An electrical load resistance includes a housing having at least one U-shaped receiving pocket, in which at least one PTC heating element is accommodated. The PTC heating element includes at least one PTC element and at least one contact plate electrically conductively connected to the PTC element for energizing the PTC element. The contact plate has a terminal lug for plug contacting the PTC element, and the PTC heating element abuts at least on opposite main side surfaces of the receiving pocket in a heat-conducting manner and projects beyond the terminal lug of the receiving pocket. The housing of the electrical load resistance is closed, and thus has no inlet or outlet openings for a medium to be heated. Also provided is a device with an electrical load resistance for reducing the starting time of an internal combustion engine, a method for reducing the starting time of an internal combustion engine, and a use of a PTC heating device as an electrical load resistance for reducing the starting time of an internal combustion engine.

A heater is provided for heating an aerosol-forming substrate, the heater including: a heating element to heat the aerosol-forming substrate, the heating element including at least one positive temperature coefficient (PTC) thermistor, the PTC thermistor being configured to be supplied with an electric current so as to heat the PTC thermistor, in which a resistance of the PTC thermistor increases when a temperature of the PTC thermistor increases within a stabilised temperature range, a lower end of the stabilised temperature range being, when a constant voltage is applied to the PTC thermistor, a reference temperature at which the resistance of the PTC thermistor is twice a value of a minimum resistance of the PTC thermistor, and in which the reference temperature is between about 100° C. and about 350° C. when a constant voltage of 3.3V is applied to the PTC thermistor.

The invention, according to a first aspect, relates to a cover (4) of an electronic interface housing (300) of an electrical heating device for a motor vehicle, the cover (4) comprising at least one pressing member (44a, 44b) and at least one pressing element (45) which are configured to be in contact with a printed circuit board (5) when the cover (4) is fixed on the electronic interface housing (300), a free end of the at least one pressing member (44a, 44b) extending in a first transverse plane (451) and a free end (4501) of the at least one pressing element (45) extending in a second transverse plane (452), the at least one pressing member (44a, 44b) and the at least one pressing element (45) being arranged so that they project, in a direction perpendicular to a reference plane (400) of the cover (4), from an inner face of the cover (4) intended to face toward the inside of the electronic interface housing (300), characterized in that the first transverse plane (451) and the second transverse plane (452) are substantially parallel to one another and to the reference plane of the cover, strictly not coincident with one another or with the reference plane (400) of the cover (4), the second transverse plane (452) being, in a direction perpendicular thereto, closer to the reference plane (400) of the cover (4) than the first transverse plane (451).

A heating unit for heating an enclosure includes a base having a central axis, a first end, a second end axially opposite the first end, and a cavity extending axially from the first end. In addition, the heating unit includes a heater disposed in the cavity of the base. Further, the heating unit includes a heat sink mounted to the base. The heat sink includes a plurality of laterally spaced fins and a plurality of laterally spaced channels positioned between the plurality of fins. Still further, the heating unit includes a manifold coupled to the base. A surface of the manifold faces the base and the heat sink. The manifold includes a flow passage and a plurality of orifices in fluid communication with the flow passage. Each orifice has an outlet at the surface of the manifold that is aligned with one of the channels of the first heat sink.

This disclosure refers to a method for confectioning resistors that each comprise a PTC ceramic plate and metallic electrode layers covering opposite faces of the ceramic plate, said method comprising the following steps: measuring an electrical resistance of a resistor to be confectioned by applying an electrical potential to one of electrode layers such that an electric current flows from one of the electrode layers through the ceramic plate to the electrode layer on the opposite face of the ceramic plate, comparing the measured resistance to a target resistance, and removing, if the measured resistance is lower than the target resistance, a section of at least one of the electrode layers. This disclosure also refers to such a resistor and a heating device comprising such resistors.

A warming device for the handrim of a wheelchair is disclosed herein to relieve discomfort caused by manually wheeling a wheelchair in cold and/or wet weather conditions. The warming device includes a hand interface, a mount, and a heating element. The warming device is configured to mount the tube of a handrim. The heating element of the warming device is coupled to an electronics system including a printed circuit board and a battery. The electronics system may be internal to the warming device, or may be housed in an external electronics box mounted similarly to the handrim or the rear wheel of the wheelchair.

The invention relates to a method for operating a heating element (210), in particular in a food processor (1) for the at least partially automatic preparation of foodstuffs, wherein the following steps are performed: a) detecting an electrical resistance of the heating element (210) such that at least one resistance value is determined, b) performing a heating operation on the heating element (210) based on the at least one determined resistance value to perform the heating operation depending on a temperature of the heating element (210).

A method for regulating a PTC heating with at least one PTC heating element and a control unit for controlling the PTC heating element is disclosed. The method includes: controlling with the control unit the PTC heating element to a target output via a control variable; receiving via PTC heating element, with the target output of the control unit, an electrical input power and emitting a thermal heating output to an environment; in a testing step the control unit keeps the target output constant over a predefined plateau duration and checks the PTC heating element for a critical imbalance state where the PTC heating element regulates itself by an increasing of its resistance; and after the testing step, when the control unit detects the critical imbalance state, the control unit reduces the target output in a regulating step.

A PTC heating assembly has a plurality of PTC elements and electric strip conductors between which the PTC elements are provided and which are electrically conductively connected to the PTC elements The PTC heating assembly also includes a frame which forms at least one receptacle for the PTC elements and which is provided between the strip conductors. For adjusting the heating power of the PTC heating assembly, at least two strip conductors on at least one side of the PTC elements are electrically conductively connected to PTC elements which deviate from one another.

The present disclosure relates to a heating element (5) for heating electrical equipment mounted on a DIN rail (1). The heating element (5) comprises an elongated flexible sheet (11) made of an electrically insulating material and a layer comprising Positive Temperature Coefficient paint (12) disposed on an upper surface (11a) of the flexible sheet (11). A method for mounting the heating element (5) to a DIN rail is provided. The method comprises bending the flexible sheet (11) such that an inverted U-shape is formed along the length of the flexible sheet and inserting the heating element (5) into a groove of the DIN rail (1) such that the bent flexible sheet stays in position by spring force of the bend. A use of the heating element for heating a DIN rail is also provided.