A self-energy type thermal response monitoring device includes a periphery constraint assembly, a variable-frequency beam arranged in the periphery constraint assembly, piezoelectric patches covering the variable-frequency beam, and an electric signal collector electrically connected to the piezoelectric patches. Deformation of the variable-frequency beam is limited by innovatively using rigid constraint, and a low-frequency thermal load is converted into a high-frequency post-buckling impact to trigger a piezoelectric material to generate an electric signal.

A self-energy type thermal response monitoring device includes a periphery constraint assembly, a variable-frequency beam arranged in the periphery constraint assembly, piezoelectric patches covering the variable-frequency beam, and an electric signal collector electrically connected to the piezoelectric patches. Deformation of the variable-frequency beam is limited by innovatively using rigid constraint, and a low-frequency thermal load is converted into a high-frequency post-buckling impact to trigger a piezoelectric material to generate an electric signal.

A fiber optic temperature sensor, a sensing head structure, and a manufacturing method are provided. The fiber optic temperature sensor includes a broad spectrum light source, a first fiber optic coupler, a spectrometer, a first sensing interferometer, and a second sensing interferometer. The first sensing interferometer and the second sensing interferometer have opposite temperature responses. A first free spectral range corresponding to the first sensing interferometer is close to but not equal to a second free spectral range corresponding to the second sensing interferometer. In the fiber optic temperature sensor, two sensing interferometers both sensitive to temperature are used, and the two sensing interferometers have opposite temperature responses, thereby achieving an enhanced vernier effect, and improving the sensitivity of temperature measurement.

A device comprising a gate pad, a source pad and a passive actuator arranged to form a reversible mechanical and electrical connection between the gate pad and the source pad only if the temperature in the passive actuator exceeds a threshold value.

A fiber optic temperature sensor, a sensing head structure, and a manufacturing method are provided. The fiber optic temperature sensor includes a broad spectrum light source, a first fiber optic coupler, a spectrometer, a first sensing interferometer, and a second sensing interferometer. The first sensing interferometer and the second sensing interferometer have opposite temperature responses. A first free spectral range corresponding to the first sensing interferometer is close to but not equal to a second free spectral range corresponding to the second sensing interferometer. In the fiber optic temperature sensor, two sensing interferometers both sensitive to temperature are used, and the two sensing interferometers have opposite temperature responses, thereby achieving an enhanced vernier effect, and improving the sensitivity of temperature measurement.

The present disclosure relates to a system for determining the shut-down temperature and melt-down temperature of a separator. The system includes a jig having a through-hole, a heating unit, a temperature sensor, a controlling unit and an air permeability-determining unit. In this manner, it is possible to provide a novel system for determining the shut-down temperature and melt-down temperature of a separator by using the air permeability (Gurly value) of the separator.

The present disclosure relates to a system for determining the shut-down temperature and melt-down temperature of a separator. The system includes a jig having a through-hole, a heating unit, a temperature sensor, a controlling unit and an air permeability-determining unit. In this manner, it is possible to provide a novel system for determining the shut-down temperature and melt-down temperature of a separator by using the air permeability (Gurly value) of the separator.

A sleeving apparatus includes a worm gear. The worm gear has a plurality of threads, the worm gear receptive of a bead between adjacent threads of the plurality of threads. A plurality of flexible diaphragms are positioned along the worm gear. Each diaphragm of the plurality of diaphragms is configured to position a wire in alignment with a central bead opening of the bead. With rotation of the worm gear about a worm gear axis, the bead advances onto the wire with the wire passing into the central bead opening. The plurality of diaphragms are configured to allow passage of the bead through each diaphragm of the plurality of diaphragms.

A sleeving apparatus includes a worm gear. The worm gear has a plurality of threads, the worm gear receptive of a bead between adjacent threads of the plurality of threads. A plurality of flexible diaphragms are positioned along the worm gear. Each diaphragm of the plurality of diaphragms is configured to position a wire in alignment with a central bead opening of the bead. With rotation of the worm gear about a worm gear axis, the bead advances onto the wire with the wire passing into the central bead opening. The plurality of diaphragms are configured to allow passage of the bead through each diaphragm of the plurality of diaphragms.

A sleeving apparatus includes a worm gear. The worm gear has a plurality of threads, the worm gear receptive of a bead between adjacent threads of the plurality of threads. A plurality of flexible diaphragms are positioned along the worm gear. Each diaphragm of the plurality of diaphragms is configured to position a wire in alignment with a central bead opening of the bead. With rotation of the worm gear about a worm gear axis, the bead advances onto the wire with the wire passing into the central bead opening. The plurality of diaphragms are configured to allow passage of the bead through each diaphragm of the plurality of diaphragms.