The present disclosure relates to a mounting platform for use in an equipment rack having a frame with a pair of spaced apart vertical frame elements. The mounting platform supports at least one external device adjacent a rear area of the equipment rack without interfering with use of internal device mounting locations within the equipment rack. The mounting platform makes use of a gate panel which is configured to support the external device thereon. At least one hinge is used to support the gate panel in a vertical orientation from one of the vertical frame elements. The gate panel is movable between a closed position and an open position. In the closed position the gate panel is positioned parallel to a line extending between the vertical frame elements and supports the external device adjacent to the rear area of the equipment rack. In the open position the gate panel is positioned substantially perpendicular to the line extending between the vertical frame elements, and does not impede access to the internal device mounting locations within the equipment rack.

A method of making a data centre is disclosed, comprising making a data centre in an existing building (3010) having a floor, walls and a roof, an air inlet and an air outlet. The method includes: installing prefabricated data centre elements by (a) connecting to the inlet an air handling module (3001, 3002); and (b) installing cold aisle services modules (3011) each having one or more integrated blanking portions and one or more data centre services extending along its length terminating with a connection to an adjacent module (3011); and installing racks of IT equipment arranged in parallel rows; the method being so performed that the floor, racks, and cold aisle services modules (3011) together define parallel cold aisles for entraining cooling air flows to the IT equipment. Also disclosed are a data centre, a service carrying frame and a cold aisle services module for a data centre and a supporting frame for supporting prefabricated data centre elements.

A device for covering a portion of a server rack includes a main body having a front side, a back side, and a longitudinal axis, a locking element connected to a first longitudinal end of the main body, and an anchor element at a second longitudinal end of the main body. The anchor element is configured to engage with and slide longitudinally relative to the server rack.

A backplane management and configuration system includes a chassis housing a first storage system having a first backplane, a second storage system having a second backplane, a second computing device coupled to each of the first backplane and the second backplane via a second multiplexer and a communication bus, and a first computing device coupled to each of the first backplane and the second backplane via a first multiplexer and the communication bus. A backplane configuration/management subsystem in the first computing device detects a multi-computing-device configuration including the first and second computing devices in the chassis and, in response, determines a first computing device location in the chassis. Based on the first computing device location, the backplane configuration/management subsystem identifies a first backplane identifier for the first backplane and, in response, configures the first backplane for management by the backplane configuration/management subsystem and ignores the second backplane.

Example implementations relate to a latch and a computing system including such latch. The latch may include a latch enclosure and a latch assembly housed at least partially within the latch enclosure. The latch assembly may include a lever mounted to the latch enclosure via a first pivot pin and having a handle section disposed outside the latch enclosure and a force transfer section integrated with the handle section and disposed inside the latch enclosure. Further, the latch may include a hook engaged with the lever and mounted at least partially within the latch enclosure via a second pivot pin, wherein a movement of the lever about the first pivot pin causes a movement of the hook about the second pivot pin via the force transfer section.

A foldable cabinet framework includes two side frames, a first beam body, and a second beam body, where two opposite ends of each of the first and second beam bodies are respectively connected to the two side frames. The first beam body and the second beam body each include a hinged part, and when the first beam body and the second beam body are in a straight state, the first beam body and the second beam body are supported between the two side frames, so that the two side frames are spaced apart and symmetrically disposed. The first beam body and the second beam body enclose a framework of a three-dimensional structure. The first beam body and the second beam body are folded by using the hinged part; and after the first beam body and the second beam body are folded, the two side frames are superposed with each other.

A fluid distribution system is incorporated into a server chassis. Connector plates have fluid connectors designed to connect with fluid cooling receptacles on server boards. A linkage system can be manually manipulated to translate the connector plates so as to engage the electronics boards and connect the fluid connectors to the receptacle. A pair of main connectors connect to the rack's fluid manifold to circulate cooling fluid to cool devices mounted onto the server boards. A locking mechanism can be included to mechanically lock the chassis to the rack to prevent accidental dismount of the chassis from the rack. Also, an anchor mechanism may be provided to apply counter force when engaging the connector plates with the server boards so as to prevent accidental dismount of the server board by the moving connector plate.

The invention relates to a switch cabinet arrangement with at least one IT rack or switch cabinet housing and with at least one cooling device, which has an air-liquid heat exchanger for cooling components accommodated in the IT rack or switch cabinet housing with cooled air, wherein the air-liquid heat exchanger comprises a first flow for cooled liquid and a first return for heated liquid, wherein the cooling device comprises a liquid-liquid heat exchanger, to the second flow of which the first return of the air-liquid heat exchanger is connected. A corresponding method is further described.

Disclosed is a computer case with I/O panels on opposite sides of the case, and a method for providing the case. The case includes a top, a bottom, a back side that is opposite a front side, and a right side that is opposite a left side. The case also includes a front I/O opening formed in the front side that receives a front I/O panel. The computer case also includes a rear I/O opening in the back side that receives a rear I/O panel.

A quick release mechanism includes a fixed component, a first assembly, and a second assembly. The fixed component has a guiding portion and a first positioner. The first assembly includes an engagement component and a return component. The engagement component is pivotably disposed on the fixed component and includes a first protrusion part, a first press part, and a second positioner. The return component keeps the engagement component in an engaged position. The second assembly is removably inserted into the guiding portion. The second assembly includes a second protrusion part and a contact part. The engagement component is movable away from the engaged position by abutting of the second protrusion part on the first protrusion part or by abutting of the contact part on the first press part during insertion of the second assembly into the guiding portion.