A purification dehumidifier includes a housing, a fan, a dehumidifier assembly, and a purifier assembly. The housing includes an air inlet, a dehumidified air outlet, and a purified air outlet. An air duct in communication with the air inlet, the dehumidified air outlet, and the purified air outlet is formed in the housing. The fan is arranged in the air duct and configured to introduce an airflow into the air duct from the air inlet and blow the airflow in the air duct out from at least one of the dehumidified air outlet or the purified air outlet. The dehumidifier assembly is arranged in the air duct and corresponding to the dehumidified air outlet. The purifier assembly is arranged in the air duct and corresponding to the purified air outlet.

The invention provides a system (1) comprising a fan assembly (100) with a plurality of nozzle openings (115a, 115b, . . . ) for creating air flows (111a, 111b, . . . ), the fan assembly (100) configured to provide the air flows (111a, 111b, . . . ) in at least two non-parallel directions (112a, 112b, . . . ), wherein the at least two non-parallel directions (112a, 112b, . . . ) are configured within a virtual cone (30) having an apex angle () selected from the range of 10-170 and having a cone axis (31), a control system (200) configured to control the air flows (11a, 111b, . . . ), the system (1) further comprising a light source (10) configured to generate light source light (11), and the system (1) further comprising heating elements (113a, 113b, . . . ) for heating the respective flows (111a, 111b, . . . ).

The invention provides a system (1) comprising a fan assembly (100) with a plurality of nozzle openings (115a, 115b, . . . ) for creating air flows (111a, 111b, . . . ), the fan assembly (100) configured to provide the air flows (111a, 111b, . . . ) in at least two non-parallel directions (112a, 112b, . . . ), wherein the at least two non-parallel directions (112a, 112b, . . . ) are configured within a virtual cone (30) having an apex angle () selected from the range of 10-170 and having a cone axis (31), a control system (200) configured to control the air flows (11a, 111b, . . . ), the system (1) further comprising a light source (10) configured to generate light source light (11), and the system (1) further comprising heating elements (113a, 113b, . . . ) for heating the respective flows (111a, 111b, . . . ).

An air conditioning system suppresses energy consumption by efficient shared use of air in a common space that is not subjected to air conditioning in an indoor area, among a plurality of air conditioners for the purpose of heat exchange. A plurality of air conditioners each include: a usage-side heat exchanger configured to carry out heat exchange with air in an air-conditioning target space; a heat source-side heat exchanger configured to carry out heat transfer to and from the usage-side heat exchanger; and a heat source-side fan configured to feed air from a common space to the heat source-side heat exchanger and to blow the air into the common space. The heat source-side heat exchangers of the air conditioners are disposed in the common space. A first ventilation fan whose airflow volume is changeable is disposed near an exhaust port through which air is discharged from the common space toward an outdoor area. A controller changes the airflow volume of the ventilation fan, based on information on an air temperature of the common space.

A ventilation apparatus includes a housing having a front cover having an indoor air inlet and an air discharge opening, a rear cover having an outdoor air inlet and an indoor air outlet, and a side cover configured to connect edges of the front cover and the rear cover; a separation wall dividing the housing into a ventilation portion and an air conditioning portion; a total heat exchange element located in the ventilation portion; a supply-side mullion located adjacent to a first side of the side cover to define an outdoor air supply passage between the supply-side mullion and the first side of the side cover; a discharge-side mullion located adjacent to a second side of the side cover in the air conditioning portion to define an indoor air discharge passage; and an evaporator located between the supply-side mullion and the discharge-side mullion in the air conditioning portion.

A ventilation apparatus includes a housing having a front cover having an indoor air inlet and an air discharge opening, a rear cover having an outdoor air inlet and an indoor air outlet, and a side cover configured to connect edges of the front cover and the rear cover; a separation wall dividing the housing into a ventilation portion and an air conditioning portion; a total heat exchange element located in the ventilation portion; a supply-side mullion located adjacent to a first side of the side cover to define an outdoor air supply passage between the supply-side mullion and the first side of the side cover; a discharge-side mullion located adjacent to a second side of the side cover in the air conditioning portion to define an indoor air discharge passage; and an evaporator located between the supply-side mullion and the discharge-side mullion in the air conditioning portion.

A fan with an integrated cooler is disclosed. Unlike conventional air-conditioners, the device is compact and lightweight, and can be used both indoors and outdoors without the need to enclose or otherwise control the user environment from thermal considerations.

A fan with an integrated cooler is disclosed. Unlike conventional air-conditioners, the device is compact and lightweight, and can be used both indoors and outdoors without the need to enclose or otherwise control the user environment from thermal considerations.

A package air conditioning unit includes a housing, a condenser portion including a condenser located in the housing and an evaporator portion located in the housing. The evaporator portion includes an evaporator in fluid communication with the condenser and a vane-axial flow fan rotatable about a fan axis to power airflow from a conditioned space, across the evaporator and back toward the conditioned space.

A self-contained pre-manufactured air unit for installation on a roof of a building and method of operation thereof has a relief passage for connection to a building to receive relief air from the building when air pressure within the building exceeds a pressure of ambient air. The relief passage is independent of an air circulation system and is located to exhaust relief air over the condenser coil to ambient air through at least one condenser fan, thereby decreasing a temperature of a refrigerant in the condenser coil.