A thermal insulation property measuring device, including a tank, a thermal insulator, a cuboidal frame, a support bracket, and a data collector. The tank includes an upper body, a first lower body, and a second lower body. The thermal insulator includes a first thermal insulation layer, a second thermal insulation layer, a first membrane, a second membrane, and a third membrane. The support bracket includes a trapezoidal support and a transition support. The tank is disposed on the support bracket. The support bracket is disposed in the cuboidal frame. The upper body, the first lower body, and the second lower body are spherical and communicate with each other. A filling tube, a pressure relief tube and a piezometer tube are disposed on the upper body. The first membrane is disposed on the tank. The first thermal insulation layer is coated on the first membrane.

A measurement mechanism having a body, a vacuum chamber that is located on the body and in which a measurement process is performed is disclosed. A first sample and a second sample between which a heat transfer occurs are placed in the vacuum chamber and contact each other. A piston that provides the first sample and the second sample to continuously contact each other, a main heater that is located above the first sample and the second sample, and a cooler located below the first sample and the second sample is also disclosed.

A measurement mechanism having a body, a vacuum chamber that is located on the body and in which a measurement process is performed is disclosed. A first sample and a second sample between which a heat transfer occurs are placed in the vacuum chamber and contact each other. A piston that provides the first sample and the second sample to continuously contact each other, a main heater that is located above the first sample and the second sample, and a cooler located below the first sample and the second sample is also disclosed.

A system and a method capable of identifying a heat source position corresponding to a failure portion are provided. An analysis system according to the present invention is an analysis system that identifies a heat source position inside a semiconductor device, and includes a tester that applies an AC signal to the semiconductor device, an infrared camera that detects light from the semiconductor device according to the AC signal and outputs a detection signal, and a data analysis unit that identifies the heat source position based on the detection signal.

A system and a method capable of identifying a heat source position corresponding to a failure portion are provided. An analysis system according to the present invention is an analysis system that identifies a heat source position inside a semiconductor device, and includes a tester that applies an AC signal to the semiconductor device, an infrared camera that detects light from the semiconductor device according to the AC signal and outputs a detection signal, and a data analysis unit that identifies the heat source position based on the detection signal.

A MEMS-based calorimeter includes a reference channel, a sample channel, and a thermopile configured to measure a temperature differential between the reference channel and a sample channel. The reference channel and the sample channel each include a passive mixer such as a splitting-and-recombination micromixer. The passive mixer can be formed by a first set of channels in a first layer and a second set of channels in a second layer. Methods for fabricating the MEMS-based calorimeter and methods of using the calorimeter to measure thermodynamic properties of chemical reactions are also provided.

An abnormality estimation apparatus for estimating an abnormality in a belt of a belt conveyor includes a displacement part that is displaced in accordance with tension or a change of the tension of the belt when the displacement part is caused to abut against the belt to receive the tension of the belt, an elastic body that is elastically deformed in accordance with displacement of the displacement part, a heat flow sensor that detects a heat flow occurring due to elastic deformation of the elastic body, and an abnormality estimation part that estimates whether there is an abnormality in the belt based on a detection result by the heat flow sensor.

An abnormality estimation apparatus for estimating an abnormality in a belt of a belt conveyor includes a displacement part that is displaced in accordance with tension or a change of the tension of the belt when the displacement part is caused to abut against the belt to receive the tension of the belt, an elastic body that is elastically deformed in accordance with displacement of the displacement part, a heat flow sensor that detects a heat flow occurring due to elastic deformation of the elastic body, and an abnormality estimation part that estimates whether there is an abnormality in the belt based on a detection result by the heat flow sensor.

Systems and methods for conducting non-destructive testing of fiber composite components are disclosed. The system may include a wire coil proximate the component and a power source connected to the wire coil. A controller may be connected to the power source and configured to continuously vary a current passing through the wire coil to generate a constantly changing magnetic field. A temperature sensor may be configured to detect a temperature of a plurality of regions of the component. The power source may be an AC or DC power source. The method may include generating a constantly changing magnetic field in proximity to a carbon-fiber composite, thereby inducing an electrical current in the carbon-fiber composite, and measuring a temperature of a plurality of different regions of the carbon-fiber composite to determine whether a defect is present. A defect may be identified by a temperature abnormality in a region.

Systems and methods for conducting non-destructive testing of fiber composite components are disclosed. The system may include a wire coil proximate the component and a power source connected to the wire coil. A controller may be connected to the power source and configured to continuously vary a current passing through the wire coil to generate a constantly changing magnetic field. A temperature sensor may be configured to detect a temperature of a plurality of regions of the component. The power source may be an AC or DC power source. The method may include generating a constantly changing magnetic field in proximity to a carbon-fiber composite, thereby inducing an electrical current in the carbon-fiber composite, and measuring a temperature of a plurality of different regions of the carbon-fiber composite to determine whether a defect is present. A defect may be identified by a temperature abnormality in a region.