A compressor and an air conditioner including the same having an improved structure capable of decreasing a discharge temperature of the compressor. The compressor which compresses and discharges refrigerant includes a casing defining an external appearance thereof, at least one cylinder including an inner space, a rolling piston which eccentrically turns in the inner space, a vane which radially abuts the rolling piston and divides the inner space into a suction chamber and a compression chamber, and a vane chamber recessed outward of the inner space such that the vane advances and retreats, a plurality of plates disposed above and below the at least one cylinder so as to define the inner space, an injection line provided in one of the at least one cylinder and the plural plates, and a check valve installed on the injection line.

A window fog detecting system for detecting fog on a windshield of a vehicle, including: a glass temperature detecting system including a contact temperature sensor attached to a portion of the windshield on the driver's seat side of the center in a width direction of the windshield, or to a portion where ceramic print is applied on the upper-side periphery of the windshield; a humidity detection device which detects the humidity of air in a vicinity of the inner surface of the windshield; and a judging device which judges the presence of fog on the windshield, on the basis of the detected values of the glass temperature detecting system and the detected values of the humidity detection device.

A control method of a refrigerator including a compressor to supply refrigerant to an evaporator to cool a storage compartment, a valve to adjust flow of the refrigerant, a fan to blow air heat-exchanged by the evaporator, and a heater to remove frost from the evaporator. The control method includes, upon receiving a power-saving signal, determining whether the received power-saving signal is a first or second power-saving mode signal, upon determining that the power-saving signal is the first power-saving mode signal, performing at least one selected from among resetting of target temperature of the storage compartment, adjustment of an operation rate of the compressor, and adjustment of operation time of the heater to execute a first power-saving mode, and, upon determining that the power-saving signal is the second power-saving mode signal, controlling the compressor, the fan, and the heater to be off to execute a second power-saving mode.

A multitemperature storage system includes a storage structure including a plurality of upright members, a plurality of horizontal members supported by the upright members and forming a grid pattern defining a plurality of grid cells and allowing containers to be arranged in stacks beneath the grid cells defined by the grid pattern, and a track structure on top of the horizontal members, the track structure being configured to allow a load-handling device to move across the storage structure to retrieve a container from a stack; and including temperature-control to maintain a first-temperature region within the storage structure at a first temperature and a second-temperature region within the storage structure at a second temperature.

A multitemperature storage system is provided. The system includes a storage structure having a plurality of upright members, a plurality of horizontal members supported by the upright members and forming a grid pattern defining a plurality of grid cells and allowing containers to be arranged in stacks beneath the grid cells defined by the grid pattern, and a track structure on top of the horizontal members, the track structure being configured to allow a load-handling device to move across the storage structure to retrieve a container from a stack; and temperature-control means configured to maintain a first-temperature region within the storage structure at a first temperature and a second-temperature region within the storage structure at a second temperature.

The invention relates to a refrigeration appliance (1) comprising an outer cabinet (2) and an inner liner (22), internal to the outer cabinet (2), defining at least one compartment (10) for receiving food items. A refrigeration system (30) comprises an evaporator (38) arranged inside the compartment (10) to cool down air. A fan assembly (50) is arranged inside the compartment (10) and associated to the evaporator (38) for generating a cooling air stream for the compartment (10). The fan assembly (50) comprises, arranged side by side: a first layer (70) of expanded polystyrene; a fan (72) comprising a rotor (82) with a rotation axis (X) inclined with respect to a vertical direction (V) and a cover plate (76). The fan assembly (50) comprises a fastening device (90) apt to fasten the cover plate (76) to the first layer (70) to keep the fan assembly (50) in the assembled configuration.

An air purification module for purifying air includes a photocatalyst filter and a light source unit sequentially arranged in a selected direction. The light source unit is spaced apart from the photocatalyst filter to provide light to the photocatalyst filter and includes a substrate and a light source disposed on the substrate. The substrate includes at least one aperture to control a flow channel and a flow velocity of air so as to improve air purification effects through the photocatalyst filter when the air flows from the substrate towards the photocatalyst filter.

An air purification module for purifying air includes a photocatalyst filter and a light source unit sequentially arranged in a selected direction. The light source unit is spaced apart from the photocatalyst filter to provide light to the photocatalyst filter and includes a substrate and a light source disposed on the substrate. The substrate includes at least one aperture to control a flow channel and a flow velocity of air so as to improve air purification effects through the photocatalyst filter when the air flows from the substrate towards the photocatalyst filter.

An automated grid based storage and retrieval system includes a framework structure including upright members and a grid of horizontal rails provided at upper ends of the upright members. The framework structure defines a plurality of storage volumes arranged adjacent one another below the horizontal rails. The storage volumes are open against the horizontal rails such that storage container vehicles may lower and raise storage containers into and out of the storage volumes. The system includes a plurality of vertical walls surrounding each of the plurality of storage volumes, and a cooler system adapted to draw air from an input of the cooler system, cool the air drawn from the input, and blow cooled air through an output of the cooler system. For each of the plurality of storage volumes, the system further includes a first air damper connected between the output of the cooler system and an air release area above the storage volume, and a second air damper connected between a void beneath the storage volumes and the input of the cooler system. The system includes a controller. The controller is adapted, independently for each of the plurality of storage volumes, to adjust airflow through the first air damper associated with that storage volume to control an overpressure and air temperature in the air release area, and to adjust airflow through the second air damper associated with that storage volume to control an underpressure in the void, such that a storage volume temperature is controlled separately for each of the plurality of storage volumes. The storage volume temperature is regulated by the air temperature in the air release area and by controlling a pressure differential between the overpressure in the air release area and the underpressure in the void in each of the storage volumes.

The invention relates to an automated, grid-based storage and retrieval system (1), said system (1) comprising a frame-work structure (100) comprising vertically extending members (102) and a grid of horizontal rails (110, 111) provided at upper ends of said vertical members (102), wherein remotely operated vehicles for handling goods holders (106) operate on top of the grid, the framework structure (100) comprising vertically extending storage columns (105) providing a storage volume (500) for storing goods holders (106). The storage volume (500) is disposed below the horizontal rails (110, 111) and at a distance from said horizontal rails (110, 111). Said system (1) further comprises a temperature management system (20) for the storage volume (500) comprising means (22) for providing air at a first temperature, and a horizontally extending air duct (24) for conveying air at the first temperature to the storage volume (500), the air duct being disposed along a middle of the storage volume (500), wherein air at the first temperature is released in an upper section (500U) of the storage volume (500). The invention further relates to a method for managing air in an automated, grid-based storage and retrieval system (1).