Abstract: In accordance with the present disclosure, a scalable and modular rack-level power infrastructure is described. The power infrastructure may include a power distribution unit (PDU), which receives alternating current (AC) power from an external power source. The PDU may be coupled to a busbar and output DC power to the busbar. The busbar may be coupled to a server within a rack-server system and provide DC power to the server. Additionally, the infrastructure may include a battery back-up unit (BBU) element coupled to the busbar. The BBU element may charge from and discharge to the busbar.

Abstract: In accordance with the present disclosure, a scalable and modular rack-level power infrastructure is described. The power infrastructure may include a power distribution unit (PDU), which receives alternating current (AC) power from an external power source. The PDU may be coupled to a busbar and output DC power to the busbar. The busbar may be coupled to a server within a rack-server system and provide DC power to the server. Additionally, the infrastructure may include a battery back-up unit (BBU) element coupled to the busbar. The BBU element may charge from and discharge to the busbar.

Abstract: A modular, scalable and expandable (MSE) rack-based information handling system (RIHS) includes: a rack assembly having a frame that defines: a front bay chassis with height, depth and width dimensions that enable insertion of a plurality of different sizes of IT gear; and a rear bay that accommodates power and cooling components to support operation of the different sizes of IT gear. The power and cooling for the IT gear are provided from the rear bay and are separate from and independent of the IT gear installed within the front bay chassis. The rack assembly further includes a power and management chassis in which is inserted a power and management module having power and management components located thereon to provide rack-level power and management. A modular configuration of fan modules are inserted within fan receptacles within the rear bay to provide block level cooling of adjacent blocks of IT gear.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: In accordance with the present disclosure, a battery back-up unit (BBU) element for providing uninterruptable direct current (DC) power in a rack-level power infrastructure is describe. The BBU element may include a rack-mountable chassis with a battery drawer. A battery may be disposed within the battery drawer, and at least one power module may be coupled to the battery. The BBU element may also include a power module controller that causes the battery to charge from or discharge to a busbar coupled to the BBU element. The power module controller may also communicate power management information to a power infrastructure controller.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: In accordance with the present disclosure, a battery back-up unit (BBU) element for providing uninterruptable direct current (DC) power in a rack-level power infrastructure is describe. The BBU element may include a rack-mountable chassis with a battery drawer. A battery may be disposed within the battery drawer, and at least one power module may be coupled to the battery. The BBU element may also include a power module controller that causes the battery to charge from or discharge to a busbar coupled to the BBU element. The power module controller may also communicate power management information to a power infrastructure controller.

Abstract: A modular, scalable and expandable (MSE) rack-based information handling system (RIHS) includes: a rack assembly having a frame that defines: a front bay chassis with height, depth and width dimensions that enable insertion of a plurality of different sizes of IT gear; and a rear bay that accommodates power and cooling components to support operation of the different sizes of IT gear. The power and cooling for the IT gear are provided from the rear bay and are separate from and independent of the IT gear installed within the front bay chassis. The rack assembly further includes a power and management chassis in which is inserted a power and management module having power and management components located thereon to provide rack-level power and management. A modular configuration of fan modules are inserted within fan receptacles within the rear bay to provide block level cooling of adjacent blocks of IT gear.

Abstract: A power switching system, a method, and an information handling system (IHS) enables selective activation and de-activation of respective alternating current (AC) outlets of a plurality of AC outlets within an AC switch (ACS). The AC switch includes a decoder circuit that is couple via a control interface to a management controller (MC) and receives control commands from the control interface. In response to receipt of the control command, the decoder circuit decodes the command in order to provide control signals to one or more of a number of serial voltage relays, which are each respectively coupled to the AC outlets. The AC switch utilizes the decoder circuit to respectively configure the serial voltage relays using the control signals. By configuring the serial voltage relays, the MC provides and/or removes respective connections between AC inputs and AC outlets, which selectively activates and/or de-activates respective AC outlets.

Abstract: A computer-implemented method enables rack-level predictive power capping and power budget allocation to processing nodes in a rack-based IHS. A rack-level management controller receives node-level power-usage data and settings from several block controllers, including current power consumption and an initial power budget for each node. A power consumption profile is generated based on the power-usage data for each node. A total available system power of the IHS is identified. A system power cap is determined based on the power consumption profiles and the total available system power. A current power budget is determined for each node based on an analysis of at least one of the power consumption profile, the initial power budget, the current power consumption, the system power cap, and the total available system power. A power subsystem regulates power budgeted and supplied to each node based on the power consumption profiles and the system power cap.

