Methods and systems for the thermo-vacuum drying and processing of objects such as clothes. A vacuum ejector driven by high-pressure steam is employed to evacuate evaporated moisture mixed with air from a dryer vessel producing an intensification of the drying process such as can significantly reduce the energy and time requirements for the drying process and increase water utilization.

Disclosed is a method for thermally drying pasty products, in particular wastewater sludge, and a belt dryer implementing such a method. The principle consists of partitioning the drying operations and using, for each of the successive operations, a different quality of air: (i) hot air for “searing” the sludge, (ii) low temperature air, then (iii) cold air for quenching the sludge before the extraction of same. Also proposed are loops of air supply circuits making it possible to optimize the energy consumption of the dryer by reusing energy produced within these circuits. Moreover, the loops make it possible to recover unavoidable low temperature energy or cheap energy, further optimising the consumption of the dryer.

An installation for drying a non-woven web includes a device (10, 11), a diffusion chamber (10) having an outlet fitting (21) in which there is mounted a perforated sheet (24) creating a drop in pressure.

The present invention provides grain-drying facilities which can effectively use the heat energy of biomass combustion hot-air that has been generated in a biomass combustion furnace. The grain-drying facilities 1 include: a biomass combustion furnace 3 provided with a heat exchanger 24 for generating a hot air from a combustion heat of a biomass fuel and an outside air which has been taken in from the outside; and a circulation type grain-drying apparatus 2 provided with a grain-drying portion 7 to which the hot air that has been generated in the biomass combustion furnace 3 is supplied through a pipe 15 for supplying a hot air, wherein the circulation type grain-drying apparatus 2 has a plurality of warming pipes 6a in the grain-drying portion 7, and an exhaust hot-air is supplied to the warming pipes 6a from the biomass combustion furnace 3 through a pipe 11 for supplying the exhaust hot-air.

An apparatus for drying an electrode plate includes a drying furnace configure to dry an electrode plate having a slurry coated thereon, an over-heated steam supplier configured to supply the drying furnace with over-heated steam as a drying heat source, a circulation fan configured to inhale at least some of the over-heated steam discharged from the drying furnace and to introduce the inhaled over-heated steam back into the drying furnace, an exhaust fan configured to inhale at least some of the gas exhausted from the drying furnace, and a heat exchanger configured to exchange heat of the exhaust gas supplied from the exhaust fan.

A dishwasher drying system includes an air inlet configured to receive hot, humid air from a tub of a dishwasher. The dishwasher drying system also includes an air outlet configured to discharge the air to an ambient environment outside the dishwasher. The dishwasher drying system further includes an air moving device configured to cause the air to move from the air inlet to the air outlet. In addition, the dishwasher drying system includes a thermal storage heat exchanger positioned within an airflow path of the moving air, the thermal storage heat exchanger configured to absorb heat and condense moisture from the moving air as the moving air contacts the thermal storage heat exchanger during a dishwasher drying cycle.

A laundry appliance includes a blower that directs process air through an airflow path. A rotating drum holds articles to be processed. A heat pump system has a condenser and an evaporator. The evaporator dehumidifies the process air that is delivered from the drum and the condenser heats the process air that is delivered from the evaporator. A thermal storage mechanism retains heat at least from the condenser that is directed away from the process air to define captured heat, and the captured heat of the thermal storage mechanism is utilized during a subsequent laundry cycle. A secondary heater is powered by an external source that delivers thermal energy to the thermal storage mechanism.

A dryer for drying dry materials having heating and cooling chambers, wherein the two chambers are sealed gas-tight to each other and/or to the outside environment, a connecting line that fluidically connects the chambers to each other and has a closing valve, a vacuum pump that is actively connected to the cooling chamber, a heat pump that is actively connected to the two chambers, and a steam generator which feeds generated steam via a steam line into the heating chamber,
The steam mixes with moisture of the dry materials in the heating chamber and the resulting moist steam is supplied to the cooling chamber via the connecting line, wherein positive pressure is generated through evaporation and negative pressure is produced through the condensation such that a pressure difference is produced between the heating and cooling chambers, and wherein the vacuum pump pumps dry air from the cooling chamber as required.

Systems and methods in accordance with the present invention provide for the efficient distillation of ethanol in an ethanol plant including a beer column. Heat is captured in the distillation process and utilized to drive operations in the ethanol plant.

The noodle driving apparatus includes an enclosure having a lateral partition separating the enclosure into an upper chamber and a lower chamber. At least one first cool-air provision device and at least one warm-air recovery device are disposed to a side inside the upper chamber. A number of first cool-air inlets and warm-air inlets are configured on the partition toward another side of the upper chamber. Noodles to be dried are placed in the lower chamber. Cool air produced by the first cool-air provision device is introduced into the lower chamber through the first cool-air inlets to absorb moisture from the noodles. Warm air produced from the first cool-air provision device is collected by the warm-air recovery device and introduced into the lower chamber through the warm-air inlets to dry the noodles. The noodle driving apparatus thereby achieves improved drying performance, enhanced energy consumption, and better drying quality.