A plug-in pump installation structure of a cooling distribution unit is disclosed. A pump seat is disposed in a machine case and has a fixed joint. A plug-in pump has a pump main body and a moveable joint. The plug-in pump is plugged or removed relative to the pump seat through the moveable joint and the fixed joint being connected or released. One distal end of each rotary arm of a handgrip has a latching hook. The rotary arms are pivotally connected at opposite sides of the pump main body. When the handgrip is folded on the machine case, the latching hook abuts against a protrusion disposed on a block piece of the machine case, when the handgrip is rotated to be away from the machine case, the latching hooks of the rotary arm is released from the abutted protrusion.

Systems and methods for providing an electronic cooling apparatus comprising a chassis having an internal space that is sized/shaped to receive/structurally support circuit card(s). The internal space defined by sidewalls with a channel formed therein in which a coolant is disposed. The coolant is in thermal communication with the circuit card(s) via the sidewall(s) when the circuit card(s) is(are) disposed in the chassis. A refrigerant-based cooling system is disposed in the chassis and comprises an evaporator having inlet/outlet ports coupled to the channel of the chassis to define a first closed-loop channel for the coolant within the chassis. The evaporator facilitates heat transfer from the coolant to a refrigerant flowing through a second closed-loop channel of the chassis at least partially defined by the evaporator. A pump is disposed in the chassis and configured to cause the coolant to flow through the first closed-loop channel.

The present invention is a modular, energy efficient structure for housing racks of computers specifically designed for mining Bitcoin assets. The fundamental principal towards an optimized mining facility design is to decrease electricity consumption as well as effective construction budget management, ensuring only appropriate business expenditures. The side benefits including improved stability of the facility computer network and electricity supply. The design concept is carried out through a cool/hot air segregation process, which results in controllable internal facilities temperatures, dust filtration and energy savings.

The invention relates to a heat exchanger for cooling a switch cabinet, with a first line system for a first coolant and with a second line system, separated fluidically from the first line system, for a second coolant, in which the first and the second line system are coupled thermally to one another, and to a corresponding switch cabinet.

A cabinet liquid cooling system is configured to dissipate heat of a cabinet. A flow allocation unit is installed on a single side of the cabinet, is located in space between a side wall of the cabinet and a mounting bar of the cabinet, and is provided with a liquid inlet and a liquid outlet. A liquid cooling system (LCS) control unit is installed at the bottom of the cabinet and cyclically supplies liquid to the flow allocation unit using the liquid inlet and the liquid outlet. A liquid supply branch includes a liquid delivery pipe and a liquid return pipe. A node pipe includes a liquid inlet pipe and a liquid outlet pipe. Both the liquid inlet pipe and the liquid outlet pipe are connected to the corresponding liquid delivery pipe and liquid return pipe using the quick male connector and the quick female connector.

A system includes one or more first cooling loops to cool one or more first components within one or more servers having a first power density, and one or more second cooling loops to cool one or more second components within the one or more servers having a second power density. The system can flow first coolant to cold plates to cool high-power server components and flow second coolant to cool low-power server components by immersion cooling.

Systems and methods for providing a fin structure. The fin structure may be employed in a heat exchanger. The fin structure comprises: a support structure; and a plurality of fins disposed on the support structure via additive manufacturing so as to facilitate a change in direction of a fluid flowing through the fin structure. The fins comprise first fins that have centers arranged in accordance with a phyllotaxis or Fibonacci pattern.

A system for immersion cooling computing system equipment includes a container containing a volume of immersion cooling fluid. At least one heat generating computing system equipment component and a liquid-liquid heat exchanger are disposed in the volume of immersion cooling fluid. A manifold system is disposed between the heat generating computing system equipment component and the liquid-liquid heat exchanger to direct a flow of immersion cooling fluid between the heat generating computing system component and the liquid-liquid heat exchanger and to isolate the flow of immersion cooling fluid from a bulk amount of immersion cooling fluid. The flow of immersion cooling fluid and the bulk amount of immersion cooling fluid constitutes the volume of immersion cooling fluid.

An information processing apparatus includes a plurality of electronic apparatus stacked over a plurality of hierarchies in the information processing apparatus, a heat exchanger that cools refrigerant liquid for cooling the plurality of electronic apparatus, a first distributor that distributes the refrigerant liquid from the heat exchanger to the plurality of hierarchies, a plurality of second distributor that stores the refrigerant liquid temporarily, and a plurality of pipes that branched from the distribution pipes to the plurality of the electronic apparatus, wherein the number of the second distributor increases toward a hierarchy on downstream side, the pipes of the last hierarchy are coupled to the electronic apparatus.

A rack mounted cooling system operable to cool a computing system is provided. The rack mounted cooling system includes a pump unit operable to pump fluid and a plurality of heat exchangers. The heat exchangers include an input heat exchanger and an outlet heat exchanger. The input heat exchanger is operable to receive the fluid from the pump unit, lower a temperature of the fluid, and provide the fluid to a liquid cooled computing unit. The outlet heat exchanger is operable to receive the fluid from the liquid cooled computing unit, lower the temperature of the fluid, and provide the fluid to the pump unit. The heat exchangers are operable to be coupled to a rack of the computing system such that the rack with the plurality of heat exchangers fits within a rack keep in area.