Abstract: A semiconductor device includes a semiconductor substrate, a first gate oxide layer, and a first source/drain doped region. The first gate oxide layer is disposed on the semiconductor substrate, and the first gate oxide layer includes a main portion and an edge portion having a sloping sidewall. The first source/drain doped region is disposed in the semiconductor substrate and located adjacent to the edge portion of the first gate oxide layer. The first source/drain doped region includes a first portion and a second portion. The first portion is disposed under the edge portion of the first gate oxide layer in a vertical direction, and the second portion is connected with the first portion.

Abstract: Disclosed is a drying device which includes desiccant wheels or desiccant wheels combined with adsorbent, and a drying apparatus using thereof. The desiccant wheel drying device includes a plurality of desiccant wheels made of direct heating desorption substrates. The drying apparatus using the drying device includes: two pressure tanks capable of performing adsorption dehumidification and regeneration desorption of moisture in compressed air. The two pressure tanks exchange functions in batches to achieve the moisture adsorption of the compressed air and the regeneration desorption of the adsorbent.

Abstract: A dehumidifying unit, a layered temperature control dehumidifying element and a drying device are provided. The dehumidifying element has a plurality of dehumidifying units. The dehumidifying units are made of a direct heating desorption material and used for dehumidifying air by adsorption and capable of being regenerated by desorption. By performing temperature compensation through a preheater and performing a layered temperature control method on the dehumidifying element, the disclosure achieves a uniform temperature control on the air flow passage of the dehumidifying element so as to improve regeneration performance of the dehumidifying element and reduce energy consumption of the drying device.

Abstract: A dehumidifying base material and a device for forming the dehumidifying base material are provided. The dehumidifying base material is formed from a raw base material including a metal layer, an upper adhesive film, a lower adhesive film, an upper absorbent material layer, a lower absorbent material layer, an upper release film, and a lower release film. The raw base material is placed on a material placement part and passes a first release roller, an upper absorbent adhesive part, a second release roller, and a lower absorbent adhesive part sequentially to form the dehumidifying base material. The dehumidifying base material with an absorbent material applied onto two sides thereof is compressed, and is rolled by a base material rolling part.

Abstract: A dehumidifying unit, a layered temperature control dehumidifying element and a drying device are provided. The dehumidifying element has a plurality of dehumidifying units. The dehumidifying units are made of a direct heating desorption material and used for dehumidifying air by adsorption and capable of being regenerated by desorption. By performing temperature compensation through a preheater and performing a layered temperature control method on the dehumidifying element, the disclosure achieves a uniform temperature control on the air flow passage of the dehumidifying element so as to improve regeneration performance of the dehumidifying element and reduce energy consumption of the drying device.

Abstract: A dehumidifying base material and a device for forming the dehumidifying base material are provided. The dehumidifying base material is formed from a raw base material including a metal layer, an upper adhesive film, a lower adhesive film, an upper absorbent material layer, a lower absorbent material layer, an upper release film, and a lower release film. The raw base material is placed on a material placement part and passes a first release roller, an upper absorbent adhesive part, a second release roller, and a lower absorbent adhesive part sequentially to form the dehumidifying base material. The dehumidifying base material with an absorbent material applied onto two sides thereof is compressed, and is rolled by a base material rolling part.

Abstract: A dehumidifying unit, a layered temperature control dehumidifying element, a drying device and a temperature control method thereof are provided. The dehumidifying element has a plurality of dehumidifying units. The dehumidifying units are made of a direct heating desorption material and used for dehumidifying air by adsorption and capable of being regenerated by desorption. By performing temperature compensation through a preheater and performing a layered temperature control method on the dehumidifying element, the disclosure achieves a uniform temperature control on the air flow passage of the dehumidifying element so as to improve regeneration performance of the dehumidifying element and reduce energy consumption of the drying device.

Abstract: A drinking dispenser has a warm water container; a hot water container coupled to the warm water container; a water supplying apparatus separately coupled to the warm water container and the hot water container; and a thermoelectric heat pump apparatus, configured with a pump that is arranged coupling to the water container and a thermoelectric module in respective coupled to the water container and the pump.

Abstract: A thermoelectric drinking apparatus has a feeding pipe, a cooling-gain circulating loop, a heating-gain circulating loop, an outlet pipe, and a thermoelectric heat pump. The thermoelectric heat pump has a cooling unit attached to the cold side of a thermoelectric chip, which has a cooling channel in its interior, and a heating unit attached to the hot side of the thermoelectric chip and provided with a heating channel in its interior. The feeding pipe conducts fluid into the cooling channel and the heating channel respectively. The cooling-gain and heating-gain circulating loop respectively cause fluids in the cooling channel and heating channel to create circular flows, such that the cold side and hot side of the thermoelectric chip respectively cool and heat the fluids via the cooling channel and heating channel. The outlet pipe discharges the cooled and/or heated fluids respectively from the cooling-gain circulating loop and heating-gain circulating loop.

Abstract: A dehumidifying unit, a layered temperature control dehumidifying element, a drying device and a temperature control method thereof are provided. The dehumidifying element has a plurality of dehumidifying units. The dehumidifying units are made of a direct heating desorption material and used for dehumidifying air by adsorption and capable of being regenerated by desorption. By performing temperature compensation through a preheater and performing a layered temperature control method on the dehumidifying element, the disclosure achieves a uniform temperature control on the air flow passage of the dehumidifying element so as to improve regeneration performance of the dehumidifying element and reduce energy consumption of the drying device.

