The invention relates to a special electrode arrangement for the targeted ohmic heating of different products, media or structures that are electrically conductive or contain electrically conductive constituents and have an inorganic or organic basis, including products of plant or animal origin, consisting of at least one electrode group comprising a plurality of individual electrodes. According to the invention, the individual electrodes are arranged at a distance apart from one another in an insulating carrier and, with the exception of an electrode surface region, are insulated from the product to be treated or the structure to be treated.

A DC powered cooking appliance which uses an induction or a resistance based DC heating element and excludes AC powered heating elements and preferably does not rely on directly connected combustion powered heating elements. Some embodiments include wattage of 1500 watts or less, voltages of 40 or 48 volts or more and are installed on a boat, van, rv or bus such that an inverter of that boat, van, rv or bus is not electrically connected to the cooking appliance.

A DC powered cooking appliance which uses an induction or a resistance based DC heating element and excludes AC powered heating elements and preferably does not rely on directly connected combustion powered heating elements. Some embodiments include wattage of 1500 watts or less, voltages of 40 or 48 volts or more and are installed on a boat, van, rv or bus such that an inverter of that boat, van, rv or bus is not electrically connected to the cooking appliance.

A protective case of a intelligent cup warmer includes a shell, a control circuit board, a heating device a thermal conductive tray, and a touch sensing switch. The thermal conductive tray is disposed on an upper side of the shell. The shell includes an installation chamber for accommodating the heating device and the control circuit board. An upper surface of the thermal conductive tray is configured to heat cups, a bottom surface of the thermal conductive tray are connected the heating device. The touch sensing switch includes a touch sensing area disposed on the shell, integrated with the shell and formed with the shell in the same molding process. The induction element is disposed between the touch sensing area and the control circuit board, one end of the induction element is in connected to the touch sensing area, and the other end is electrically connected to the control circuit board.

A protective case of a intelligent cup warmer includes a shell, a control circuit board, a heating device a thermal conductive tray, and a touch sensing switch. The thermal conductive tray is disposed on an upper side of the shell. The shell includes an installation chamber for accommodating the heating device and the control circuit board. An upper surface of the thermal conductive tray is configured to heat cups, a bottom surface of the thermal conductive tray are connected the heating device. The touch sensing switch includes a touch sensing area disposed on the shell, integrated with the shell and formed with the shell in the same molding process. The induction element is disposed between the touch sensing area and the control circuit board, one end of the induction element is in connected to the touch sensing area, and the other end is electrically connected to the control circuit board.

A hob plate above a radiant heating device and a safety temperature limiter between said radiant heating device and hob plate, which safety temperature limiter is designed to deactivate the radiant heating device when a switch-off temperature is reached. To actuate the radiant heating device, a cooking vessel is first placed on the hob plate above the radiant heating device and then the radiant heating device is activated and at the same time detection of a first switch-on time starts. When a switch-off temperature is reached at the safety temperature limiter, the radiant heating device is deactivated by said safety temperature limiter. The first switch-on time that has elapsed up to that point between activation and deactivation of the radiant heating device is detected and compared with a predefined limit switch-on time. If the first switch-on time lies below the limit switch-on time the radiant heating device is switched off.

A radiant electric heater having a dish-like support having a base layer of thermal insulation material. At least one heating element is supported relative to the base layer. A temperature-responsive device having a rod-like component is secured at one end at a peripheral region of the dish-like support and extends without support partly across the heater over the at least one heating element. A supporting member is provided at a free end region of the rod-like component. The supporting member comprises a central portion with a hoop at a first end to receive the free end of the rod-like component and a foot at a second end, the foot being bent at an angle relative to the central portion. A base of the dish-like support is provided with a loop of material extending internally of the dish-like support so as to provide an opening between the base of the dish-like support and the loop, the foot of the supporting member being received through the opening.

The invention provides a wafer heating pedestal including a shaft connected to a bottom of a plate. The shaft holds a contact array being in contact with plural contact pads of the plate. The contact array includes plural contact columns.

Embodiments described herein relate to a substrate support assembly which enables a cryogenic temperature operation of an electrostatic chuck (ESC) so that a substrate disposed thereon is maintained at a cryogenic processing temperature suitable for processing while other surfaces of a processing chamber are maintained at a different temperature. The substrate support assembly includes an electrostatic chuck (ESC), an ESC base assembly coupled to the ESC having a refrigerant channel disposed therein, and a facility plate having a coolant channel disposed therein. The facility plate includes a plate portion and a flange portion. The plate portion is coupled to the ESC base assembly and the flange portion coupled to the ESC with a seal assembly. A vacuum region is defined by the ESC, the ESC base assembly, the plate portion of the facility plate, the flange portion of the facility plate, and the seal assembly.

The present invention relates to an article comprising at least one glass-ceramic substrate, in particular a plate, intended, for example, to cover or receive at least one heating element, said substrate exhibiting, in at least one zone, a surface roughness such that the characteristic dimensions of the patterns forming said roughness are between 2 and 100 μm. The present invention also relates to an advantageous process for producing said substrate.