A humidifier includes: moisture permeable members each having a tubular shape; a case housing the moisture permeable members; a first flow path portion in which one of cathode gas to be supplied to a fuel cell and cathode off-gas discharged from the fuel cell flows inside the moisture permeable members; a second flow path portion in which the other of the cathode gas and the cathode off-gas flows outside the moisture permeable members within the case; and a temperature sensitive member attached to at least one of the moisture permeable members, deformable in response to temperature, and deforming so as to decrease a gap between the moisture permeable members as the temperature decreases.

A resettable sensor assembly includes a body having a axis and defining a cavity therein. The body includes a first plurality of threads disposed about the axis. The assembly includes a housing mated to the body and including at least one electrical contact. The assembly further includes a plate. The assembly also includes an actuator element configured for translating the plate along the axis between a first position in which the plate contacts the at least one electrical contact and a second position in which the plate is spaced apart from the at least one electrical contact. The element is formed from a shape memory alloy that is transitionable between an austenite crystallographic phase and a martensite crystallographic phase in response to a thermal activation signal to thereby translate the plate between the first position and the second position.

A humidifier includes: moisture permeable members each having a tubular shape; a case housing the moisture permeable members; a first flow path portion in which one of cathode gas to be supplied to a fuel cell and cathode off-gas discharged from the fuel cell flows inside the moisture permeable members; a second flow path portion in which the other of the cathode gas and the cathode off-gas flows outside the moisture permeable members within the case; and a temperature sensitive member attached to at least one of the moisture permeable members, deformable in response to temperature, and deforming so as to decrease a gap between the moisture permeable members as the temperature decreases.

The present invention relates to temperature detection and indication technology and anti-counterfeit indication technology, and particularly to a temperature indication or multilevel anti-counterfeit indication label and a temperature indication or multilevel anti-counterfeit indication method based on a shape memory polymer. The temperature indication or multilevel anti-counterfeit indication label based on the shape memory polymer includes a matrix of a thermally driven shape memory polymer material, and one or more predeformations are formed on the matrix; the predeformation is formed in one or more stress processes at the same temperature; when multiple predeformations are formed, the sizes of the multiple predeformations are different; and when one predeformation is formed, the geometrical dimension of the predeformation continuously changes along the extension direction of the predeformation.

The sampling point valve, with a valve body that is movable in a valve housing between a closed position and an open position of the sampling point valve, wherein the valve body has a sample fluid channel, characterized in that the valve body is made of a material with a high thermal conductivity coefficient, preferably metal, that a signal unit with an essentially pot-shaped housing part made of a material with a high thermal conductivity coefficient, preferably metal, is in contact with the valve body, and that the signal unit includes a signal button that can be advanced out of a housing by a shape memory spring device when this device is warmed.

A temperature tag and methods of making and using the same are disclosed. The temperature tag includes one or more cantilevers, each having at least one end attached to a substrate, wherein the cantilever includes a shape memory material having at least one transformation temperature, and the cantilever is configured to transform in shape when exposed to a temperature equal to or above the at least one transformation temperature. Methods of preparing and using the temperature tag are also disclosed.

A structural health monitoring system based on a shape memory polymer includes a plurality of shape memory polymer buckling beam rod components, and a signal processing and structural health state abnormity warning platform. Each shape memory polymer buckling beam rod component includes an outer frame constraint, a shape memory polymer rod, and an electric signal generating element. The electric signal generating element includes piezoelectric material layers, and the signal processing and structural health state abnormity warning platform is electrically connected to the piezoelectric material layers.

The present invention relates to the technical field of thermal runaway management for lithium-ion batteries, and more particularly to a method for detecting and locating overheating in lithium-ion batteries or battery packs using temperature sensors. The temperature sensor is based on a shape memory alloy or bimetallic strips. The lithium-ion batteries or battery packs are equipped with these temperature sensors and arranged in a matrix configuration, enabling detection and localization of overheated batteries within the pack. This method addresses the challenge of identifying overheating in large-scale battery packs and energy storage power stations, thereby improving the efficiency of detection and localization. It also facilitates timely identification and precise location of batteries that may be undergoing thermal runaway.