In some examples, an electronic device for mounting in a chassis includes a housing to be received in the chassis, and a mechanical intrusion indication segment to move from a retracted position to an extended position responsive to mounting of the housing in the electronic device. The mechanical intrusion indication segment when in the extended position is to break upon removal of the housing from the chassis. A controller is to detect an intrusion of the electronic device in response to breaking of the mechanical intrusion indication segment.

A handle module applicable to a server or a server system is provided. The handle module includes a handle and a plate. The handle includes a sliding column assembly. The plate includes a first sliding rail and a second sliding rail. The sliding column assembly is pivotably and slidably disposed in the first sliding rail and the second sliding rail. A user pushes the handle to install the server in a rack.

Technologies for dynamic accelerator selection include a compute sled. The compute sled includes a network interface controller to communicate with a remote accelerator of an accelerator sled over a network, where the network interface controller includes a local accelerator and a compute engine. The compute engine is to obtain network telemetry data indicative of a level of bandwidth saturation of the network. The compute engine is also to determine whether to accelerate a function managed by the compute sled. The compute engine is further to determine, in response to a determination to accelerate the function, whether to offload the function to the remote accelerator of the accelerator sled based on the telemetry data. Also the compute engine is to assign, in response a determination not to offload the function to the remote accelerator, the function to the local accelerator of the network interface controller.

A slide rail assembly includes a first rail, a second rail and first function member. The first rail has a passage. The second rail is movably mounted in the passage of the first rail. The least one function member is arranged on the first rail and adjacent to an end portion of the first rail. The least one function member includes a first function portion located in the passage and a second function portion exceeding the end portion of the first rail. When the second rail is moved along a direction from a predetermined position and a rail section of the second rail exceeds the end portion and is located at outside of the channel of the first rail, the second function portion of the least one function member is configured to support at least one part of the rail section of the second rail.

A slide rail assembly adapted for a rack includes a first slide rail, a fitting, and a second slide rail. The first slide rail is movable with respect to the rack between a first position and a second position. The fitting is configured to be mounted on the first slide rail and includes at least one guiding structure. The second slide rail is configured to be guided by the at least one guiding structure of the fitting while being outside a channel of the first slide rail and thus enter the channel.

A service system and a server capable of increasing an operation rate of a production base are provided. The server acquires operation information of a component mounter in a mounting work from a host computer in the production base. The server generates analyzed result data obtained by analyzing the operation information based on the types of the manufacturers (component manufacturer and the package manufacturer) of electronic component and the package. The server transmits the generated analyzed result data to host computers in the other production bases.

A linear motion actuation system and method of using the same may be utilized for installing or removing a server blade within a server rack, via a linear motion assembly fastened to a server blade and configured for linear motion with the server blade; a bracket fastened to a server rack; and at least one linear motion actuator comprising: a first component secured with the linear motion assembly; and a second component movably secured with the first component and secured with the bracket. The second component is configured for at least substantially linear movement relative to first component, and the at least one linear motion actuator is configured to, upon receipt of a signal from a controller, move the second component in an at least substantially linear direction relative to the first component to move the server blade relative to the server rack.

A retention assembly includes a first retention member with a first set of ribs and a second set of ribs. The first set of ribs are positioned to form slots, which are shaped to receive data storage devices. The first set of ribs are arranged to separate adjacent data storage devices and have a first length. The second set of ribs extend into respective slots to form air channels within the slots, and the second set of ribs have a second length that is shorter than the first length.

A configurable multi-orientation device mount rack system includes a rack including a first rack shelf. A first device housing is defined by the rack and the first rack shelf. A first device mounting subsystem is included on the rack and that is configurable to mount each of a plurality of devices in the first device housing and to the rack in a first orientation. A second device mounting subsystem is included on the first rack shelf and that is configurable to mount each of a plurality of devices in the first device housing and to the rack in a second orientation that is different than the first orientation. As such, each of a plurality of devices may be positioned in and mounted to the rack in the first device housing in either a “vertical”/side-by-side orientation or a “horizontal”/stacked orientation.

Technologies for switching network traffic include a network switch. The network switch includes one or more processors and communication circuitry coupled to the one or more processors. The communication circuity is capable of switching network traffic of multiple link layer protocols. Additionally, the network switch includes one or more memory devices storing instructions that, when executed, cause the network switch to receive, with the communication circuitry through an optical connection, network traffic to be forwarded, and determine a link layer protocol of the received network traffic. The instructions additionally cause the network switch to forward the network traffic as a function of the determined link layer protocol. Other embodiments are also described and claimed.