An air-conditioning system according to the present invention includes plural air-conditioning apparatuses which air-condition the same space, and a controller which includes a communication unit, a data collection unit and a determination unit. The communication unit communicates with the plural air-conditioning apparatuses via a communication line. The data collection unit collects air-conditioning data including information indicating an air-conditioning efficiency from each of the plural air-conditioning apparatus via the communication unit. The determination unit determines one of the air-conditioning apparatuses which has the lowest air-conditioning efficiency, as a low-efficiency air-conditioning apparatus, based on the collected air-conditioning data, reduces the load on the low-efficiency air-conditioning apparatus, and causes one or ones of the plural air-conditioning apparatuses which are other than the low-efficiency air-conditioning apparatus, to bear an amount of load by which the load on the low-efficiency air-conditioning apparatus is reduced.

An induction heating device includes a case having a lower plate that defines an inlet and an exhaust slit; a cover plate coupled to the case; a working coil disposed inside the case; an indicator substrate support coupled to the lower plate and disposed below the working coil; an inverter substrate disposed on a lower surface of the indicator substrate support and including an inverter and a first heat sink configured to dissipate heat generated from the inverter; and a first blowing fan disposed at the lower plate and configured to draw air from an outside of the case through the inlet and discharge the air to the inverter substrate. The exhaust slit is configured to discharge, to an area below the lower plate, at least a portion of air discharged from the first blowing fan to the inverter substrate.

A method comprises performing an analysis of airflow and temperature distribution in an indoor environment utilizing a hybrid turbulence model including a Chen-Xu model used for analysis of bulk flow and a wall function used in first grid cells bounding solid objects in the indoor environment and adjusting physical layout and/or operating parameters of heat producing electrical equipment and/or a cooling system of the indoor environment responsive to results of the analysis to improve one of temperature distribution within the indoor environment and operating efficiency of the cooling system of the indoor environment.

Disclosed are a system, method, and computer-readable medium for optimizing a fan control system inside a rack system. In at least one example embodiment, the system can include a rack server with a plurality of chassis each having at least one node, each of the nodes including at least one adjustable air vent and configured for adjusting the at least one adjustable air vent based on an air flow requirement of the node. The system can further include a plurality of fans, where the plurality of fans are configured to operate based on a control signal. The system also can comprise a fan control logic board, wherein the fan control logic board is configured to receive from each node in the plurality of chassis the air flow requirements and based on the plurality of air flow requirements generate and transmit the control signal to the plurality of fans.

A temperature-regulated cabinet (10) includes a cabinet body (1) and a temperature regulating module (2). The cabinet body (1) has a containing space (11) formed inside the cabinet body (1) and an opening (12) communicated with the containing space (11). The temperature regulating module (2) is detachably installed to the cabinet body (1) and covered onto the opening (12) and includes a temperature regulator (21), a first hood (22), a second hood (23) and an exhaust fan (24). The temperature regulator (21) has a casing (211). The first hood (22) is detachably installed to the top of the casing (211), and the second hood (23) is detachably installed to the bottom of the casing (211). The exhaust fan (24) is installed inside the first hood (22) or the second hood (23). The cabinet has the advantages of simplifying the production line and lowering the construction and operation costs.

A system for providing cooling to electronic modules received within a chassis. The chassis includes a cooling apparatus having ducting and a plurality of fans coupled to the ducting. The ducting includes air passageways that extend through the ducting and are configured to direct air blown into the passageways by the fans toward the modules installed in the chassis. The modules include heat sinks and the air passageways direct the air toward the fins to provide cooling to the heat sinks. The chassis includes switches coupled to the fans and configured to selectively activate the individual fans when the electronic modules are installed in the chassis.

An airflow characterization system includes a first airflow sensor subsystem positioned at a first location on an airflow characterization board base and a second airflow sensor subsystem positioned at a second location on the airflow characterization board base that is different than the first location. An airflow characterization controller is coupled to the first airflow sensor subsystem and the second airflow sensor subsystem. When the airflow characterization board is positioned in a circuit board slot, the airflow characterization controller receives a first airflow signal from the first airflow sensor subsystem during a first time period and receives a second airflow signal from the second airflow sensor subsystem during the first time period. The airflow characterization controller determines a circuit board slot airflow characterization for the circuit board slot based on the first airflow signal and the second airflow signal.

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 monitoring phase separation is disclosed. The system includes a temperature control housing having an inlet and an outlet connection for a circulator; a bottle holder positioned inside the housing, the bottle holder having a body with a plurality of recesses for receiving test bottles, each recess having a back surface, a front opening, and a first light scanning component mounted on the back surface of the recess; a sleeve having a plurality of second light scanning components mounted thereon, the sleeve being disposed between the housing and the bottle holder, and each second light scanning component being aligned with one of the first light scanning components; and a lid latched onto the housing to hold the test bottles in place during testing.

The invention relates to a regulation method for an electrical enclosure cooling device, which has a refrigerating machine and a heat pipe arrangement, wherein the method comprises measuring a current internal electrical enclosure temperature and determining a target temperature for the internal electrical enclosure temperature, wherein said internal electrical enclosure temperature and target temperature form input signals of a regulator for actuating the electrical enclosure cooling device, and wherein said regulator outputs a control signal for determining manipulated variables of the refrigerating machine; determining the regulator control signal as a measured variable which is proportional to the respective current required cooling power; measuring the ambient electrical enclosure temperature and determining a respective energy efficiency for the refrigerating machine and the heat pipe arrangement either in the event that the required cooling power is to be provided by the refrigerating machine or in the event that the required cooling power is to be provided by the heat pipe arrangement; and selecting and activating that one of the two coolant circuits that can provide the required cooling power with greater energy efficiency.