The motor driving device is to be mounted to a control panel, and includes: a motor driving device main body; a radiator disposed to face a rear surface of the motor driving device main body; a fan motor unit being disposed above the radiator and being withdrawable through an area above the motor driving device main body; and a floor sheet member configured to be laid out along a withdrawal route of the fan motor unit in a process of withdrawing the fan motor unit.

The motor driving device is to be mounted to a control panel, and includes: a motor driving device main body; a radiator disposed to face a rear surface of the motor driving device main body; a fan motor unit being disposed above the radiator and being withdrawable through an area above the motor driving device main body; and a floor sheet member configured to be laid out along a withdrawal route of the fan motor unit in a process of withdrawing the fan motor unit.

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.

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 server case includes a case, a drawer body, and a adjustable device. The drawer body is received in the case. The adjustable device includes a first end, a second end, and a adjustable structure. The second end is connected to the drawer body, the adjustable structure is connected to the first end and the second end, and a distance between the first end and the second end is changeable. The drawer body received in the case is moved until at least a part of the drawer body is located outside the case, to change the distance between the first end and the second end.

A server case includes a case, a drawer body, and a adjustable device. The drawer body is received in the case. The adjustable device includes a first end, a second end, and a adjustable structure. The second end is connected to the drawer body, the adjustable structure is connected to the first end and the second end, and a distance between the first end and the second end is changeable. The drawer body received in the case is moved until at least a part of the drawer body is located outside the case, to change the distance between the first end and the second end.

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.

A server rack for supporting a plurality of servers of varying heights includes opposing side walls each including one or more vertical tracks. A first column of holes is disposed in one of the vertical tracks and a second column of holes disposed in a corresponding opposing vertical track of the opposing side wall. A third and fourth column of holes are disposed adjacent to and corresponding to the first column of holes and the second column of holes. A first pair of opposing rails are each disposed on the opposing side walls. Each of the opposing rails are mechanically secured to the one or more vertical tracks at the first and second columns of holes. The first pair of opposing rails are configured to support a first server having a first height. For the first and second columns of holes, the spacing between holes is predefined to accommodate opposing rails to support servers of the first height. For the third and fourth columns of holes, the spacing between holes is predefined to accommodate rails to support servers of a second different height and a different size than the first server.

A multifunctional base includes a flexible member and a base connected to an end of the flexible member. The base includes a rigid shell, a connecting edge extends along a periphery of the rigid shell, the flexible member is connected to the base via the connecting edge, and the connecting edge is made of flexible material. A connecting structure and an electronic device are also provided.

A multifunctional base includes a flexible member and a base connected to an end of the flexible member. The base includes a rigid shell, a connecting edge extends along a periphery of the rigid shell, the flexible member is connected to the base via the connecting edge, and the connecting edge is made of flexible material. A connecting structure and an electronic device are also provided.