A louver blade for a louver assembly includes a first section, a second section extending from the first section and including a crest of the louver blade, an extension extending from the second section to form a recess between the extension and the second section, and a protrusion extending from the second section toward the extension and configured to facilitate retention of the particles within the recess. The extension is configured guide particles into the recess in an installed configuration of the louver blade with the louver assembly.

A ventilation and air conditioning system includes: an outdoor air supply fan; an exhaust fan; and a system controller to control operations of the outdoor air supply fan and the exhaust fan. The system controller includes: a link controller; an exhaust air volume receiver; a disconnection determinator; and a disconnected state supply air controller. The link controller controls the outdoor air supply fan and the exhaust fan in a linked manner. The exhaust air volume receiver receives, from the exhaust fan, an exhaust air volume signal indicating an exhaust air volume of the exhaust fan. The disconnection determinator determines a disconnected state where the exhaust air volume receiver fails to receive the exhaust air volume signal. The disconnected state supply air controller controls the outdoor air supply fan at a predetermined air volume when the disconnected determinator determines the disconnected state.

Methods, devices, and systems for space conditioning based on weather information are described herein. One device includes a memory, and a processor to execute executable instructions stored in the memory to receive forecasted weather information, determine, based on the forecasted weather information, future weather conditions, determine based on the future weather conditions and historical setpoint data, whether conditioning of a space is expected, and generate an alert in response to conditioning of the space being expected.

A method for operating a packaged terminal air conditioner includes activating a compressor of the packaged terminal air conditioner such that refrigerant flows through an interior coil of the packaged terminal air conditioner, and, while the compressor is active, periodically cycling a fan of the packaged terminal air conditioner between a low speed active operating state and an inactive operating state. The fan runs at a modulated speed limit of the fan in the low speed active operating state, and the fan is unpowered in the inactive operating state.

Real-time correction of vehicle load curve for dynamometer testing, and associated systems and methods are disclosed herein. In one embodiment, a method for replicating an on-road performance and/or a failure of a road vehicle in a test facility includes applying a load curve to a controller of the test facility and testing a test vehicle in the test facility using the load curve. The method also includes verifying whether the performance/failure is replicated on the test vehicle, and if the performance/failure is not replicated, changing at least one parameter in the load curve.

According to various aspects and embodiments, a system and method for controlling temperature in a control zone within a building is provided. According to some embodiments, the method includes receiving measured wind condition data external to the building and measured tracer gas concentration data in the control zone for a sample time interval and calculating an air flow characteristic for the sample time interval based on the measured tracer gas concentration data. The method further includes using the air flow characteristic in a temperature control loop for the control zone. According to some embodiments, the air flow characteristic is an air change rate (ACR) that may be used in determining a preheat time interval.

The present disclosure discloses an air conditioner driving device, and the air conditioner driving device comprises a sensing unit and a processing unit, wherein the sensing unit at least comprises a microwave sensing module; the sensing unit is at least used for sensing whether any human activity exists within the action range based on microwave sensing according to a certain microwave sensing cycle, and periodically outputting a sensing signal to the processing unit; and the processing unit is used for processing the sensing signal, so that the driving device can adaptively control the turn-on and turn-off of the air conditioner and adaptively regulate the working power of the air conditioner. Based on this, a dynamic intelligent air conditioner driving device without a user's turn-on and turn-off action and based on environmental state sensing is realized.

The invention relates to a method for controlling a passive-ventilation system of a building, comprising: determining an outdoor air temperature of air in an environment of the building; determining an indoor air temperature of at least one zone inside the building; calculating a temperature difference by subtracting the determined outside air temperature from the determined indoor air temperature; and, if the calculated temperature difference is greater than zero, controlling a state of at least one passive-ventilation device of the passive-ventilation system to be in any of a closed state, an open state, and one of one or more intermediate states between closed and open state. Each of the states corresponds to one value of an opening fraction value of the at least one zone inside the building varying between 0 and 1.

A ventilator (10) comprises a ventilator stator (12) for mounting to a structure and a ventilator rotor (14) for mounting and rotation with respect to the stator. One or more wind-drivable elements (44) are mounted to the ventilator rotor. A motor (20) is provided for operation between the ventilator rotor and ventilator stator for selective motor-driven rotation of the ventilator rotor.

An air handling unit includes a rain hood configured to receive an air flow from an external environment surrounding the rain hood, and a sensor disposed within the rain hood and configured to monitor air flow parameters indicative of a flow rate of the air flow.