The invention relates to a device and a method for preventing faults of an oven for producing containers, in particular cans. The device comprises: a conveyor unit with transport pins, said conveyor unit being designed to convey the containers along a drying section; at least one measuring unit which is designed to: ascertain an inlet number of containers which have entered an observation section of the drying section and an outlet number of containers which have exited the observation section; and a control device which is designed to: determine the amount of container loss on the basis of a deviation between the inlet number and the outlet number.

Embodiments provide a unidirectional multi-path kiln with two or more chambers and generally parallel flow paths extending through the kiln, on opposite sides, from charge entry portals at a first end of the kiln to charge exit portals at a second end of the kiln. Moist heated air flowing from the second heated chamber is received in the first chamber and circulated around the lumber charges with one or more fans. The lumber charges proceed in the same direction on the flow paths through the heated second chamber, which may be an existing kiln. Charge exit portals at the distal end of the kiln and/or intermediate charge portals between the second chamber and a third chamber may be provided with insulating members configured to reduce airflow from the second chamber through the charge exit portals.

Embodiments provide a unidirectional multi-path kiln with two or more chambers and generally parallel flow paths extending through the kiln, on opposite sides, from charge entry portals at a first end of the kiln to charge exit portals at a second end of the kiln. Moist heated air flowing from the second heated chamber is received in the first chamber and circulated around the lumber charges with one or more fans. The lumber charges proceed in the same direction on the flow paths through the heated second chamber, which may be an existing kiln. Charge exit portals at the distal end of the kiln and/or intermediate charge portals between the second chamber and a third chamber may be provided with insulating members configured to reduce airflow from the second chamber through the charge exit portals.

A multi-zone heating oven is disclosed. The multi-zone heating oven includes a plurality of in-line heating chambers, a conveyor system configured to convey objects between and into each chamber of the plurality of in-line heating chambers and a supply line for each of the plurality of in-line heating chambers. In addition, the multi-zone heating oven includes an exhaust system. The humidity in each chamber is set individually. Changes in the temperature and humidity that an object is subjected to are controlled by moving the object through the plurality of chambers.

A coat drying device dries a wet-coated film that is coated on a continuously transported coating object having first and second parts, where the second part has a greater heat capacity than the first part. The coat drying device includes a heat source and a heat source moving device. The heat source provides thermal energy primarily to a coating surface of a second part. The heat source moving device moves the heat source to the second part such that a spacing between the second part and the heat source is maintained within a predetermined range.

A coat drying device dries a wet-coated film that is coated on a continuously transported coating object having first and second parts, where the second part has a greater heat capacity than the first part. The coat drying device includes a heat source and a heat source moving device. The heat source provides thermal energy primarily to a coating surface of a second part. The heat source moving device moves the heat source to the second part such that a spacing between the second part and the heat source is maintained within a predetermined range.

A vibratory dryer includes a conveying surface over which a bed of materials to be dried is conveyed, the surface having an inlet end and an outlet end, and passages through which air passes through the conveying surface to pass through the bed of materials on the conveying surface, a source of heated air coupled to the passages to supply heated air to the bed through the passages, and a vibration generator coupled to the conveying surface. The dryer also includes at least one rotary mixer having an impeller spaced from the conveying surface at a distance so as to be disposed within the bed, the at least one rotary mixer disposed along the length of the conveying surface between the inlet end and the outlet end. The at least one rotary mixer is adapted to provide uplift within the bed without de-densification of the bed.

A vibratory dryer includes a conveying surface over which a bed of materials to be dried is conveyed, the surface having an inlet end and an outlet end, and passages through which air passes through the conveying surface to pass through the bed of materials on the conveying surface, a source of heated air coupled to the passages to supply heated air to the bed through the passages, and a vibration generator coupled to the conveying surface. The dryer also includes at least one rotary mixer having an impeller spaced from the conveying surface at a distance so as to be disposed within the bed, the at least one rotary mixer disposed along the length of the conveying surface between the inlet end and the outlet end. The at least one rotary mixer is adapted to provide uplift within the bed without de-densification of the bed.

Methods for drying a substrate. The methods include the following steps: (a) emitting infrared radiation towards a substrate moving through a process space using an emitter unit comprising at least one infrared emitter, (b) generating at least two process gas streams of a process gas directed towards the substrate, (c) drying the substrate by the action of infrared radiation and process gas on the substrate, and (d) extracting moisture-laden process gas from the process space via an extraction duct, forming an exhaust air stream leading away from the substrate. To specify a drying method which is reproducible and effective and leads to an improved result, in particular in terms of homogeneity and speed of drying of the substrate, the at least two process gas streams are guided to the infrared emitter before they act on the substrate, and an exhaust air stream is spatially assigned to each process gas stream.

Methods for drying a substrate. The methods include the following steps: (a) emitting infrared radiation towards a substrate moving through a process space using an emitter unit comprising at least one infrared emitter, (b) generating at least two process gas streams of a process gas directed towards the substrate, (c) drying the substrate by the action of infrared radiation and process gas on the substrate, and (d) extracting moisture-laden process gas from the process space via an extraction duct, forming an exhaust air stream leading away from the substrate. To specify a drying method which is reproducible and effective and leads to an improved result, in particular in terms of homogeneity and speed of drying of the substrate, the at least two process gas streams are guided to the infrared emitter before they act on the substrate, and an exhaust air stream is spatially assigned to each process gas stream.