According to one embodiment, an electrical equipment housing includes a first storage room, an air conditioner, a second storage room, a temperature sensor, and a heater. The first storage room contains a power converter converting electrical power. The air conditioner adjusts a temperature inside the first storage room. The air conditioner includes an indoor unit and an outdoor unit. The indoor unit is provided inside the first storage room. The outdoor unit is provided outside the first storage room. The second storage room contains the outdoor unit. The temperature sensor senses a temperature inside the second storage room. The heater heats inside the second storage room when the temperature sensed by the temperature sensor is a lower limit or less.

A system for cooling a plurality of electrical equipment components inside a mobile platform may include at least one manifold and a plurality of flexible tubing ducts. The manifold may have an outlet, and a plurality of inlet tubing connections in fluid communication with the outlet. The outlet may be coupled to an interface of a cooling system of the platform by exhaust tubing. Each of the flexible tubing ducts may have a proximal end and a distal end. Each proximal end may be selectively connectable to the inlet tubing connections. Each distal end may have an air intake port that is alternatively positionable in two or more thermal dissipation zones of the electrical equipment components for permitting an exhaust profile inside the platform to the interface to be reconfigured based at least in part on respective positions of the electrical equipment components.

An objective of the present disclosure is to provide a cooling system for a data center. The system includes: a cabinet hot aisle, disposed above a cabinet; a hot airflow passage, disposed at a top of the data center, a ventilating fan being disposed between the hot airflow passage and the cabinet hot aisle; an exterior wall heat exchanging structure, disposed on an exterior wall of the hot airflow passage, a surface of the exterior wall heat exchanging structure adopting a turbulent airflow heat exchanging structure; and a cold airflow passage, communicated with the cabinet, a natural cold air supply damper being disposed between the cold airflow passage and the hot airflow passage.

Embodiments of the present disclosure provide an air-conditioning system for a data center computer room and a control method thereof, belonging to the technical field of heat dissipation of the data center computer room. The system includes an indoor evaporation circulation loop and an outdoor cooling circulation loop, where the indoor evaporation circulation loop includes an evaporator and an indoor side heat exchange fan. The outdoor cooling circulation loop includes the evaporator, an outdoor side heat exchange fan, a wet-film cooling cooler, a condenser, an intercooler, a low-pressure stage compressor, a high-pressure stage compressor, a one-way valve, and a refrigerant pipeline. The system has good refrigeration effect, can accurately adjust temperature of the data center computer room and save energy.

A modular data center includes a cooling module with a cooling module enclosure and a first cooling unit housed within the cooling module enclosure. The cooling module enclosure includes a first interface side wall with a first cooling module supply opening that receives a first portion of cooling air from the first cooling unit. The center further includes a data module with a data module enclosure for housing data equipment. The data module enclosure includes a second interface side wall with a first data module supply opening that receives the first portion of cooling air from the first cooling module supply opening such that the first portion of cooling air flows into the data module enclosure and removes heat from the data equipment.

A highly integrated mobile energy storage system is provided, which includes a container and battery racks. The battery racks are arranged in two rows along a length direction of the container, and the two rows of the battery racks are arranged back to back. For each of the two rows of battery racks, a maintenance door is arranged at a wall of the container close to the row of battery racks. In a case that a battery rack needs to be maintained, it is just required to open the maintenance door to maintain the battery rack. Since the two rows of battery racks are arranged back to back, no maintenance passage is required, thereby reducing a floor space along a width direction of the container, thus reducing the floor space of the system.

An environmental control system for a telecom shelter integrates with a native HVAC system for exchanging interior air in a conditioned space in a machine room, telecom enclosure, or other closed machine environment by forcing or directing cooler outside air to replace interior air without active refrigeration by the native HVAC system. Primary cooling and heating of the conditioned space in the enclosure is performed by an exchange system and control logic that identifies, based on sensory input, when outside air exchange is more efficient than native AC (Air Conditioner) operation. The native AC system is suppressed or inhibited, and primary environmental control performed by fan driven exchange of outside air with air in the enclosure. Sensors and timers identify appropriate periods to defer control to the native AC system for cooling demand in excess of outside air exchange capability, and also identify ongoing suppression, or takeback of cooling control from the native system when erroneous, erratic or mistaken operation results in excessive or insufficient cooling, resulting from such factors as equipment failure, operator error, and environmental/disaster occurrences.

A system for cooling a plurality of electrical equipment components inside a mobile platform may include at least one manifold and a plurality of flexible tubing ducts. The manifold may have an outlet, and a plurality of inlet tubing connections in fluid communication with the outlet. The outlet may be coupled to an interface of a cooling system of the platform by exhaust tubing. Each of the flexible tubing ducts may have a proximal end and a distal end. Each proximal end may be selectively connectable to the inlet tubing connections. Each distal end may have an air intake port that is alternatively positionable in two or more thermal dissipation zones of the electrical equipment components for permitting an exhaust profile inside the platform to the interface to be reconfigured based at least in part on respective positions of the electrical equipment components.

A modular enclosure includes a plurality of enclosure modules, each of the enclosure modules comprising a front wall, a rear wall opposite the front wall, and two opposed side walls that span the front and rear walls; the front, rear and side walls forming an cavity; an equipment rack within the interior cavity with electronic equipment mounted thereon; and an air containment barrier that extends between the side walls to limit air flow between a front portion of the interior cavity and a rear portion of the interior cavity. At least one of the side walls of each of the enclosure modules includes a removable side panel, the side panel including first and second air flow openings, wherein the first air flow opening is forward of the air containment barrier and the second air flow opening is rearward of the air containment opening. The enclosure modules are arranged in adjacent relationship, and wherein at least one removable side panel of a first enclosure module abuts a removable side panel of a second adjacent enclosure module. The modular enclosure also includes an air cooling system mounted to the side wall of a first endmost enclosure module and an exhaust system mounted to the side wall of an opposite second endmost enclosure module.

A modular data center includes a cooling module with a cooling module enclosure and a first cooling unit housed within the cooling module enclosure. The cooling module enclosure includes a first interface side wall with a first cooling module supply opening that receives a first portion of cooling air from the first cooling unit. The center further includes a data module with a data module enclosure for housing data equipment. The data module enclosure includes a second interface side wall with a first data module supply opening that receives the first portion of cooling air from the first cooling module supply opening such that the first portion of cooling air flows into the data module enclosure and removes heat from the data equipment.