A pressure-sensitive device includes a resin mixture in which a carbon nanotube is mixed, an electrode stacked on the resin mixture, and a pressurization unit that pressurizes the resin mixture in a direction of the stacking, wherein the pressurization unit includes an adjustment mechanism of adjusting an amount of the pressurization. Further, the pressurization unit has a first board, a second board placed along a direction of stacking on the first board, and a screw as the adjustment mechanism, and a distance between the first board and the second board changes by turning of the screw, and thereby, the amount of pressurization is adjusted.

The present invention relates to an article suitable to act as a thermal switch device, the article having a surface resistance of more than 10.sup.5 ohms and formed from a polymer composition comprising from 50 to 99.9 wt % relative to the total weight of the polymer composition, of a polymer being selected from an amorphous polymer having a glass transition temperature Tg, a semi-crystalline polymer having a melting temperature Tm or a mixture thereof, and from 0.1 to 50 wt % relative to the total weight of the polymer composition, of a conductive material, wherein the surface resistance of the article is divided by at least 10, preferably by at least 100, when said article is submitted for a determined period of time of less than 5 minutes to a temperature of switch i) ranging from Tg+10 C. to Tg+250 C. if the polymer composition comprises an amorphous polymer, or ii) ranging from Tm80 C. to Tm+250 C. if the polymer composition comprises a semi-crystalline polymer.

A circuit protection assembly has a protection element having a positive temperature coefficient of resistance and consisting of a polymer-based conductive composite material layer tightly clamped and fixed between two metal electrodes and a copper clad laminate having a through hole in a middle thereof, wherein the protection element is provided in the through hole, the copper clad laminate serves as a substrate for the circuit protection assembly and has an adhesive layer on an upper surface and a lower surface thereof, so as to cover the protection element in a space formed by the copper clad laminate and the upper and the lower adhesive layers. The protection element having a positive temperature coefficient of resistance is electrically connected to a protected circuit via a conductive part.

According to the invention there is provided an electrothermic composition comprising: at least one carbon component; at least one graphite component, and an optional binder or carrier, wherein the carbon, graphite, and/or their ratio are selected such that that the composition or a material formed from the composition has a thermal coefficient of electrical resistance (TCR) of about zero or is substantially stable over a predefined temperature range. The invention further relates to a product or a material produced or formed by the electrothermic composition. The invention additionally relates to a method of preparing an electrothermic composition comprising the steps of: (i) selecting a predetermined ratio of at least one carbon component and at least one graphite component such that the composition is electrically conductive, electrothermic and will have a TCR of about zero or is substantially stable over a predefined temperature range; and (ii) preparing the composition by mixing said at least one carbon component and said at least one graphite component, optionally in a suitable binder or carrier. Alternative embodiments relate to an electrothermic composition comprising: at least one carbon component; at least a second carbon component; and an optional binder or carrier; wherein the first carbon component, the second carbon component, and/or their ratio are selected such that that the composition or a material formed from the composition has a TCR of about zero or is substantially stable over a predefined temperature range.

Shown herein is a method of forming an electrical resistor comprising the steps of: forming an electrically resistive layer on a substrate; measuring an electrical resistance-related parameter of the electrically resistive layer and determining a target length of the electrically resistive layer corresponding to a target electrical resistance; and forming first and second electrically conductive terminals contacting the electrically resistive layer, said first and second electrically conductive terminals being separated by a distance corresponding to the target length.

A composition, method, and system for directly printing and creating complete functional 3D electronic circuits and devices without any thermal or laser post-processing treatment, by using at least Triphenylamine (TPA) as a powder binding agent. The composition can have mechanical characteristics that allow it to be melted and extruded on a structure, and electrical properties that allow it to function as at least one of a conductor, insulator, resistor, p-type semiconductor, n-type semiconductor, or capacitor.

A novel compound having exponential temperature dependent electrical resistivity comprises an electrically insulating bulk material (11), electrically conductive particles (12) of a first kind, and electrically conductive particles (13) of a second kind covered by a lubricant. The bulk material holds the particles of the first and second kinds in place therein; the particles of the second kind are smaller than the particles of the first kind; the particles of the second kind are more in number than the particles of the first kind; and the particles of the second kind have higher surface roughness than the particles of the first kind, wherein the particles of the second kind comprise tips (13a) and the particles of the first kind comprise even surface portions (12a). The particles of the first and second kinds are arranged to form a plurality of current paths (14) through the compound, wherein each of the current paths comprises galvanically connected particles of the first and second kinds and a gap (14a) between a tip (13a) of one of the particles of the second kind and an even surface portion (12a) of one of the particles of the first kind, which gap is narrow enough to allow electrons to tunnel through the gap via the quantum tunneling effect. The bulk material has a thermal expansion capability such that it expands with temperature, thereby increasing the gap widths (w) of the current paths, which in turn increases the electrical resistivity of the compound exponentially.

A polymeric positive temperature coefficient (PPTC) device including a PPTC body, a first electrode disposed on a first side of the PPTC body, and a second electrode disposed on a second side of the PPTC body, wherein the PPTC body is formed of a PPTC material that includes a polymer matrix and a conductive filler, wherein the conductive filler defines 20%-39% by volume of the PPTC material.

Shown herein is a method of forming an electrical resistor comprising the steps of: forming an electrically resistive layer on a substrate; measuring an electrical resistance-related parameter of the electrically resistive layer and determining a target length of the electrically resistive layer corresponding to a target electrical resistance; and forming first and second electrically conductive terminals contacting the electrically resistive layer, said first and second electrically conductive terminals being separated by a distance corresponding to the target length.

A heater comprising: (a) a non-woven heating layer having: a forward surface, a rearward surface, and a plurality of edges around a periphery of the heating layer; (b) two or more connections to a power source; wherein the heating layer is made up of a plurality of individual fibers that are randomly oriented; and wherein substantially all of the non-woven heating layer produces heat when power is to the non-woven heating layer.