According to one aspect, embodiments described herein provide a system and a method for modeling airflow. In one example, the system comprises a memory and a controller coupled to the memory, the controller configured to receive data related to equipment including at least two of a group comprising
According to one aspect, embodiments described herein provide a system and a method for modeling airflow. In one example, the system comprises a memory and a controller coupled to the memory, the controller configured to receive data related to equipment including at least two of a group comprising a cooling consumer and a cooling provider, compute at least one quantity of airflow between an inlet and an outlet associated with the equipment, generate a representation of at least one airflow path between the outlet and the inlet having a cross-sectional area proportional to the at least one quantity of airflow, and display the representation of the at least one airflow path in a cooling model.
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1. A system comprising: a memory; anda controller coupled to the memory and configured to:receive data related to equipment including at least two of a group comprising a cooling consumer and a cooling provider;compute quantities of airflow between an inlet and an outlet associated with the equipmen
1. A system comprising: a memory; anda controller coupled to the memory and configured to:receive data related to equipment including at least two of a group comprising a cooling consumer and a cooling provider;compute quantities of airflow between an inlet and an outlet associated with the equipment;generate a three-dimensional representation of each airflow path of a variety of airflow paths between the outlet and the inlet, the each three-dimensional representation having a cross-sectional area proportional to a quantity of airflow and is configured such that one airflow path of the variety of airflow paths does not cross one another airflow path of the variety of airflow paths, wherein each airflow path of the variety of airflow paths includes a representation of percentage of airflow;display the three-dimensional representation of each airflow path of the variety of airflow paths in a cooling model; andcontrol equipment of the group based on the computed quantity of airflow. 2. The system of claim 1, wherein each quantity of airflow comprises at least one fractional quantity of airflow including one of a fraction of airflow that originates from the cooling consumer that is captured by the cooling provider, or a fraction of airflow captured by the cooling consumer that originates from the cooling provider. 3. The system of claim 1, wherein the controller is configured to generate the representation of each airflow path such that the cross-sectional area of airflow into and out of the equipment is proportional to an inlet or an outlet area of the equipment. 4. The system of claim 3, wherein the controller is configured to generate the representation of each airflow path such that a total amount of airflow into and out of the equipment corresponds to a total inlet or outlet area of the equipment. 5. The system of claim 1, wherein the controller provides an indication for a user to arrange equipment in a data center based on the representation of each one airflow path. 6. The system of claim 1, wherein each quantity of airflow includes at least one quantity of recirculated airflow. 7. The system of claim 1, wherein the three-dimensional representation has one of a rectangular and a tubular shape. 8. The system of claim 1, wherein the controller is configured to generate the representation of each airflow path for the sources having the airflow quantities exceeding a predetermined threshold. 9. The system of claim 1, wherein the controller is configured to: compute at least one cooling power quantity as a function of heat generated by the cooling consumer and each quantity of airflow;generate a representation of at least one cooling power path from the cooling provider to the cooling consumer having a cross-sectional area based on the at least one cooling power quantity; anddisplay the representation of the at least one cooling power path in the cooling model. 10. The system of claim 1, wherein the equipment is positioned in a data center and the controller is configured to: compute each quantity of airflow between the data center and one of the inlet and the outlet associated with the equipment;generate a representation of the variety of airflow paths between the data center and the one of the inlet and the outlet; anddisplay the representation of each airflow path between the data center and the one of the inlet and the outlet in the cooling model. 11. A method comprising: receiving data related to equipment including at least two of a group comprising a cooling consumer and a cooling provider;computing, by a computer system, quantities of airflow between an inlet and an outlet associated with the equipment;generating, by the computer system, a three-dimensional representation of at least one each airflow path of a variety of airflow paths between the inlet and the outlet, the three-dimensional representation having a cross-sectional area proportional to each quantity of airflow and is configured such that one airflow path of the variety of airflow paths does not cross one another airflow path of the variety of airflow paths, wherein each airflow path of the variety of airflow paths includes a representation of percentage of airflow;displaying, by the computer system, the three-dimensional representation of each airflow path in a cooling model; andarranging equipment in a data center based on the representation of the at least one each airflow path. 12. The method of claim 11, wherein computing each quantity of airflow computing at least one fractional quantity of airflow, representing one of a fraction of airflow originating from the cooling consumer that is captured by the cooling provider, or a fraction of airflow entering the cooling consumer that originates from the cooling provider. 13. The method of claim 11, wherein generating the representation further comprises generating the representation of each airflow path such that the cross-sectional area of airflow into and out of the equipment is proportional to an inlet or an outlet area of the equipment. 14. The method of claim 13, wherein generating the representation further comprises generating the representation of each airflow path such that a total amount of airflow into and out of the equipment corresponds to a total inlet or outlet area of the equipment. 15. The method of claim 11, wherein each quantity of airflow includes at least one quantity of recirculated airflow. 16. The method of claim 11, wherein the three-dimensional representation has one of a rectangular and a tubular shape. 17. The method of claim 11, further comprising computing at least one cooling power quantity as a function of heat generated by the cooling consumer and the at least one fractional quantity of airflow;generating a representation of at least one cooling power path from the cooling provider to the cooling consumer having a cross-sectional area based on the at least one cooling power quantity; anddisplaying the representation of the at least one cooling power path in the cooling model. 18. A non-transitory computer readable medium having stored thereon sequences of instruction that will cause at least one processor to: receive data related to equipment including at least two of a group comprising a cooling consumer and a cooling provider;compute quantities of airflow between an inlet and an outlet associated with the equipment;generate a three-dimensional representation of each airflow path of a variety of airflow paths between the inlet and the outlet, the three-dimensional representation having a cross-sectional area proportional to each quantity of airflow and is configured such that one airflow path of the variety of airflow paths does not cross one another airflow path of the variety of airflow paths, wherein each airflow path of the variety of airflow paths includes a representation of percentage of airflow;display the three-dimensional representation of each airflow path in a cooling model; andcontrol equipment of the group based on the computed quantity of airflow.
Archibald, Matthew R.; Chu, Richard C.; Hamann, Hendrik F.; Iyengar, Madhusudan K.; Schmidt, Roger R., Apparatus and method for simulating heated airflow exhaust of an electronics subsystem, electronics rack or row of electronics racks.
Archibald, Matthew R.; Chu, Richard C.; Hamann, Hendrik F.; Iyengar, Madhusudan K.; Schmidt, Roger R., Method of laying out a data center using a plurality of thermal simulators.
Rasmussen, Neil; VanGilder, James W.; Buell, Scott Douglass; Shrivastava, Saurabh Kumar; Dalgas, Mikkel, Methods and systems for managing facility power and cooling.
Rasmussen, Neil; VanGilder, James W.; Buell, Scott Douglass; Shrivastava, Saurabh Kumar; Dalgas, Mikkel, Methods and systems for managing facility power and cooling.
Rasmussen, Neil; VanGilder, James W.; Dalgas, Mikkel; Berard, Stephen; Jensen, Henrik; Daae, Henrik; Schoellhammer, Sandi, Methods and systems for managing facility power and cooling.
Rasmussen, Neil; VanGilder, James W.; Dalgas, Mikkel; Berard, Stephen; Jensen, Henrik; Daae, Henrik; Schoellhammer, Sandi, Methods and systems for managing facility power and cooling.
Bash, Cullen E.; Patel, Chandrakant D.; Beitelmal, Abdimonem; Sharma, Ratnesh K., Pressure control of cooling fluid within a plenum using automatically adjustable vents.
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