A locking mechanism for securing a computing device in an enclosure includes a jaw, a transmission lever, and an arm. The jaw is configured to abut a portion of the enclosure for holding the computing device. The transmission lever includes an arm pivot at one end and an actuating pivot at the opposite end. The arm is configured to rotate open and closed about the arm pivot and be selectively decoupled from the transmission lever. When the arm is coupled to the transmission lever, opening the arm causes the transmission lever to rotate open about the actuating pivot. Rotating open the transmission lever about the actuating pivot releases the jaw from the portion of the enclosure, and allows the computing device to be removed from the enclosure.

A self-standing data center infrastructure system includes a bottom frame and a collapsible top frame that are configured to be inserted into a standard shipping container for transport to a data center location. At the data center location the bottom frame is secured to a floor of the data center and the top frame is mounted as a pre-assembled unit on the bottom frame. The top frame is then expanded to provide infrastructure support to one or more rows of racks. Also, the racks may be secured to the bottom frame without the need for additional anchoring of the racks.

A handle assembly may include a base, a handle rotably coupled to the base via a hinge, the handle comprising a lock integral to the handle and mechanically coupled to a remainder of the handle via a spring having a spring force that biases the lock in a locked position relative to the handle. The base may include a mechanical retention feature for receiving and mechanically retaining an information handling resource. The base may also include one or more features configured to, as the handle is translated into a closed position relative to the base, mechanically engage with the lock to overcome the spring force that biases the lock in a locked position and allows the lock to return to the locked position in order to maintain the handle in the closed position.

Examples described herein relate to a securing sub-system. The securing sub-system includes a lever and a cam assembly engaged with the lever. The cam assembly is movable due to a pivotal movement of the lever and includes a cam body, a cantilevered arm, and a load support member. The cantilevered arm extends from the cam body and is deformable when the cantilevered arm contacts a restrictive structure. The load support member disposed on the insertion cam. A portion of the load support member is offset from an open end of the cantilevered arm to limit deformation of the cantilevered arm. Further, some examples described herein relate to a securing system including a plurality of securing sub-systems coupled via a synchronous movement link is also presented. Moreover, certain examples described herein relate to a computing system including at least one such securing sub-system.

An inspection system of a chip includes a reading device and a determining unit. The reading device is configured to count a number of chips stored in a storage case, the chips associated with a table game and including a chip having a radio tag, read the radio tag while the chips are stored in the storage case, and acquire chip information. The determining unit is configured to compare the chip information of the chips in the storage case with a physical number of the chips in the storage case, determine that there is an abnormal chips among the chips stored in the storage case based on a determination that the counted number of the chips does not match a physical number of the chips in the storage case, and output a result associated with an indication of the abnormal chip.

A method for transporting and installing an electronic device having at least one first electrical contact element includes fixing the electronic device in a recess or interior of a reusable transport and assembly module such that access to the at least one first contact element is blocked by a protective element, transporting the transport and assembly module and the electronic device into a connection region of an electrical apparatus, removing the protective element so that the at least one first contact element is accessible, actuating an actuation apparatus provided on the transport and assembly module to move the electronic device in a direction out of the recess or interior into a contact position in which the at least one first contact element is brought into electrical contact with at least one second contact element provided on the electrical apparatus, and removing the transport and assembly module.

An ejector can be provided for a surge protection module that is configured to be engaged with a base for operation. The ejector can include a lever that is configured to pivot relative to the base to eject the surge protection module from engagement with the base.

An electronic device includes a housing having a front wall and a floating connector assembly coupled to the front wall. The connector assembly includes a panel and a connector. The connector includes a frame attached to the panel and defines first and second alignment openings. A sleeve extends from the frame and extends through the front wall. A removable cover for the electronic device includes first and second connector alignment pins that align with the first and second alignment openings to align the connector sleeve with a connector aperture defined by the cover. The first and second connector alignment pins and the first and second alignment openings can each include tapered portions to move the connector assembly into alignment with the connector aperture as the cover is attached with the housing.

A detection system including a control device detecting fraud performed in a game table by using a result of an image analysis performed by an image analyzing device. A substitute currency for gaming used for this detection system has a multi-layer structure in which a plurality of plastic layers having different colors are stacked, a coloring layer is included at least in the middle, and white layers or thin-color layers (may be layers having a color thinner than that of the coloring layer; not illustrated in the drawing) are stacked on both sides of the coloring layer disposed in the middle.

Systems and methods for a profile-modeling cable clip for sealing airflow in an Information Handling System (IHS) chassis. In some embodiments, a profile-modeling cable clip for sealing airflow in an IHS chassis may include a base and a plurality of comb teeth coupled to the base via spring elements, where each of the comb teeth is independently compressible.