A rack system for housing an electronic device comprising: an immersion case configured to provide housing to the electronic device, and to receive an immersion cooling liquid, wherein the immersion case includes a drainage opening, wherein the drainage opening is configured to remove at least a part of the immersion cooling liquid from the immersion case, based on a user actuated action, during a de-racking operation of the immersion case; and a rack frame configured to slidably accommodate racking and de-racking operations of the immersion case.

A rack system for housing an electronic device comprises an immersion case configured to provide housing to the electronic device. The immersion case includes a first wall, and a second wall. The first wall and the second wall define means for controlling deformation of the immersion case, such that when an immersion cooling liquid is inserted in the immersion case, the means for controlling deformation limit the deformation of the immersion case.

A rack system for use, e.g., in data centers is disclosed. The rack system includes a rack frame and a rack-mounted assembly, including an electronic device disposed within the rack-mounted assembly, the electronic device including a heat-generating component. The heat-generating component is in thermal contact with a liquid cooling block through which a channelized cooling fluid is conveyed. The electronic device is immersed in a dielectric immersion cooling liquid. The rack-mounted assembly includes a non-sealed immersion case in which the electronic device is immersed in the dielectric immersion cooling liquid, the non-sealed immersion case configured to permit the rack-mounted assembly to be individually inserted into or removed from the rack frame. Also disclosed are container-based data center modules based on the disclosed rack system, and a data center using numerous such container-based modules.

A cooling device mountable on an electronic component comprising: a body having an internal fluid conduit for allowing a heat-transfer fluid to flow therethrough. The body comprises a first surface configured for mounting on the electronic component and permitting thermal transfer therethrough; a second surface; at least one side wall extending between the first surface and the second surface; and a gasket extending along the at least one side wall or a perimeter of the first surface, the gasket configured to extend away from the body beyond the first surface in a direction transverse thereto, to fluidly insulate the first surface when the first surface is mounted on the electronic component and submerged in the immersion cooling liquid in use.

A double-reeved lifting device includes a lower reeve block secured to a lifting hook and an upper reeve block, wherein the two reeve blocks include reversible connection means adapted to be reversibly configured between a connected configuration and a disconnected configuration. The reversible connection means include a locking mechanism and a complementary locking structure having a frame securely supporting a bolt. The locking mechanism includes a chassis having a locking channel provided with a mouthpiece through which the bolt is configured to enter and exit and slide in the locking channel respectively upon a relative approach or distancing between the two reeve blocks, and at least one latch pivotally mounted on the chassis so as to pivot inside the locking channel, the latch provided with a free end adapted to engage with the bolt.

A double-reeved lifting device includes a lower reeve block secured to a lifting hook and an upper reeve block, wherein the two reeve blocks include reversible connection means adapted to be reversibly configured between a connected configuration and a disconnected configuration. The reversible connection means include a locking mechanism and a complementary locking structure respectively having at least one striker orifice and a bolt slidably movable and supporting a locking finger adapted to rotatably cooperate with the striker orifice, and respective guide elements cooperating together so as to convert a relative approach and a relative distancing between the two reeve blocks into concomitants slidings and rotations of the bolt.

A support arrangement for a fluid monitoring system is provided, configured for being secured within a vertical shaft and for facilitating positioning of a fluid monitor suspended therefrom. The support arrangement includes an attachment arrangement to be secured to a vertical access shaft of an open channel fluid transport system, a cross rail assembly including a cross rail and being configured to be mounted to the attachment arrangement for being supported thereby, and a lifting assembly mounted on the cross rail and configured for suspension therefrom of the fluid monitor along a vertically-extending suspension axis. The cross rail is configured to be rotatable about a vertical axis when at least partially received within the attachment arrangement. The lifting assembly is configured to be selectively secured to one of a plurality of lateral positions along the length of the cross rail.

Described herein is a storage system for installation onto a surface, such as a horizontal or vertical wall, such as an interior garage ceiling, floor, or wall. The system can be used to move, lift, and/or store articles, such as bicycles, skis, storage containers, and the like. The system generally comprises a track defining a longitudinally extending path and a trolley assembly coupled to the track. The trolley assembly generally comprises a trolley body, a pair of opposing sidewalls extending from the trolley body, and a roller assembly positioned between the pair of opposing sidewalls. The trolley assembly may further comprise a carrier attachment to secure an article thereto. A drive member and drive unit can be used for effecting movement so as to shift the trolley assembly from one position to another. The system generally comprises simple and easy-to-install components, thereby providing advantages over prior storage systems.

Embodiments of the present disclosure describe methods and apparatuses for a load lifting system.

Embodiments of the present disclosure describe methods and apparatuses for a load lifting system.