Abstract: A dehumidifying unit, a layered temperature control dehumidifying element and a drying device are provided. The dehumidifying element has a plurality of dehumidifying units. The dehumidifying units are made of a direct heating desorption material and used for dehumidifying air by adsorption and capable of being regenerated by desorption. By performing temperature compensation through a preheater and performing a layered temperature control method on the dehumidifying element, the disclosure achieves a uniform temperature control on the air flow passage of the dehumidifying element so as to improve regeneration performance of the dehumidifying element and reduce energy consumption of the drying device.

Abstract: A regenerating-type compressed air drier for regenerating compressed air by an electrical heating mechanism and a dehumidifying-and-regenerating unit are provided. The drier includes a dehumidifying-and-regenerating unit and an air distribution unit. Compressed high-humidity air and regenerating air are guided to the air distribution unit by a compressed high-humidity air piping and a regenerating air piping. The compressed high-humidity air and the regenerating air are guided to dehumidifying-and-regenerating components of the dehumidifying-and-regenerating unit by a shunt rotor of the air distribution unit to complete the dehumidification of the compressed air and the regeneration of the dehumidifying-and-regenerating components. The drier has a simple structure, and can reduce an undue loss of heat energy by an electrical heating mechanism to the regeneration of the dehumidifying-and-regenerating components.

Abstract: A regenerating-type compressed air drier for regenerating compressed air by an electrical heating mechanism and a dehumidifying-and-regenerating unit are provided. The drier includes a dehumidifying-and-regenerating unit and an air distribution unit. Compressed high-humidity air and regenerating air are guided to the air distribution unit by a compressed high-humidity air piping and a regenerating air piping. The compressed high-humidity air and the regenerating air are guided to dehumidifying-and-regenerating components of the dehumidifying-and-regenerating unit by a shunt rotor of the air distribution unit to complete the dehumidification of the compressed air and the regeneration of the dehumidifying-and-regenerating components. The drier has a simple structure, and can reduce an undue loss of heat energy by an electrical heating mechanism to the regeneration of the dehumidifying-and-regenerating components.

Abstract: An adsorption unit is provided, including an electrical heating substrate defined with a fluid channel therein, and an adsorptive material layer formed on the electrical heating substrate to contact the fluid channel for adsorbing moisture or volatile organic compounds (VOCs) in a gas flow through the fluid channel.

Abstract: A drinking dispenser has a warm water container; a hot water container coupled to the warm water container; a water supplying apparatus separately coupled to the warm water container and the hot water container; and a thermoelectric heat pump apparatus, configured with a pump that is arranged coupling to the water container and a thermoelectric module in respective coupled to the water container and the pump.

Abstract: An adsorption unit is provided, including an electrical heating substrate defined with a fluid channel therein, and an adsorptive material layer formed on the electrical heating substrate to contact the fluid channel for adsorbing moisture or volatile organic compounds (VOCs) in a gas flow through the fluid channel.

Abstract: A water dispenser including a water inlet system, a drinking water storage system, a heat-exchange water system, a refrigeration system, a heating system and a water outlet system is provided. The drinking water storage system connects the water inlet system. The refrigeration system connects the drinking water storage system and has a water cooling tank and a first thermoelectric element. The cooling side of the first thermoelectric element contacts the water cooling tank. The heating system connected the drinking water storage system has a low-temperature water heating tank and a second thermoelectric element. A heating side of the second thermoelectric element contacts the low-temperature water heating tank. The heat-exchange system connects the water inlet system, a heating side of the first thermoelectric element and a cooling side of the second thermoelectric element. The water outlet system connects the refrigeration system and the heating system.

Abstract: A thermoelectric drinking apparatus has a feeding pipe, a cooling-gain circulating loop, a heating-gain circulating loop, an outlet pipe, and a thermoelectric heat pump. The thermoelectric heat pump has a cooling unit attached to the cold side of a thermoelectric chip, which has a cooling channel in its interior, and a heating unit attached to the hot side of the thermoelectric chip and provided with a heating channel in its interior. The feeding pipe conducts fluid into the cooling channel and the heating channel respectively. The cooling-gain and heating-gain circulating loop respectively cause fluids in the cooling channel and heating channel to create circular flows, such that the cold side and hot side of the thermoelectric chip respectively cool and heat the fluids via the cooling channel and heating channel. The outlet pipe discharges the cooled and/or heated fluids respectively from the cooling-gain circulating loop and heating-gain circulating loop.

Abstract: A device for producing a laminated film includes a plurality of thin film extruding dies, a case, and a thin film pressing module. Each thin film extruding die has a conveying channel, and extrudes a thin film through the conveying channel. The case forms an accommodation space together with the thin film extruding dies. One end of the conveying channels is respectively communicated with the accommodation space. The case has a through hole communicated with the accommodation space. The through hole is connected to a vacuum pump, and the vacuum pump is used to remove the gas in the accommodation space. The thin film pressing module is connected to the case and is located in the accommodation space. The thin film pressing module receives the output thin films, and then stacks, adheres, and presses the thin films together, so as to form a laminated film.

Abstract: A rotor replacing mechanism for rotary desiccant includes a base plate, on which a plurality of gears are mounted to form multiple support points, to and between which a rotor of the rotary desiccant is held in place. One or two of the plurality of gears may be moved to different positions to allow easy removal of the rotor from the base plate and accordingly the rotary desiccant and be replaced with a new one.