A computer system includes a shielding casing, a movable component, at least one cable, and a shielding apparatus arranged at a first part of the shielding casing configured to accommodate the at least one cable in a first state at least partially, and to be compressed during a movement of the movable component in a second state, whereby the at least one cable is clamped into the shielding apparatus.

Data storage system connectors are described for a parallel array of dense memory cards that allow high airflow. In one example, a connector has a horizontal plane board having a plurality of memory connectors aligned in a row and a plurality of external interfaces, a plurality of memory cards, each having an edge connector at one end of the memory card to connect to a respective memory connector of the board, each memory card extending horizontally parallel to each other memory card and extending vertically and orthogonally from the board, and a plurality of interface connectors each to connect an edge connector to a respective board connector, the interface connectors extending horizontally from the one end of the memory cards and vertically to the respective plane board connector.

The present disclosure relates to methods and devices for preventing or minimizing water ingress in electronic components, particularly card cages or similarly sized and configured components, which may be used in many applications including, but not limited to, materials testing. A gutter is formed around a first portion of the perimeter of a chassis cover and a second channel is formed around a second portion of the perimeter of the chassis cover. This configuration is arranged and constructed to direct the impinging water or liquid away from such components as the air intake, the backplane, openings and exposed electronic terminals

The present disclosure relates to methods and devices for preventing or minimizing water ingress in electronic components, particularly card cages or similarly sized and configured components, which may be used in many applications including, but not limited to, materials testing. A gutter is formed around a first portion of the perimeter of a chassis cover and a second channel is formed around a second portion of the perimeter of the chassis cover. This configuration is arranged and constructed to direct the impinging water or liquid away from such components as the air intake, the backplane, openings and exposed electronic terminals.

A convertible chassis system for receiving a plurality of storage drives includes a chassis that includes a plurality of bays for receiving the storage drives. The convertible chassis also includes a reversible key that is removably affixed to the chassis body in either a first orientation or a second orientation. Each orientation provides a different key guide within the plurality of bays that either allows the storage drives to be received into or rejected from the bays of the chassis.

A plurality of electronic circuit boards (2), on which electronic components are mounted, is inserted in parallel through an electronic circuit insertion port (11) of a casing body (1). A gap (3) is formed between front panels (22) of inserted and adjacent electronic circuit boards (2) inserted. A bridge body (5) constituting conduction means electrically conducts a first conductive side portion (22a) of a front panel (22) in one electronic circuit board (2) of adjacent electronic circuit boards (2) and a second conductive side portion (22b) of a front panel (22) in another electronic circuit board (2) that faces the first conductive side portion (22a) via a gap (3).

A storage chassis may be adapted, or configured, to secure a plurality of carrierless devices (e.g., without the use of a carrier or drive tray) received thereby. The storage chassis may include a base, a first drive wall coupled to and extending from the base, and a second drive wall coupled to and extending from the base. The first drive wall may be spaced apart from the second drive wall. The base, the first drive wall, and the second drive wall may define a row of drive slots and each drive slot of the row of drive slots may be configured to receive a carrierless device. Further, the storage chassis may include a plate extending across the row of drive slots and may be configured to extend over the carrierless devices received by the row of drive slots.

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.

A connector assembly includes a guiding shield cage, at least two receptacle modules, at least two partitioning brackets and at least two extending brackets. The receptacle modules are provided to a rear segment of an interior of the guiding shield cage. The partitioning brackets include a first partitioning bracket and a second partitioning bracket, the partitioning brackets are arranged side by side and are provided in the guiding shield cage, a rear end of each partitioning bracket is positioned in front of a front end of corresponding one of the receptacle modules. The extending brackets includes a first extending bracket which is assembled to the first partitioning bracket and a second extending bracket which is assembled to the second partitioning bracket, the extending brackets are arranged side by side and are respectively assembled to rear ends of the partitioning brackets, each extending bracket is capable of moving relative to the partitioning bracket assembled therewith between a front position where each extending bracket is positioned in front of a front end of the corresponding receptacle module and a rear position where each extending bracket at least partially extends into the corresponding receptacle module.

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.