Building management systems and methods are described herein which augment predicted weather data with an external model of a built environment to calculate wind infiltration into a specific building or wind conditions at a building site. The wind infiltration can be used to predict the performance characteristic of at least one energy consuming component installed in the building, whereas the wind conditions can be used to determine whether the calculated wind conditions exceed a safety threshold.

There is described a mobile device and method for commissioning air intake control of an environmental control system. A communication component receives multiple air measurements from an air flow sensor, in which the air flow sensor is positioned in a duct compartment of the environmental control system. The processor generates multiple air flow tables based on the multiple air measurements, multiple fan speeds associated with the environmental control system, and multiple damper positions associated with the environmental control system. The communication component transmits the multiple air flow tables to an air intake controller of the environmental control system.

An air-conditioning apparatus includes a refrigerant circuit in which a compressor, a refrigerant flow switching device, a heat source side heat exchanger, an expansion device, a heat medium heat exchanger, and an accumulator are connected, a heat medium circuit in which a pump, the heat medium heat exchanger, a heat medium flow control device, and a load side heat exchanger are connected, at least one or more bypass pipes provided in the refrigerant circuit so that the refrigerant discharged from the compressor bypasses at least either one of the heat source side heat exchanger and the heat medium heat exchanger, a bypass opening and closing device provided at the bypass pipe, and a controller configured to control the bypass opening and closing device to carry out a start-up control function of causing low-pressure gas refrigerant with a high degree of superheat to flow into the accumulator.

An air-conditioning apparatus includes a refrigerant circuit in which a compressor, a refrigerant flow switching device, a heat source side heat exchanger, an expansion device, a heat medium heat exchanger, and an accumulator are connected, a heat medium circuit in which a pump, the heat medium heat exchanger, a heat medium flow control device, and a load side heat exchanger are connected, at least one or more bypass pipes provided in the refrigerant circuit so that the refrigerant discharged from the compressor bypasses at least either one of the heat source side heat exchanger and the heat medium heat exchanger, a bypass opening and closing device provided at the bypass pipe, and a controller configured to control the bypass opening and closing device to carry out a start-up control function of causing low-pressure gas refrigerant with a high degree of superheat to flow into the accumulator.

A refrigerating cycle apparatus includes a refrigerating cycle device having a refrigerating cycle, the refrigerating cycle in which a refrigerant is compressed in a compressor and made to circulate, and by a heat exchanger, heat is absorbed from a low temperature heat source and heat is exhausted to a high temperature heat source, and a control device that controls operation of the refrigerating cycle device. An obtaining unit obtains an operation operating request that controls the refrigerating cycle device arranged in a structure's interior to a target state. An operation control unit, when the operation operating request transmitted from an outside is obtained, controls the refrigerating cycle device to the target state with lower operation capacity than operation capacity of the refrigerating cycle device of a case where the operation operating request is transmitted from the structure's interior.

A refrigerating cycle apparatus includes a refrigerating cycle device having a refrigerating cycle, the refrigerating cycle in which a refrigerant is compressed in a compressor and made to circulate, and by a heat exchanger, heat is absorbed from a low temperature heat source and heat is exhausted to a high temperature heat source, and a control device that controls operation of the refrigerating cycle device. An obtaining unit obtains an operation operating request that controls the refrigerating cycle device arranged in a structure's interior to a target state. An operation control unit, when the operation operating request transmitted from an outside is obtained, controls the refrigerating cycle device to the target state with lower operation capacity than operation capacity of the refrigerating cycle device of a case where the operation operating request is transmitted from the structure's interior.

A machine learning apparatus determines an operation condition of a precooling operation or preheating operation of an air conditioner. The machine learning apparatus includes an acquisition unit and a learning unit. The acquisition unit acquires, as state variables, room temperature data at a time of the precooling operation or preheating operation, set temperature data, and outside air temperature data. The learning unit learns the operation condition of the precooling operation or preheating operation based on the state variables, a room temperature after start of the precooling operation or preheating operation, and a set temperature.

A machine learning apparatus determines an operation condition of a precooling operation or preheating operation of an air conditioner. The machine learning apparatus includes an acquisition unit and a learning unit. The acquisition unit acquires, as state variables, room temperature data at a time of the precooling operation or preheating operation, set temperature data, and outside air temperature data. The learning unit learns the operation condition of the precooling operation or preheating operation based on the state variables, a room temperature after start of the precooling operation or preheating operation, and a set temperature.

A method and an apparatus for controlling an air conditioner are provided, and the air conditioner is also provided. Herein, the method for controlling the air conditioner may include: acquiring at least one operating environment parameter of the air conditioner; determining a target temperature of the air conditioner and a revolving speed of an internal fan according to the at least one operating environment parameter of the air conditioner; and adjusting a frequency of a compressor on the basis of the operating environment parameter and the target temperature of the air conditioner and the revolving speed of the internal fan.

A controller has a timer operation mode in which the operation of a refrigeration cycle that operates as a heat source or a cold source is started before a set operation start time of an indoor fan by a preliminary operation time period. In the timer operation mode, the controller calculates a heat capacity of water or brine, calculates a heat storage amount of a second heat medium from a temperature detected by a temperature sensor and the heat capacity, and determines the preliminary operation time period from the heat storage amount. By determining the preliminary operation time period in this manner, timer operation can be performed such that air at an appropriate temperature is blown from an indoor unit at the operation start time of the indoor fan, from the initial time at which an air conditioning apparatus is installed.