A heating system for use with a can dryer or oven includes a gas burner, an electrical heating element, a heating chamber structured to heat cans using air heated by the gas burner and/or the electrical heating element, a circulation system structured to move air from the gas burner and the electrical heating element to the heating chamber, and a control system structured to selectively control the gas burner and the electrical heating element to switch between a first mode where the gas burner and the electrical heating element are active and both heat air provided to the heating chamber and in a second mode where the gas burner is inactive and the electrical heating element is active.

This invention in the field of grain drying, along with other particulates, provides an apparatus which dehumidifies air, then heats the air to relative low drying temperatures (95-160 Deg. F.), provides the dehumidified, heated air as process air to a system which uses the airflow as a transport method to fluidize the particulate matter and move the mixed process air and particles through a process column for drying. Once a particle reaches a designed moisture level, its mass will have been reduced, and that effect plus the velocity of the process air in the column will float the dried particle up and out of the column for further handling.

Disclosed herein is a process for de-watering a sludge. The process comprises heating a de-watering fluid, and passing the de-watering fluid through the sludge, thereby de-watering the sludge. Also disclosed herein is a system for de-watering a sludge and a sludge which is at least partially de-watered according to the process.

Disclosed herein is a process for de-watering a sludge. The process comprises heating a de-watering fluid, and passing the de-watering fluid through the sludge, thereby de-watering the sludge. Also disclosed herein is a system for de-watering a sludge and a sludge which is at least partially de-watered according to the process.

A system (27) arranged to dry a filament (5) used in additive manufacture, the system (27) comprising: a first heater (55) arranged to heat air; a tubing section (29) having a wall (31) defining an enclosed passage (33), the passage (33) arranged to convey a filament (5), the tubing section (29) having an air inlet (51) for providing heated air from the first heater (55) into the passage (33); and a second heater (59) arranged around along at least part of the tubing section (29), in order to further heat filament (5) within the passage (33).

A system (27) arranged to dry a filament (5) used in additive manufacture, the system (27) comprising: a first heater (55) arranged to heat air; a tubing section (29) having a wall (31) defining an enclosed passage (33), the passage (33) arranged to convey a filament (5), the tubing section (29) having an air inlet (51) for providing heated air from the first heater (55) into the passage (33); and a second heater (59) arranged around along at least part of the tubing section (29), in order to further heat filament (5) within the passage (33).

A method for drying a component interior of a component can be used in a lithographic process chain. The method includes a first drying step, in which simultaneously heated air is admitted into a component interior through an inlet, and the heated air is sucked out of the component interior through an outlet. The method also includes a succeeding second drying step, in which the inlet for the heated air is closed and the air is sucked out of the component interior, resulting in a reduced pressure is generated in the component interior.

A method for drying a component interior of a component can be used in a lithographic process chain. The method includes a first drying step, in which simultaneously heated air is admitted into a component interior through an inlet, and the heated air is sucked out of the component interior through an outlet. The method also includes a succeeding second drying step, in which the inlet for the heated air is closed and the air is sucked out of the component interior, resulting in a reduced pressure is generated in the component interior.

An apparatus and method to deter mold growth on the interior surfaces of buildings. The apparatus is a corded and plugged power supply with adjustable temperature and humidity sensors, logic circuitry, and split duplex receptacles. The method employs the apparatus, a portable heater, an array of portable fans, and catchments containing a hygroscopic substance such as calcium chloride. One receptacle controls the heater. The other receptacle controls the fans. There are three operative states: a heat-on/fans-on state at low temperature, a heat-off/fans-on state at high temperature and high humidity, and an idle state at high temperature and low humidity. The catchments capture water vapor circulated by the fans.

An apparatus and method to deter mold growth on the interior surfaces of buildings. The apparatus is a corded and plugged power supply with adjustable temperature and humidity sensors, logic circuitry, and split duplex receptacles. The method employs the apparatus, a portable heater, an array of portable fans, and catchments containing a hygroscopic substance such as calcium chloride. One receptacle controls the heater. The other receptacle controls the fans. There are three operative states: a heat-on/fans-on state at low temperature, a heat-off/fans-on state at high temperature and high humidity, and an idle state at high temperature and low humidity. The catchments capture water vapor circulated by the fans.