A clothes dryer is disclosed. The clothes dryer includes a rotatably disposed drum, a heat pump system including a compressor configured to compress a refrigerant and a condenser configured to condense the refrigerant, a heater configured to heat air supplied to the interior of the drum, a first temperature sensor configured to detect a temperature of air passing through the interior of the drum, a second temperature sensor configured to detect a temperature of the compressor, and a processor configured to control an operation of the compressor on the basis of the temperature of the air passing through the interior of the drum detected by the first temperature sensor and control an operation of the heater on the basis of the temperature of the compressor detected by the second temperature sensor.

A controlling method for a dryer is applied to a dryer, in which at least one of a heat pump system and a heater is selected as a heat source for heating air supplied in to a drum and a heat supply capacity of the heat pump system is more than that of the heater. The controlling method includes, when both the heat pump system and the heater are selected as the heat sources, turning the heat pump system on, turning the heater on after the heat pump system is normally turned on, turning the heater off to cool the drum and terminate drying after the drying is performed, and turning the heat pump system off after the heater is turned off.

The present disclosure relates to a tumble dryer 1 with a rotatable drum 11 and a heat pump for drying process air that enters the drum, the heat pump comprising a condenser 19, a compressor 17, and an evaporator 15. In order to improve energy efficiency, the rotatable drum comprises a circular rear wall with air inlet openings and a radial cylindrical wall with air outlet openings, the compressor 17 is adapted to be run by an inverter 29, allowing the compressor output to be varied, and the expansion 16 is controllable. This allows the heat pump arrangement to be controlled to an optimum heat pump cycle envelope.

A Peltier element for a thermoelectric heat exchanger may include n-doped n-type semiconductors, p-doped p-type semiconductors, and a plate structure for electrically contacting the semiconductors. The plate structure may include first plate sections and second plate sections, which may be alternately arranged along an extension of the Peltier element. The first plate sections may form a first side of the Peltier element, and the second plate sections may form a second side of the Peltier element, the second side being spaced from the first side. The plate structure may further include a plurality of legs. Each leg may interconnect adjacent first and second plate sections and may extend inclined relative to the adjacent first and second plate sections. An n-type semiconductor and a p-type semiconductor may be alternately integrated in the legs along the plate structure.

A tumble dryer (1) comprising a heat pump system (22) and an air flow circuit (21) for circulation of an air flow. The air flow circuit (21) comprises a condenser (19), a drying drum (11), a fan arrangement (13), an air flow duct (18) and an evaporator (15). The air flow duct (18) comprises a constriction (16), arranged upstream the evaporator (15). The constriction (16) is provided with a plurality of openings (23), distributed across a cross section of the air flow duct (18), wherein the constriction (16) is adapted to create a pressure drop in the air flow that is circulated in the air flow duct (18), when the air flow flows from a first side A of the constriction (16) to a second side B of the constriction (16). The openings (23) in the constriction (16) are adapted to distribute the air flow across the cross section of the air flow duct (18).

A condensing type clothes dryer having a heat pump cycle and a method for controlling a condensing type clothes dryer having a heat pump cycle are provided. The condensing type clothes dryer may include a drum in which an object to be dried may be accommodated; a circulation duct that forms a circulation passage such that air may circulate via the drum; a circulation fan configured to circulate the air along the circulation duct; a heat pump cycle having an evaporator and a condenser spaced from each other in the circulation duct, and configured to absorb heat of air discharged from the drum through the evaporator and to transfer the heat to air introduced into the drum through the condenser using an operation fluid which may circulate via the evaporator and the condenser; a bypass flow path formed at the circulation duct such that a portion of air discharged from the drum may bypass the evaporator to be mixed with air having passed through the evaporator at an upstream side of the condenser; and an opening and closing device installed at the bypass flow path and configured to selectively open or close the bypass flow path.

In accordance with one aspect of the disclosure, a clothes dryer includes: a refrigerant pressure sensor provided in at least one of a first pipe connecting an expander to an evaporator or a second pipe connecting the evaporator to a compressor; a refrigerant temperature sensor provided in the second pipe; an electronic expansion valve configured to control a refrigerant; and a controller configured to control the electronic expansion valve based on detection values of the refrigerant pressure sensor and the refrigerant temperature sensor.

A drying apparatus is disclosed. The drying apparatus comprises: a drum; a compressor for compressing a refrigerant; a first temperature sensor provided at an air discharge port of the drum; a second temperature sensor provided at a refrigerant discharge port of the compressor; and a processor which, when a drying cycle for an object to be dried begins, compares a first temperature sensed by the first temperature sensor with a predetermined threshold temperature so as to obtain an operation frequency of the compressor, and when a second temperature sensed by the second temperature sensor reaches a predetermined first target temperature, adjusts the operation frequency of the compressor on the basis of a third temperature calculated on the basis of the first temperature and the second temperature.

An apparatus and method towards a laundry treating appliance for drying laundry comprising a rotatable drum at least partially defining a treating chamber and having a front and a rear where at least one conductivity sensor is located within the treating chamber, and a motor rotating the drum tumbles laundry within the treating chamber to enable contact of the laundry with the conductivity sensor.

A clothes dryer includes a drum configured to accommodate an object to be dried; a first sensor configured to sense a dry state of the object to be dried accommodated in the drum; a heating unit configured to heat air supplied into the drum; a blower including a fan configured to generate a flow of the air passing through the inside of the drum; a second sensor configured to sense a temperature of the air discharged from the drum; and a processor configured to control a rotation speed of the drum, a temperature of the air discharged from the drum, and a rotation speed of the fan.