A method (300) for operating a heating, ventilation, and air conditioning (HVAC) system includes an apparatus (102) to select a set point temperature and allow the HVAC system to reach the set point temperature. The apparatus (102) maintains the set point temperature for a predetermined duration and reach a first temperature by changing the setpoint temperature by a predefined value and maintain the first temperature for a first predetermined duration. The first temperature is changed by the predefined value to reach a second temperature and maintain the second temperature for a second predetermined duration. The apparatus modify the second temperature by the predefined value to reach the first temperature and maintain the first temperature for a third predetermined duration. The apparatus (102) modifies the first temperature by the predefined value to reach the set point temperature.

A method (300) for operating a heating, ventilation, and air conditioning (HVAC) system includes an apparatus (102) to select a set point temperature and allow the HVAC system to reach the set point temperature. The apparatus (102) maintains the set point temperature for a predetermined duration and reach a first temperature by changing the setpoint temperature by a predefined value and maintain the first temperature for a first predetermined duration. The first temperature is changed by the predefined value to reach a second temperature and maintain the second temperature for a second predetermined duration. The apparatus modify the second temperature by the predefined value to reach the first temperature and maintain the first temperature for a third predetermined duration. The apparatus (102) modifies the first temperature by the predefined value to reach the set point temperature.

A system, apparatus and method for deactivating HVAC equipment when the thermostat determines that a door or a window has been opened. The thermostat determines that a door or window is open using one or more security sensors previously installed for use with a separate security system.

A system, apparatus and method for deactivating HVAC equipment when the thermostat determines that a door or a window has been opened. The thermostat determines that a door or window is open using one or more security sensors previously installed for use with a separate security system.

An integrated energy optimizer having an edge side and a cloud side. The edge side may incorporate an energy optimizer, a building management system connected to the energy optimizer, a controller connected to the building management system, and equipment connected to the controller. The cloud side may have a cloud connected to the energy optimizer and to the building management system, and a user interface connected to the cloud. Data from the field sensor may go to the optimizer and the building management system. The data may be processed at the optimizer and the building management system for proper settings at the building management system.

An integrated energy optimizer having an edge side and a cloud side. The edge side may incorporate an energy optimizer, a building management system connected to the energy optimizer, a controller connected to the building management system, and equipment connected to the controller. The cloud side may have a cloud connected to the energy optimizer and to the building management system, and a user interface connected to the cloud. Data from the field sensor may go to the optimizer and the building management system. The data may be processed at the optimizer and the building management system for proper settings at the building management system.

A hydronic system is provided that includes a primary fluid loop that includes a thermal source for heating or cooling a working fluid, dual secondary fluid loops that include respective thermal loads, and a decoupler. One leg of a supply tee at an output of the source places the output in fluid communication with one end of a decoupler and, beyond the decoupler, with the input of a thermal load of a first secondary fluid loop. Another leg of the supply tee places the source output in fluid communication with the input of a thermal load in a second secondary fluid loop. One leg of a return tee at an input of the source places the input in fluid communication with the other end of the decoupler and, beyond the decoupler, with the output of the thermal load of the first secondary fluid loop. Another leg of the return tee places the input of the source in fluid communication with the input of the thermal load in the second secondary fluid loop.

The present disclosure discloses a fan driving device, and the fan 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 outputting a sensing signal to the processing unit periodically; 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 fan and adaptively regulate the working power of the fan. Based on this, a dynamic intelligent fan driving device without a user's turn-on and turn-off action and based on environmental state sensing is realized.

The present disclosure discloses a fan driving device, and the fan 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 outputting a sensing signal to the processing unit periodically; 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 fan and adaptively regulate the working power of the fan. Based on this, a dynamic intelligent fan driving device without a user's turn-on and turn-off action and based on environmental state sensing is realized.

A network of wireless remote climate sensors in a heating, ventilation, and air conditioning (HVAC) system permits the creation of personalized microclimates within an enclosed space. In addition to collecting temperature and humidity data, the wireless remote climate sensors can detect whether the enclosed space is occupied by a human. Human detection is made possible by optional cameras, microphones, and gas sensors on the wireless remote climate sensors. As the human moves throughout the enclosed space, the HVAC system is able to track the human's movement using the wireless remote climate sensors. The HVAC system may adjust airflow to different portions of the enclosed space based on the human's location. The result is an efficient use of system resources to keep users at their ideal temperature.