A cooking apparatus includes a non-ferrous cooking vessel configured to receive food. The cooking apparatus also includes a ferrous cooking vessel cover that is configured for placement over a top of the non-ferrous cooking vessel. The cooking apparatus also includes one or more induction heating elements suspended from the ferrous cooking vessel cover, and a radiation source. The radiation source is configured to deliver electromagnetic radiation to the ferrous cooking vessel cover and the one or more induction heating elements such that the ferrous cooking vessel cover and the one or more induction heating elements are heated.

A blow-by heater includes a metal pipe for flowing a blow-by gas therethrough. The metal pipe includes a flat portion on one side along an axis direction and a curved portion on a side opposite to the flat portion and is formed of a metal plate with a joining portion abutting against each other at edges of the metal plate at the curved portion. The blow-by gas heater further includes a resin molded over the metal pipe, and a heating source provided inside resin and directly contacting the flat portion.

A method for the manufacturing of an interior component for vehicles includes arranging a heating element in an injection mold and injecting a plastic melt into the injection mold in order to produce a base body. The heating element is disposed on a surface of the base body. The method further includes removing of the base body with the heating element from the injection mold after the plastic melt has solidified, and applying a cladding in order to clad the heating element and at least a part of the surface of the base body.

A food heating mat manufacturing process comprises the following steps: 1. manufacturing silicone layers; 2. treating a heating film; 3. combining the silicone layers and the heating film to form a mat body; 4. integrally molding the mat body at high temperature and high pressure; 5. assembling a food heating mat; and 6. testing the food heating mat; wherein in Step 1, the silicone layers are cut to a predetermined size.

A method for performing resin infusion into a dry reinforcement on a layup mandrel comprises placing resin at a resin zone on the mandrel; bagging the reinforcement and the resin with a bagging film; heating the resin while applying compaction pressure to the bagging film to cause the resin to be infused into the reinforcement; and creating a pressure differential outside of the bagging film over the resin zone to control rate and pressure at which the resin is infused into the reinforcement. As a result, the resin pressure and infusion rate are controlled independently of the compaction pressure on the reinforcement.

A system is disclosed for additively manufacturing a composite structure. The system may include a print head configured to receive a continuous reinforcement, and at least one of a matrix jet and a matrix bath configured to wet the continuous reinforcement with a liquid matrix during passage through the print head. The system may also include a coating mechanism configured to dispense at least one of metallic and ceramic particles onto the wetted continuous reinforcement during passage through the print head, and at least one cure enhancer configured to at least one of cure the liquid matrix and cause the at least one of metallic and ceramic particles to coalesce around the continuous reinforcement. The system may further include a support configured to move the print head in multiple dimensions during discharging.

An additive manufacturing system is disclosed. The additive manufacturing system may include a first print stage configured to discharge a first type of composite structure. The additive manufacturing system may also include a second print stage configured to discharge a second type of composite structure. The additive manufacturing system may further include a support configured to move the first and second print stages.

A head is disclosed for use with an additive manufacturing system. The head may include a nozzle configured to discharge multiple fiber strands oriented transversely adjacent each other relative to a travel direction of the head. The head may also include a matrix supply separately associated with each of the multiple fiber strands.

An additive manufacturing system is disclosed. The additive manufacturing system may include a plate having a plurality of print heads arranged in a grid and each configured to discharge a curable material, and at least one shuttle having a plurality of print heads arranged in a row and each configured to discharge a curable material. The additive manufacturing system may also include at least one cure enhancer associated with at least one of the plate and the at least one shuttle. The at least one cure enhancer may be configured to cure the curable material as the curable material is being discharged. The additive manufacturing system may further include at least one actuator configured to move at least one of the plate and the at least one shuttle during discharge of the curable material.

A system is disclosed for additively manufacturing a structure. The system may include a feeder configured to feed a thin-film material through the system, and a cutter configured to cut out of the thin-film material a pattern associated with a shape of the structure at a particular layer within the structure. The system may also include a placer configured to place the pattern in at least one of a desired location and a desired orientation.