Abstract: A rack-based information handling system (IHS) includes a rack having a modular structure that supports insertion from a front of the rack of different numbers and sizes of information technology (IT) gear to create one or more IT nodes. Power bay chassis is received in the rack with a power distribution unit directed towards a rear of the rack. A modular busbar assembly is attached to the rear of the rack. A first vertical busbar segment is in direct electrical connection with the power distribution unit and spans one or more nodes to provide hot pluggable electrical power to an aft-directed connection of an IT node inserted into the rack. A second busbar segment can be attached to the first vertical busbar to electrically communicate with the power distribution unit and span an additional node adjacent to the one or more nodes to provide electrical power to the adjacent node.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: In accordance with the present disclosure, a scalable and modular rack-level power infrastructure is described. The power infrastructure may include a power distribution unit (PDU), which receives alternating current (AC) power from an external power source. The PDU may be coupled to a busbar and output DC power to the busbar. The busbar may be coupled to a server within a rack-server system and provide DC power to the server. Additionally, the infrastructure may include a battery back-up unit (BBU) element coupled to the busbar. The BBU element may charge from and discharge to the busbar.

Abstract: In accordance with the present disclosure, a battery back-up unit (BBU) element for providing uninterruptable direct current (DC) power in a rack-level power infrastructure is describe. The BBU element may include a rack-mountable chassis with a battery drawer. A battery may be disposed within the battery drawer, and at least one power module may be coupled to the battery. The BBU element may also include a power module controller that causes the battery to charge from or discharge to a busbar coupled to the BBU element. The power module controller may also communicate power management information to a power infrastructure controller.

Abstract: A system includes a dual in-line memory module and a system board. The dual in-line memory module includes a plurality of dynamic random access memory devices, and a system management interface. The system management interface is configured to measure a first voltage provided to the dynamic random access memory devices, and configured to digitize the first voltage. The system board includes a test module and a voltage regulator. The test module is configured to receive the digitized first voltage via a connector pin between the dual in-line memory module and the system board, and configured to compare the first voltage to a first threshold voltage. The voltage regulator is configured to adjust a remote sense target voltage for the system management interface when the first voltage is less than the first threshold voltage.

Abstract: A device includes a plurality of voltage regulators, and a test module. Each of the voltage regulators are configured to provide a regulated voltage to one of a plurality of subsystems. The test module is in communication with the voltage regulators, and is configured to perform a subsystem component inventory for each of the subsystems at a start of a power-on self-test of the device, to determine a configuration of the device. The test module is also configured to capture first voltage data for the subsystems during an idle operation, to capture second voltage data for the subsystems during a stressed operation, and to set a voltage set point for each of the regulated voltages provided by one of the voltage regulators based on the subsystem component inventory, a power requirement table, or the first and second voltage data.

Abstract: A system includes a dual in-line memory module and a system board. The dual in-line memory module includes a plurality of dynamic random access memory devices, and a system management interface. The system management interface is configured to measure a first voltage provided to the dynamic random access memory devices, and configured to digitize the first voltage. The system board includes a test module and a voltage regulator. The test module is configured to receive the digitized first voltage via a connector pin between the dual in-line memory module and the system board, and configured to compare the first voltage to a first threshold voltage. The voltage regulator is configured to adjust a remote sense target voltage for the system management interface when the first voltage is less than the first threshold voltage.

Abstract: A device includes a plurality of voltage regulators, and a test module. Each of the voltage regulators are configured to provide a regulated voltage to one of a plurality of subsystems. The test module is in communication with the voltage regulators, and is configured to perform a subsystem component inventory for each of the subsystems at a start of a power-on self-test of the device, to determine a configuration of the device. The test module is also configured to capture first voltage data for the subsystems during an idle operation, to capture second voltage data for the subsystems during a stressed operation, and to set a voltage set point for each of the regulated voltages provided by one of the voltage regulators based on the subsystem component inventory, a power requirement table, or the first and second voltage data.