Secondary loop air conditioning and heat pump systems include a reservoir with a capsule holding a phase change material.

An air conditioner includes a first medium circulating system including a first, second, and a fifth heat exchanging units, and a first and second throttling units. The first heat exchanging unit is serially connected between the first and second throttling units, the second throttling unit is serially connected between the first and second heat exchanging units, the first throttling unit is serially connected between the fifth heat exchanging unit and the first heat exchanging unit, and the first heat exchanging unit and the fifth heat exchanging unit are used to exchange heat with an environment. An energy storage apparatus is provided with an energy storage material. The second heat exchanging unit exchanges heat with the energy storage material. The air conditioner realizes diversified cooling ways for the environment, and includes an operation mode for synchronously cooling the room and storing the energy for the energy storage material.

An air-conditioning apparatus includes: a heat-source-side device that heats or cools a heat medium; a pump that sucks and transfers the heat medium; use-side heat exchangers; a heat medium circuit; flow rate control devices; indoor-side pressure sensors; a pump inlet-side pressure sensor and/or a pump outlet-side pressure sensor; a flow rate detection device that detects a pump flow rate; and a controller that performs a first operation in which the flow rate control devices are individually opened or closed and data regarding a flow passage resistance at a path related to each of the heat exchangers is obtained, and a second operation in which heat is supplied to indoor air, and calculates calculate flow rates of the heat medium that flows through the heat exchangers in the second operation, from pump flow rates and pressures detected by the pressure sensors in the first and second operations.

A system comprising a first plurality of microchannels, a second plurality of microchannels in thermal communication with the first plurality of microchannels such that the first plurality of microchannels and second plurality of microchannels form a heat exchanger, and a phase change composite in thermal communication with the heat exchanger and methods of operating are disclosed herein.

A portable conditioner to cool or heat an internal space separate from an external space includes a control and command unit configured to determine at least the enthalpy difference between the internal space and the external space, and to regulate the quantity of air exchanged with the external space in relation to the enthalpy difference determined with respect to an expected value of enthalpy difference corresponding to a conditioning temperature and to a defined conditioning relative humidity. The present invention also concerns a method to regulate the portable conditioner.

An air-conditioning garment includes a garment, a miniature air conditioner, and a convenient strap for carrying the miniature air conditioner on the garment. The garment includes an outer layer and an inner layer sealed together to form an air channel, at least two air holes are arranged across the outer layer of the garment, the garment and the miniature air conditioner are connected by an air inlet tube and an air outlet tube, and one end of the air inlet tube and one end of the air outlet tube are respectively connected to at least two of the air holes, so as to be connected to the air channel of the garment.

The present invention provides an integrated water-cooled air conditioning device, which comprises a cooling water tank device and an air conditioning system. The cooling water tank device includes a cooling water tank. A water tank region is disposed at the bottom of the cooling water tank for accommodating water. The air conditioning system includes a compressor, a condenser, a regulator, and an evaporator connected sequentially by a refrigerant piping. The condenser is formed by spirally bending the refrigerant piping to a spiral hollow tube in the water tank region. Thereby, the air conditioning system and the cooling-water circulation system can be connected integrally for miniaturization. The shortcomings of long heat dissipation loop, high pressure loss, and large size can be solved. Accordingly, the installation costs can be lowered, and the subsequent maintenance management can be convenient.

The present disclosure provides a refrigeration system. The system includes an evaporator unit having a housing configured to receive the refrigerant and an air inlet port configured to receive air. A porous material is disposed within the housing for defining a first compartment and a second compartment. A compressor unit is fluidically coupled to the housing and configured to induce an evacuation action within the housing, which enables air to enter the housing from the ambient surroundings via the air inlet port. The porous material is positioned above the air inlet port for allowing the air into the housing therethrough. The routed air disperses within the housing to form air bubbles, inducing turbulent motion of the refrigerant for converting the refrigerant into a mixture of refrigerant vapors and a cooled refrigerant. A heat exchanger is configured to refrigerate the enclosure.

An air-conditioning system includes an outside air conditioning device, an air conditioning device, and a machine learning apparatus, and includes a state variable acquiring unit configured to acquire state variables, a learning unit configured to perform learning by associating the state variables with at least either an operating capacity of the outside air conditioning device or an operating capacity of the air conditioning device, and a reward calculating unit configured to calculate a reward that correlates with a total of energy consumption of the outside air conditioning device and energy consumption of the air conditioning device. The learning unit performs the learning by using the reward calculated in a period determined in accordance with a time duration until the total of the energy consumption changes after at least either the operating capacity of the outside air conditioning device or the operating capacity of the air conditioning device has changed.

Proposed a gas heat-pump system including: a compressor compressing refrigerant and discharging the compressed refrigerant; an engine providing a drive force to the compressor; a radiator that cools coolant which is heated while passing through the engine; an indoor heat exchanger causing heat exchange to occur between indoor air and the refrigerant and thus cooling or heating an indoor space; an outdoor heat exchanger condensing the refrigerant; a four-way valve switching a flow direction of the refrigerant in such a manner that the refrigerant discharged from the compressor flows to the outdoor heat exchanger in a cooling operation mode and flows to the indoor heat exchanger in a heating operation mode; and a hot-water storage tank causing the heat exchange to occur between stored water and the refrigerant, and thus cooling the refrigerant in the cooling operation mode and heating the refrigerant in the heating operation mode.