Abstract: A power controller allocates input power to a datacenter between computing power for computing services, backup power, and overhead power for overhead systems. The power controller reallocates the overhead power and/or the backup power to the computing power. This may increase the overall utilization of the datacenter by allowing additional processing power of the servers to be used.

Abstract: A system outputs data for performing an operation. The system confirms an identity of a device on which to perform the operation by receiving an input from the device and verifying that the input matches a known identifying information of the device. The system allows the operation to be performed on the device after confirming the identity of the device. The system receives feedback from a monitoring system that monitors states of a plurality of devices including the device, including a state of the device after the operation is performed on the device. The system determines whether the state of the device received in the feedback matches an expected state of the device after the operation is performed on the device. The system outputs data for performing a next operation after determining that the state of the device received in the feedback matches the expected state of the device.

Abstract: A design for the electrical infrastructure of a data center enables two different configurations to be utilized, including a distributed, redundant configuration that provides higher reliability and a non-redundant configuration that provides higher capacity. In the distributed, redundant configuration, each server in the data center draws power from at least two different power supply systems. This enables load shifting when a power supply system becomes unavailable, which can have the effect of increasing server reliability. In the non-redundant configuration, each server in the data center draws power from only one power supply system. Load shifting is not utilized in the non-redundant configuration, which eliminates the need to maintain reserve capacity and thereby increases capacity. Advantageously, it is possible to switch between these two configurations without making any internal changes to the data center other than modifying connections between sets of server racks and power buses.

Abstract: A method of power management in a datacenter includes obtaining at least one workload status of at least one server rack, obtaining at least one infrastructure parameter, obtaining at least one utility telemetry, and comparing the at least one workload status to the at least one utility telemetry. The method further includes determining a workload demand based at least partially on a difference between the at least one workload status and the at least one utility telemetry and changing the at least one infrastructure parameter based on the workload demand and the at least one infrastructure parameter.

Abstract: A system outputs data for performing an operation. The system confirms an identity of a device on which to perform the operation by receiving an input from the device and verifying that the input matches a known identifying information of the device. The system allows the operation to be performed on the device after confirming the identity of the device. The system receives feedback from a monitoring system that monitors states of a plurality of devices including the device, including a state of the device after the operation is performed on the device. The system determines whether the state of the device received in the feedback matches an expected state of the device after the operation is performed on the device. The system outputs data for performing a next operation after determining that the state of the device received in the feedback matches the expected state of the device.

Abstract: A cooling system includes one or more air channeling sub-systems that provide cooling air to electronic equipment, at least one heat removal sub-system that removes heat from the cooling air in at least one of the air channeling sub-systems, at least one temperature sensor measures a wet bulb temperature of outside air, and at least one controller. At least one of the air channeling sub-systems includes an outside air damper operable allow outside air into the air channeling sub-system. The at least one controller at least partially opens the outside air damper if a wet bulb temperature measured at the at least one temperature sensor drops to or below a predetermined temperature.

Abstract: A system outputs data for performing an operation. The system confirms an identity of a device on which to perform the operation by receiving an input from the device and verifying that the input matches a known identifying information of the device. The system allows the operation to be performed on the device after confirming the identity of the device. The system receives feedback from a monitoring system that monitors states of a plurality of devices including the device, including a state of the device after the operation is performed on the device. The system determines whether the state of the device received in the feedback matches an expected state of the device after the operation is performed on the device. The system outputs data for performing a next operation after determining that the state of the device received in the feedback matches the expected state of the device.

Abstract: A design for the electrical infrastructure of a data center enables two different configurations to be utilized, including a distributed, redundant configuration that provides higher reliability and a non-redundant configuration that provides higher capacity. In the distributed, redundant configuration, each server in the data center draws power from at least two different power supply systems. This enables load shifting when a power supply system becomes unavailable, which can have the effect of increasing server reliability. In the non-redundant configuration, each server in the data center draws power from only one power supply system. Load shifting is not utilized in the non-redundant configuration, which eliminates the need to maintain reserve capacity and thereby increases capacity. Advantageously, it is possible to switch between these two configurations without making any internal changes to the data center other than modifying connections between sets of server racks and power buses.

Abstract: A data center includes various sets of infrastructure modules which each provide a particular type of infrastructure support to support computing operations in the data center. Separate sets of infrastructure modules can be installed incrementally based on incrementally changing support capacity for the corresponding type of infrastructure support in the data center. Such incrementally changing support capacity can be based upon support requirements of electrical loads, including rack computer systems, which are inbound to the data center. Where support capacity for a particular type of infrastructure support drops below a threshold, a quantity of additional infrastructure modules which provide the particular type of infrastructure support can be selected and installed to increase the support capacity.

Abstract: A design for the electrical infrastructure of a data center enables two different configurations to be utilized, including a distributed, redundant configuration that provides higher reliability and a non-redundant configuration that provides higher capacity. In the distributed, redundant configuration, each server in the data center draws power from at least two different power supply systems. This enables load shifting when a power supply system becomes unavailable, which can have the effect of increasing server reliability. In the non-redundant configuration, each server in the data center draws power from only one power supply system. Load shifting is not utilized in the non-redundant configuration, which eliminates the need to maintain reserve capacity and thereby increases capacity. Advantageously, it is possible to switch between these two configurations without making any internal changes to the data center other than modifying connections between sets of server racks and power buses.

