A portable blockchain mining system is disclosed comprising: a portable building; a plurality of blockchain mining processors mounted within, or a plurality of blockchain mining processor mounts located within, an interior of the portable building; an air inlet defined in the portable building; an air outlet defined in the portable building above the air inlet and oriented to direct exhaust air out of the portable building; and a cooling fan connected to convey air through the air inlet, across the plurality of blockchain mining processors and out the air outlet.

A cable harness includes a support frame configured to support a plurality of cables coupled to an electronic device. The cable harness also includes a tapered frame comprising a first end and a second end. The second end is smaller than the first end and the first end is coupled to the support frame. The cable harness further includes an attachment portion coupled to the tapered frame at the second end. The attachment portion is configured to attach the cable harness to the electronic device.

A network device includes a shelf configured to support interface cards on a front side; a control module including a first frame and a printed circuit board disposed to the first frame, wherein the control module is configured to connect on a rear side of the shelf; and a cooling module including a second frame and cooling fans disposed to the second frame, wherein the second frame is configured slidingly connect to the first frame on the rear side of the shelf.

An assembly includes a ring frame having first and second open sides and an electrical connector block; a mounting structure to which the ring frame is secured; a plurality of power and signal cable connection points defined on the ring frame; and a plurality of power and signal cables coupled to the power and signal cable connection points and the connector block. First and second covers are secured to the ring frame. Each of the first and second covers is open on one side facing the ring frame and defines a mounting cavity. A plurality of heat-dissipating electronic components are mechanically and thermally coupled to the first and second covers and located in the mounting cavities. The heat-dissipating electronic components are releasably electrically coupled to the electrical connector block.

An optical midplane includes an airframe having a first side on which first modules are disposed and a second side on which second modules are disposed. The airframe is to provide for optimized airflow through the first modules disposed on the first side. A plurality of optical connectors are disposed at respective locations on the airframe to provide optical connectivity. Optical connectivity is provided between at least one of any first module disposed on the first side of the airframe and any second module disposed on the second side of the airframe, any first modules disposed on the first side of the airframe, and any second modules disposed on the second side of the airframe.

A thermal control system for pluggable optics in an optical telecom platform. The thermal control system comprises a thermal interface and one or more actuators. The thermal interface is configured to dissipate heat from a pluggable optical module in the optical telecom platform. The one or more actuators configured to change a position of the pluggable optical module relative to the thermal interface such that a thermal resistance between the pluggable optical module and the thermal interface is different based on a position of the pluggable optical module relative to the thermal interface.

A heat exchanger includes a vapor collection pipe, a liquid collection pipe, and an exchange pipeline. The exchange pipeline includes a condensing section, an evaporation section, and a transition section. An upper end of the condensing section is connected to the vapor collection pipe. A lower end of the condensing section is connected to a first end of the transition section. An upper end of the evaporation section is connected to a second end of the transition section. A lower end of the evaporation section is connected to the liquid collection pipe. The evaporation section and the condensing section respectively extend in directions opposite to each other.

A cabinet is provided, including a case and a fin element. The case has at least one opening. The fin element is disposed in the case and is adjacent to the at least one opening and includes a main body and a plurality of fins, wherein the fins are disposed on the main body and face the at least one opening.

Apparatuses, systems, and associated methods of manufacturing are described that provide a cooling system for network connections. An example system includes a networking cage assembly that receives a networking cable and a water block that circulates water. The system includes a thermal unit that includes a thermal medium. The thermal medium defines a static end that thermally engages the water block and a dynamic end opposite the static end that is disposed within the networking cage assembly. In an operational configuration in which the networking cable is received by the networking cage assembly, a portion of the dynamic end thermally engages the networking cable so as to dissipate heat from the networking cable to the thermal medium, the thermal medium conducts the heat from the dynamic end to the static end, and the static end dissipates heat from the thermal medium via thermal engagement with the water block.

To achieve multiple benefits, a high speed computing system is configured in a hierarchical manner with flexibility and re-configurability concerns maximized. This begins with a particular cabinet architecture which is specifically designed to accommodate various needs and considerations. The cabinet or rack is designed to receive various chassis assemblies depending on the particular needs and or functions involved. These may include a compute chassis, a switch chassis, or a rectifier chassis, which can be incorporated into the cabinet. Within each chassis, specific components are then inserted, with each of these components being in a subsystem configuration. For example, the compute chassis is specifically designed to receive a number of compute blades. Similarly, the switch chassis is designed to receive a number of switch blades. Lastly, the rectifier chassis is configured to receive a number of rectifiers. Collectively, the multiple blades and chassis are all configured to cooperate with one another in an efficient manner. While various subassemblies are utilized, the cabinet or rack does accommodate certain centralized functions such as cooling and power distribution.