The present disclosure describes an equipment rack for a telecommunications cabinet. The equipment rack allows a telecommunications cabinet to be reconfigured such that telecommunications equipment can be vertically mounted therein. The equipment rack includes a structural rail configured to be mounted within the telecommunications cabinet, an insert plate configured to fit within a cavity of the structural rail and be secured to the structural rail, and a bracket configured to be secured to the to the insert plate and configured such that a piece of telecommunications equipment can be mounted thereto.

A method for providing wireless telecommunications. The method includes providing a modular remote radio unit (RRU) capable of wirelessly transmitting data, placing the modular RRU on a boom truck with a boom arm, transporting the remote radio unit to a deployment location, setting the modular RRU on a structure at the deployment location by lifting the modular RRU off the boom truck with the boom arm, electrically coupling a power input of the modular RRU to a power source to power the modular RRU, and transmitting and receiving wireless data with the modular RRU unit after the power input is coupled to the power source.

A cabling-based airflow routing system includes a chassis that defines a chassis housing. A first heat producing component is located in the chassis housing. A first cabling connector is located in the chassis housing. A second cabling connector that is located in the chassis housing. A first ribbon cable that extends through the chassis housing between the first cabling connector and the second cabling connector. The first ribbon cable includes a first cabling airflow routing portion that is oriented in the chassis housing in an airflow path and that is configured to redirect a first portion of an airflow provided in the airflow path towards the first heat producing component.

A utility cabinet includes a housing having an interior compartment, a rear wall, a top wall, a bottom wall, a first side wall, a second side wall, a front opening, and a side opening. A frame is connected to the housing and moveable between a first position where the frame is entirely in the housing and a second position where at least a portion of the frame is outside of the housing. The frame is configured to receive one or more utility components. A front door is connected to the housing and moveable between a closed position covering the front opening and an open position providing access to the front opening. A side door is connected to the housing and moveable between a closed position covering the side opening and an open position providing access to the side opening.

A modular multipurpose telecommunications enclosure has a plurality of walls, to which are removably affixed a plurality of mounting bulkheads. Each mounting bulkhead has a plurality of mounting holes arranged into a specified hole pattern that is configured to receive and mount cameras or other electronics units from various different equipment manufacturers which employ different hole patterns in their mounting kits. The enclosure is made of a high thermal conductivity material such as aluminum to promote convection cooling and employs one or more airflow vents to keep any internal electronics from reaching undesirably high temperatures during operation. The enclosure also features antenna mounting holes to accommodate various wireless communication antennas, as well as a mounting bracket to allow easy installation of the enclosure in a desired location. The enclosure is rugged and durable against the elements to facilitate purposes such as video monitoring of an outdoor area.

Certain types of aggregation enclosures include cable input ports and downwardly angled cable output ports. A cover is pivotally coupled to the body so that the cover moves between an open position and a closed position. A modular component panel may be disposed within the enclosure. The component panel includes one or more distribution components (e.g., fiber distribution components or power distribution components) configured to connect at least a portion of an incoming cable to at least a portion of an outgoing cable.

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.

A cabling-based airflow routing system includes a chassis that defines a chassis housing. A first heat producing component is located in the chassis housing. A first cabling connector is located in the chassis housing. A second cabling connector that is located in the chassis housing. A first ribbon cable that extends through the chassis housing between the first cabling connector and the second cabling connector. The first ribbon cable includes a first cabling airflow routing portion that is oriented in the chassis housing in an airflow path and that is configured to redirect a first portion of an airflow provided in the airflow path towards the first heat producing component.

A damping device and a CPE assembly are disclosed. The damping device may include a housing, a guide roller, a friction drum, and a buffer shaft. The buffer shaft includes a shaft body, and a buffer arranged in the housing. The shaft body has one end connected with the buffer and the other end arranged on the bottom plate of the housing. The guide roller is rotatably arranged on the shaft body. The friction drum is sleeved on the guide roller, the guide roller has an outer diameter less than an inner size of the friction drum. The housing is provided with a first wire inlet hole and a first wire outlet hole in a sidewall, and the friction drum is provided with a second wire inlet hole and a second wire outlet hole respectively opposite to the first wire inlet hole and the first wire outlet hole.

A system for improved cable management is disclosed in several example embodiments. The disclosed embodiments describe example structures for supporting cables, for example telecommunications and fiber optic cables, within a cable storage cabinet. The disclosed embodiments also describe a door for a cable storage cabinet. The example door includes a hinge control and handle system which allows the door to be opened along either side to therefore allow the door to be opened either way from a single handle. The disclosed embodiments also describes an indicator system which informs a user when the door for the cable storage cabinet is in either a closed position or an open position. Each of these embodiments improves the utility and safety of cable management, particularly within cable storage cabinets.