Technologies for providing shared memory for accelerator sleds includes an accelerator sled to receive, with a memory controller, a memory access request from an accelerator device to access a region of memory. The request is to identify the region of memory with a logical address. Additionally, the accelerator sled is to determine from a map of logical addresses and associated physical address, the physical address associated with the region of memory. In addition, the accelerator sled is to route the memory access request to a memory device associated with the determined physical address.

A method and apparatus (“utility”) for facilitating connection of rack-mounted data devices (50) to a data network is provided. The utility includes a distribution strip (42) and a number of network ports (44), disposed on the distribution strip (42), for use in connecting the rack-mounted data devices (50) to the network. The distribution strip (42) has a longitudinal axis, and is disposed on a rack (40) such that a length of the distribution strip (42), defined relative to the longitudinal axis, extends primarily or exclusively along a vertical axis of the rack (40). The distribution strip may further include a data network switch device. A utility is also provided that provides improved redundancy with regard to connections of rack-mounted data devices by including a distribution strip (42) that includes first and second ports (46) for connecting the distribution strip (42) to a network device (56).

A locking arrangement can be used for securing electric module cards between two side walls of a housing. The locking arrangement includes two side members for fixed arrangement with the respective side walls. An opening defined between the side members accommodates electric contacts of the electric module cards. A first and a second transverse member form a frame with the side members in order to lock the electric module cards within the housing. A locking mechanism is detachably connects at least one of the transverse members to at least one of the side members by means of a snap-fit.

A power converter includes a semiconductor unit, a capacitor unit, a first input connector, a second input connector, an output connector, a housing case, a first input bus bar connecting the first input connector and the semiconductor unit, a second input bus bar connecting the second input connector and the semiconductor unit, an output bus bar connecting the semiconductor unit and the output connector, and a bus bar connecting portion at which the first input bus bar and the second input bus bar are connected. The capacitor unit is arranged in a portion of the first input bus bar between the first input connector and the bus bar connecting portion.

A fixing device includes a main body, a sliding block, and a fixing rod. The main body has a sliding rail and a guiding hole, and the sliding rail which is disposed at a front side of the main body vertically extends. The guiding hole adjoins the sliding rail and horizontally extends through the main body. The sliding block is slidably connected to the sliding rail. The fixing rod is movably connected to the sliding block extending through the guiding hole, and the sliding block is configured to move along the sliding rail and enable the guiding hole to drive the fixing rod to horizontally move.

A modular control unit (100) is adaptable, in terms of interface functions, for an electric motor selected from a predetermined number i of electric motors, in particular electric motors of the same power class. The control unit (100) has at least two printed circuit boards (L1, L2), selected from a set of N different printed circuit boards (L1, L2, . . . , LN). Interface functions, electrical components, electronic components or control units for the operation of the electric motor are located on the printed circuit boards.

A modular control unit (100) is adaptable, in terms of interface functions, for an electric motor selected from a predetermined number i of electric motors, in particular electric motors of the same power class. The control unit (100) has at least two printed circuit boards (L1, L2), selected from a set of N different printed circuit boards (L1, L2, . . . , LN). Interface functions, electrical components, electronic components or control units for the operation of the electric motor are located on the printed circuit boards.

An airflow device includes a cooling air passage structure formed external to and along a side of a server chassis, the cooling air passage structure extending in a depth direction of the server chassis from a front side of the server chassis. The airflow device further includes an airflow channel formed within the cooling air passage structure, the airflow channel extending in the depth direction, and a vent fluidically connecting the airflow channel with an interior of the server chassis at a vent location that is rearward in the depth direction relative to the front side.

A lock mechanism within a slot of a computer chassis is disclosed. The lock mechanism includes a gear wheel, a gear rack body, a push rod latch, a push rod body, and a chassis latch. The gear wheel, the gear rack body, the push rod latch, the push rod body, and the chassis latch cooperate to restrict a flap in the slot from opening when the flap is in the closed position, and the chassis latch is engaged with a cutout on the push rod body.

A drive carrier for a cold plug device of an information handling system includes a handle, a first latch, and a second latch. The handle rotates between a locked position and an unlocked position. The first latch includes first and second ends, and slides between first and second positions. The handle is held in the locked position when the first latch is in the first position. The second latch includes first and second ends. The first end of the second latch is pivotally attached to the second end of the first latch and the second end of the second latch snap fits over a first end of the handle. The second latch prevents the first latch from sliding from the first position to the second position when the second end of the second latch is snap fitted over the first end of the handle.