A system (10) and method for transferring energy utilises an evacuated recirculation duct (11), with a pump (20) to circulate gas and a control nozzle (22) to form a jet of gas. Hydrogen gas is provided into the duct to be circulated, and an electrical device (30, 32) provides energy into the jet of gas so as to form hydrogen atoms. A heat exchanger (44) is arranged downstream of the electrical device (30, 32), onto which the flowing jet of gas impacts. Means (40) are also provided to generate an electric or magnetic field in the region of the jet of gas between the electrical device (30, 32) and the heat exchanger (44), and is connected to a source (42) of electricity. For example an electromagnet coil (40) and may generate a magnetic field (B) transverse to the direction of travel of the jet of gas, or an electromagnet coil (40A, 40B) may generate a magnetic field parallel to the jet of gas.

A system (10) and method for transferring energy utilises an evacuated recirculation duct (11), with a pump (20) to circulate gas and a control nozzle (22) to form a jet of gas. Hydrogen gas is provided into the duct to be circulated, and an electrical device (30, 32) provides energy into the jet of gas so as to form hydrogen atoms. A heat exchanger (44) is arranged downstream of the electrical device (30, 32), onto which the flowing jet of gas impacts. Means (40) are also provided to generate an electric or magnetic field in the region of the jet of gas between the electrical device (30, 32) and the heat exchanger (44), and is connected to a source (42) of electricity. For example an electromagnet coil (40) and may generate a magnetic field (B) transverse to the direction of travel of the jet of gas, or an electromagnet coil (40A, 40B) may generate a magnetic field parallel to the jet of gas.

An induction heating device for heating and/or melting a heat affected product zone of shaving or cosmetic products stored in a product container which consists of a layer of the product heated by an electrically conductive metallic target member having through-passages overlying the top product surface and energized by an induction coil into which an electromagnet field is generated by electronic circuitry for a predetermined time period into the product container, thereby permitting the heated and or melted product to flow through the through-passages onto the top surface of the target member to be collected by a user for shaving or cosmetic purposes.

A system (10) and method for transferring energy utilises an evacuated recirculation duct (11), with a pump (20) to circulate gas and a control nozzle (22) to form a jet of gas. Hydrogen gas is provided into the duct to be circulated, and an electrical device (30, 32) provides energy into the jet of gas so as to form hydrogen atoms. A heat exchanger (44) is arranged downstream of the electrical device (30, 32), onto which the flowing jet of gas impacts. Means (40) are also provided to generate an electric or magnetic field in the region of the jet of gas between the electrical device (30, 32) and the heat exchanger (44), and is connected to a source (42) of electricity. For example, an electromagnet coil (40) and may generate a magnetic field (B) transverse to the direction of travel of the jet of gas, or an electromagnet coil (40A, 40B) may generate a magnetic field parallel to the jet of gas.

A system (10) and method for transferring energy utilises an evacuated recirculation duct (11), with a pump (20) to circulate gas and a control nozzle (22) to form a jet of gas. Hydrogen gas is provided into the duct to be circulated, and an electrical device (30, 32) provides energy into the jet of gas so as to form hydrogen atoms. A heat exchanger (44) is arranged downstream of the electrical device (30, 32), onto which the flowing jet of gas impacts. Means (40) are also provided to generate an electric or magnetic field in the region of the jet of gas between the electrical device (30, 32) and the heat exchanger (44), and is connected to a source (42) of electricity. For example, an electromagnet coil (40) and may generate a magnetic field (B) transverse to the direction of travel of the jet of gas, or an electromagnet coil (40A, 40B) may generate a magnetic field parallel to the jet of gas.

An electrode is embedded in a piece of ceramic material having a population of conduction band electrons. Applying a voltage bias to the electrode causes electrons to flow towards or away from the electrode to form a positively charged sheath either a distance apart from or adjacent the electrode, depending the polarity of the bias. The electron flow also forms a negatively charged sheath lying opposite the positively charged sheath, and an electrically neutral region lying between the two sheaths. Electromagnetic radiation impinging the ceramic material heats the ceramic where the radiation is absorbed by the electron population. As the incident radiation is absorbed in proportion to the electron density, heating is increased in the negatively charged sheath, relative to the other parts of the ceramic material. The location of heating is controlled by controlling the magnitude and polarity of the voltage bias.

An electrode is embedded in a piece of ceramic material having a population of conduction band electrons. Applying a voltage bias to the electrode causes electrons to flow towards or away from the electrode to form a positively charged sheath either a distance apart from or adjacent the electrode, depending the polarity of the bias. The electron flow also forms a negatively charged sheath lying opposite the positively charged sheath, and an electrically neutral region lying between the two sheaths. Electromagnetic radiation impinging the ceramic material heats the ceramic where the radiation is absorbed by the electron population. As the incident radiation is absorbed in proportion to the electron density, heating is increased in the negatively charged sheath, relative to the other parts of the ceramic material. The location of heating is controlled by controlling the magnitude and polarity of the voltage bias.

Cooking device includes heating chamber with door for housing object to be heated, vapor generator for supplying vapor into heating chamber, and water storage tank. Cooking device further includes cooling air passage provided between heating chamber and water storage tank and allowing cooling air to pass therethrough, and air inlet provided to the side of door and introducing cooling air into cooling air passage. This enables cooling, using a smaller and more inexpensive cooling fan. As a result, cooking device is made shorter in overall height.

In accordance with one embodiment of the present disclosure, a cooking apparatus includes a casing, a cooking chamber formed inside the casing, a duct member formed outside the cooking chamber to extend from a first plate of the cooking chamber to a second plate forming an upper surface of the cooking chamber, a heater installed inside the duct member, and a fan installed inside the duct member and configured to blow air in the duct member, wherein the cooking chamber is formed to cook food using high-temperature air discharged into the cooking chamber through a first outlet part formed at the second plate.

An electromagnetic induction heating element includes a first heating layer 11 formed of electrocast nickel and having an endless-belt-like form; a second heating layer 12 formed of a non-magnetic material; and a coating layer 13 having a thickness of 3 μm or less, wherein the first heating layer 11, the second heating layer 12, and the coating layer 13 are sequentially stacked.