

17 InfraStruXure™ for Data Centers Phase1 In Row Configuration Temperature at 1.8m Very good containment is maintained across the entire room with maximum inlet temperatures at the tops of the cabinets reaching no more than 21 o C.

18 InfraStruXure™ for Data Centers With increased loads of 4.5kW per rack, In Row systems cope extremely well with maximum inlet temperatures reaching around 24 o C. Legacy systems see temperatures exceeding 30 o C. Phase1 Comparison Increased Load to 4.5kW per Cabinet Temperature at 1.8m (42U) Legacy 4.5kW, 84 Racks, Total Load = 378kWIn Row 4.5kW, 104 Racks Total Load = 468kW Legacy 3kW, 84 Racks, Total Load = 256kWIn row 3kW, 104 Racks, Total Load = 312kW

19 InfraStruXure™ for Data Centers Phase1 Comparison N+1 Failure Scenarios at 3kW per Cabinet Temperature at 1.8m (42U) Legacy 3kW, 84Racks, Total Load = 256kW Legacy AHU Failure, 84 @ 3kW = 256kW In row 3kW, 104 Racks, Total Load = 312kW In row FM IR Failure, 104 @ 3kW = 312kW Inlet temperature >30 o CInlet temperature 26-27 o C

20 InfraStruXure™ for Data Centers Conclusions  Blade servers and HD devices offer many benefits but draw from 2x to 5x the power when compared with older technology  Keep the data center operating in optimum condition to avoid equipment failures, unexplained slowdowns and shortened equipment life  Use new technology to keep HD racks cool.

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