A heater assembly includes a tubular body, a heater, and a support member. The tubular body is formed in a tubular shape and has a length that extends longitudinally. The heater is received within the tubular body. The heater provides thermal energy in response to being electrically energized. The heater includes a first surface side extending laterally and longitudinally along an inner peripheral surface of the tubular body. The heater includes n electrical contact, through which electrical energy is supplied to the heater. The support member is coupled to the heater and extends longitudinally. The support member defines an opening that exposes the electrical contact. The support member is configured to bend to facilitate coupling the heater to the support member.

In an image heating device having a plurality of heating blocks which are controllable independently in a longitudinal direction of a heater, an increase of the size of the heater can be suppressed, and temperatures of a plurality of heating block can be detected. A heater has a first temperature sensor corresponding to a first heating block, a second temperature sensor corresponding to a second heating block, a first electric conductor electrically coupled to the first temperature sensor, a second electric conductor electrically coupled to the second temperature sensor, and a common electric conductor electrically coupled to the first and second temperature sensors.

A resistance heating component is to come into contact with and heat a fixing belt made of a heat resistant material, and is to be provided at a position away from a fixing area between which the resistance heating component and the fixing belt a recording material is held and conveyed, the resistance heating component including: a metal base material having a low heat capacity; and a resistance heating layer laminated on a front surface or a rear surface of the base material with an insulating layer interposed between the base material and the resistance heating layer.

A heating roller includes a cylindrical member and a winding. The cylindrical member has a cylindrical body forming first and second sides along an axial direction. Plural wiring holes penetrate the cylindrical body along the axial direction and are each open on the first and second sides. The winding has a conductive wire penetrating the wiring holes. The conductive wire extends in opposite directions through each two adjacent wiring holes and is connected to a power source. Alternatively, the heating roller includes two windings each having plural conductive wires penetrating the corresponding wiring holes, wherein the conductive wires of one of the windings are connected to the positive and negative terminals of the power source at the first and second sides respectively, whereas the conductive wires of the other winding are connected to the negative and positive terminals of the power source at the first and second sides respectively.

Disclosed is a heat source for radiating heat onto an intermediate printing material transfer element of a printing apparatus. The heat source can include a plurality of heat generating segments disposed along an axis, the plurality of heat generating segments including a first heat generating segment, a second heat generating segment and a third heat generating segment. The second heat generating segment is disposed between the first heat generating segment and the third heat generating segment. The second heat generating segment has a length shorter than a length of the first heat generating segment and shorter than a length of the third heat generating segment. Also disclosed is a printing system that includes the disclosed heat source. Also disclosed is a method of selecting a heat radiating pattern of a heat source.

An image heating device includes a fixing belt (100) including a heat generating layer (102); a pressure roller (110) configured to rotationally drive the fixing belt; a power feed ring (119) disposed at one end of the fixing belt in a longitudinal direction and extending along an outer periphery of the fixing belt, the power feed ring being electrically connected to the heat generating layer; a brush (81) configured to be brought into contact with an outer periphery of the power feed ring and electrically connected to the power feed ring; a power supply circuit (79) configured to feed power to the brush; and a leaf spring (82) configured to elastically press the brush toward the power feed ring, the leaf spring being configured to come into contact with the power feed ring when the brush wears by a predetermined amount.

A heater is provided having at least one thermally sprayed resistive heating layer, the resistive heating layer comprising a first metallic component that is electrically conductive and capable of reacting with a gas to form one or more carbide, oxide, nitride, and boride derivative; one or more oxide, nitride, carbide, and boride derivative of the first metallic component that is electrically insulating; and a third component capable of stabilizing the resistivity of the resistive heating layer. In some embodiments, the third component is capable of pinning the grain boundaries of the first metallic component deposited in the resistive heating layer and/or altering the structure of aluminum oxide grains deposited in the resistive heating layer.

A heater according to an embodiment includes a substrate, a first wiring, a second wiring, and a plurality of first heating elements. Each first heating element includes an inclined portion, a first connecting portion, and a second connecting portion. When viewed from a direction perpendicular to the one surface of the substrate, the inclined portion is provided between the first wiring and the second wiring and inclined with respect to the first direction. An angle between the first (second) connecting portion side and the first (second) wiring side on an inclined portion side is larger than an angle between the first (second) wiring side on the inclined portion side and the inclined portion side on one (the other) side of the first direction where an angle between the inclined portion side and the first (second) wiring side on the inclined portion side is 90° or less.

Methods and systems for electrically heating and cooling rollers is described. A system may include one or more rollers comprising one or more electrical heating elements and one or more air channels. The one or more electrical heating elements may integrated to a power source and control circuit through an electrical contact on at least one end of the roller. The control circuit may additionally receive input from one or more temperature sensors.

In an image heating device having a plurality of heating blocks which are controllable independently in a longitudinal direction of a heater, an increase of the size of the heater can be suppressed, and temperatures of a plurality of heating block can be detected. A heater has a first temperature sensor corresponding to a first heating block, a second temperature sensor corresponding to a second heating block, a first electric conductor electrically coupled to the first temperature sensor, a second electric conductor electrically coupled to the second temperature sensor, and a common electric conductor electrically coupled to the first and second temperature sensors.