An electronic device may include a receptacle cage comprising a longitudinal aperture extending along a portion of a top surface of the receptacle cage, a cooling body disposed directly on the top surface of the receptacle cage, wherein a longitudinal portion of a bottom surface of the cooling body is disposed within the longitudinal aperture on the top surface of the receptacle cage, a first conduit to deliver a liquid coolant into an interior of the cooling body, and a second conduit to deliver the liquid coolant from the interior of the cooling body.

A preconfigured weather-resistant enclosure assembly for terminating telecommunication equipment that includes at least one access panel for gaining access to an interior portion, the interior portion of the weather-resistant enclosure including a backboard portion for mounting telecommunication equipment, and at least one internal bus bar to provide electrical ground. A set of one or more solar panels mechanically coupled to the weather-resistant enclosure. The solar panels are typically mechanically coupled to the top side of the weather-resistant enclosure. A renewable energy power management system that includes one or more outputs that provide at least one of 100 VAC-120 VAC power, 220 VAC-240 VAC, 24 VDC-48 VDC, or a combination thereof, the renewable energy power management system is positioned inside the interior portion of the weather-resistant enclosure, the renewable energy power management system includes one or more inputs electrically coupled to the set of one or more solar panels.

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.

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.

The invention provides a heat dissipating device comprising: a heat generating unit, which generates heat when under operation and is placed at a first side of the heat dissipating device; a heat sensitive object, which is place at a second side of the heat dissipating device; and an air layer, which is arranged in between the heat generating unit and the heat sensitive object. The heat generated by the heat generating unit is isolated by the air layer.

An electrical system includes modules and a frame structure for mechanically supporting the modules successively in an arrival direction of cooling air. Each module includes a cooling element in heat conductive relation with one or more electrical components. The frame structure mechanically supports the modules so that the cooling elements are substantially in the same attitude and successively in the arrival direction of the cooling air. The cooling elements are shaped so that, when the modules are mechanically supported by the frame structure, the cooling elements conduct cooling air in a direction deviating from the arrival direction of the cooling air. Furthermore, at least a part of a flank of the heat transfer portion of each cooling element is oblique with respect to the arrival direction of the cooling air. Thus, each of the cooling elements receives a fresh portion of the cooling air.

In some examples, an apparatus includes electronic equipment and a port assembly electrically coupled to the electronic equipment. The port assembly can include a port to receive a plug as well as an electromagnetic interference (EMI) grounding member disposed on the periphery of the port assembly. The apparatus can further include a housing to securely house the equipment. The housing can include a panel with a panel opening for the port assembly. The panel opening can include a vent portion to permit air venting for the electronic equipment through the vent portion of the panel when a plug is plugged into the port.

A module for a networking node is disclosed. The module includes a Printed Circuit Board (PCB); one or more circuits mounted to the PCB; and a faceplate that including a plurality of plates, angled relative to one another, such that the faceplate includes increased surface area relative to a substantially flat faceplate, wherein at least two plates of the plurality of plates include physical ports each having track lengths to a circuit of one or more circuits, wherein one or more of the physical ports support signals at a rate of at least 100 Gbps. Each plate of the plurality of plates can be flat. Any of the plurality of plates can include physical ports. The physical ports can be pluggable modules. Each type of the physical ports can be a same type on a given plate.

There is provided a telecommunications network equipment unit, comprising a cooling system. The cooling system comprises an air input channel and an exhaust air output, wherein the exhaust air output is separate from the air input channel. The cooling system further comprises a plurality of air conduits. The plurality of air conduits is arranged such that heat can be transferred from respective ones of a plurality of devices in the telecommunications network equipment to air passing through respective ones of the plurality of air conduits. Each of the plurality of air conduits is arranged to receive a respective outflow of air from the air input channel and to direct said outflow of air therethrough to the exhaust air output. There is further provided telecommunications network equipment comprising one or more telecommunications network equipment units.

A telecommunications system is disclosed herein. The telecommunications system includes a chassis defining a top end, a bottom end, and a generally pyramidal shape, wherein a transverse cross-sectional footprint of the chassis changes in outer dimension as the transverse cross-sectional footprint extends from the top end to the bottom end, the telecommunications chassis further defining at least one sidewall, the at least one sidewall extending at an angle to both the top end and the bottom end, the at least one sidewall defining ports defining connection locations for receiving telecommunications equipment.