Abstract: A design for the electrical infrastructure of a data center enables two different configurations to be utilized, including a distributed, redundant configuration that provides higher reliability and a non-redundant configuration that provides higher capacity. In the distributed, redundant configuration, each server in the data center draws power from at least two different power supply systems. This enables load shifting when a power supply system becomes unavailable, which can have the effect of increasing server reliability. In the non-redundant configuration, each server in the data center draws power from only one power supply system. Load shifting is not utilized in the non-redundant configuration, which eliminates the need to maintain reserve capacity and thereby increases capacity. Advantageously, it is possible to switch between these two configurations without making any internal changes to the data center other than modifying connections between sets of server racks and power buses.

Abstract: A bus architecture for supplying power to loads in a datacenter includes a first DC bus including a first bus conductor and a first plurality of source/load groups. Each of the first plurality of source/load groups includes a first power source and a first plurality of loads, wherein at least one of the first plurality of loads includes a server rack. The first power source in each of the first plurality of source/load groups is sized to supply power to the first plurality of loads for the corresponding one of the first plurality of source/load groups. The first power source in each of the first plurality of source/load groups is also sized to provide excess capacity to be shared by the first plurality of loads corresponding to other ones of the first plurality of source/load groups.

Abstract: A system for performing computing operations in a data center includes one or more sets of computer systems, one or more primary power systems, and a reserve power system. The primary power systems include at least one power distribution unit that supplies power to at least one of the sets of computer systems. The reserve power system automatically supplies power to at least one of the sets of computer systems if a condition is met (such as a failure of the primary power system).

Abstract: Air quality inside a computing device is monitored utilizing an air quality monitor that can be sized to simulate a server computing device and can have multiple sensing equipment mounted inside, including equipment to detect corrosive aspects in the air and condensation sensing equipment to detect instances in which condensation can form on computing device hardware. Corrosion sensing can include metallic members that can be electrically coupled to voltage that can induce a current within the metallic members, thereby more accurately simulating the corrosion of operating PCBs. Condensation sensing can include condensation hosting members that can have a thermal mass that is approximately equal to the thermal mass of PCBs and can include heating elements by which the condensation hosting members can more accurately simulate the thermal effects and aspects of operating PCBs, and also moisture detectors, including electrical and optical moisture detectors. Additionally, an off-gassing chamber can be included.

Abstract: A method for facilitating increased utilization of a data center includes receiving information about availability of components in a data center's electrical infrastructure and about power consumption of servers in the data center. The method may also include detecting that the power consumption of the servers in the data center exceeds a reduced total capacity of the electrical infrastructure. The reduced total capacity may be caused by unavailability of at least one component in the data center's electrical infrastructure. The method may also include causing power management to be performed to reduce the power consumption of the servers so that the power consumption of the servers does not exceed the reduced total capacity of the electrical infrastructure of the data center.

Abstract: A modular computing system for a data center includes one or more data center modules including rack-mounted computer systems. An electrical module is coupled to the data center modules and provides electrical power to computer systems in the data center modules. One or more air handling modules are coupled to the data center modules. The data center module may include two pre-fabricated portions, each portion including a row of racks of computer systems. The two computing module portions of the data center module may combine to form a computing space when coupled to one another.

Abstract: A method of adding a power feed to electrical systems includes coupling a set of input lines to a power source such that the input lines are connected to at least one phase of AC power from the power source, and coupling a set of backfeed lines to an output receptacle in a power distribution unit. The output receptacle may be connected in parallel with at least one other output receptacle that is supplying primary power to systems in the data center. The set of backfeed lines and the set of input lines may be tested to determine a match between a pair of lines in the set of backfeed lines and a pair of lines in the set of input lines. Determining the match may include matching the phase of the pair of backfeed lines with the phase of the pair of input lines.

Abstract: A data center includes various sets of infrastructure modules which each provide a particular type of infrastructure support to support computing operations in the data center. Separate sets of infrastructure modules can be installed incrementally based on incrementally changing support capacity for the corresponding type of infrastructure support in the data center. Such incrementally changing support capacity can be based upon support requirements of electrical loads, including rack computer systems, which are inbound to the data center. Where support capacity for a particular type of infrastructure support drops below a threshold, a quantity of additional infrastructure modules which provide the particular type of infrastructure support can be selected and installed to increase the support capacity.

Abstract: Air quality inside a computing device is monitored utilizing an air quality monitor that can be sized to simulate a server computing device and can have multiple sensing equipment mounted inside, including equipment to detect corrosive aspects in the air and condensation sensing equipment to detect instances in which condensation can form on computing device hardware. Corrosion sensing can include metallic members that can be electrically coupled to voltage that can induce a current within the metallic members, thereby more accurately simulating the corrosion of operating PCBs. Condensation sensing can include condensation hosting members that can have a thermal mass that is approximately equal to the thermal mass of PCBs and can include heating elements by which the condensation hosting members can more accurately simulate the thermal effects and aspects of operating PCBs, and also moisture detectors, including electrical and optical moisture detectors. Additionally, an off-gassing chamber can be included.

Abstract: A data center includes a plurality of racks on a floor and one or more fire suppression systems coupled to at least some of the racks. The fire suppression systems include reservoirs mounted on the racks, a fire suppression material in the reservoir, and one or more material dispensing devices coupled to the reservoir. The material dispensing devices may dispense fire suppression material onto or into the racks in response to a fire condition.