A set for assembling a heat source unit of an air conditioner at the site of the air conditioner, includes a heat source heat exchanger module having a first casing, a heat source heat exchanger and a compressor module port fluidly communicated with the heat source heat exchanger, a compressor module having a second casing separate from the first casing, a compressor and a heat source heat exchanger module port fluidly communicated with the compressor, wherein the heat source heat exchanger module and the compressor module are fluidly communicatable via the compressor module port and the heat source heat exchanger port, a main board comprising a control logic of the air conditioner and a first electric connector, wherein at least one of heat source heat exchanger and compressor modules has a circuit board comprising a second electric connector, the circuit board of such a module being configured for data communication with the main board upon electrical connection of the circuit board and the main board via the first and second connectors. Further, a method for assembling a heat source unit of an air conditioner at the site of the air conditioner uses such a set.

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.

A packaged terminal air conditioner unit includes a main expansion device connected to an interior coil such that the main expansion device is operable to throttle a flow of refrigerant to both a first coil section and a second coil section of the interior coil. A secondary expansion device is connected in series between the main expansion device and the second coil section of the interior coil such that the secondary expansion device is operable to throttle a flow of refrigerant to the second coil section of the interior coil. A controller is in operative communication with the secondary expansion device such that the controller adjusts the secondary expansion device to a configuration between a fully open configuration and a fully closed configuration during operation of the compressor.

The present invention provides a flow guiding device for an air conditioner, a supplementary device for enhancing and accelerating heat dissipation of flow guiding device and a method for heat dissipation thereof. The flow guiding device which is disposed between a condenser fan and a condenser coil is configured on a bottom surface of the air conditioner and obliquely configured to the condenser fan. The flow guiding device includes a flake body and a plurality of flow guiding members, the flake body has holes disposed through the flake body, and flow guiding protrusions are disposed on two opposite sides of the flake body, and a space between two of the plurality of flow guiding protrusions is a concave. A plurality of flow guiding member disposed on the concaves, and parts of the plurality of holes on the two opposite sides connected to the plurality of flow guiding member.

This application describes systems and methods for locating, securing, accessing and utilizing a discrete enclosure or workspace. The discrete enclosure or workspace may be located in a public, private or semi-private setting and may comprise a combination of working platforms or surfaces, seats, desks and other apparatus, as well as computer hardware and software. Systems may comprise natural language processing, artificial intelligence, machine learning and other adaptive learning capabilities to enhance the use of the discrete workspace. The workspace may be dimensioned to be used for a wide variety of activities by one or more users.

The present disclosure relates to a heating, ventilating, and air conditioning (HVAC) system that includes a refrigerant circuit and a sensor configured to measure a refrigerant concentration external to the refrigeration circuit. The HVAC system also includes a controller that is communicatively coupled to the sensor and to an economizer. The controller is configured to control a flow of environmental air into the HVAC system. The controller is further configured to increase a ratio of the flow of environmental air relative to a flow of return air from a conditioned interior space of a building when the sensor measures the refrigerant concentration above a predetermined threshold concentration.

Heating, ventilating and air conditioning are provided to a temporary, flexible shelter, especially in a rugged, remote and/or extreme environment, including locations and/or conditions where access to electric power may be limited and/or expensive. A portable system may include a light weight HVAC unit, with variable-speed components that are dynamically managed for efficiency, reliability and safety, and a flexible, self-insulating duct for connecting the HVAC unit to the temporary shelter.

A universal air handler unit includes a blower and evaporator juxtaposed one another within a compact, weather resistant cabinet adapted for outdoor installation. Ports for cool and return air ducts disposed on one side of the cabinet couple directly to the blower and evaporator respectively. Return air drawn by the blower into the cabinet passes across the evaporator core, then through the blower and back out through the adjacent cool air duct. Coolant lines couple to a stand-alone condenser/compressor unit. In a particular embodiment, an adapter enables stacking the condenser/compressor unit atop the cabinet to reduce the overall footprint of the combination. In another embodiment, a manifold adapted to couple to the cool and return air ducts may be installed in various locations, the air handler unit slideably coupling to the manifold during installation, and easily decoupling and reecoupling for transportation and maintenance.

A rear panel assembly includes a rear panel body provided with a vent and a motor bracket arranged at a side of the rear panel body and connected to the rear panel body. The motor bracket is at least partially opposite to the vent, and the motor bracket is provided with an air hole to allow air to flow into the vent through the air hole.