A stress measuring structure, including a substrate, a support layer, a material layer, and multiple marks, is provided. The support layer is disposed on the substrate. The material layer is disposed on the support layer. There is a trench exposing the support layer in the material layer. The material layer includes a main body and a cantilever beam. The trench is located between the cantilever beam and the main body and partially separates the cantilever beam from the main body. One end of the cantilever beam is connected to the main body. The marks are located on the main body and the cantilever beam.

A stress sensing assembly includes: a stretchable substrate and at least one stress sensing line. The stress sensing line is disposed over the stretchable substrate and includes: rigid segments and flexible conductive segments. The rigid segments are separated from each other. Each of the flexible conductive segments is disposed between two adjacent rigid segments of the rigid segments and directly contacts the sidewalls of the two adjacent rigid segments of the rigid segments, and the Young's modulus of one of the flexible conductive segments is smaller than the Young's modulus of one of the rigid segments. A display device including stress sensing assembly is also disclosed herein.

A stress sensing assembly includes: a stretchable substrate and at least one stress sensing line. The stress sensing line is disposed over the stretchable substrate and includes: rigid segments and flexible conductive segments. The rigid segments are separated from each other. Each of the flexible conductive segments is disposed between two adjacent rigid segments of the rigid segments and directly contacts the sidewalls of the two adjacent rigid segments of the rigid segments, and the Young's modulus of one of the flexible conductive segments is smaller than the Young's modulus of one of the rigid segments. A display device including stress sensing assembly is also disclosed herein.

A structure for strain detection is provided with a ceramic main body which is attached to a detection target, in which strain is to be detected, and a stress concentrated section which is formed in the main body and which is fractured at a predetermined strain or greater. Assuming the dimension of the entire main body in one direction is represented by Lm and the dimension of the stress concentrated section in the one direction is represented by Lc, then it holds that Lc<Lm. The stress concentrated section is constituted by a thin-walled portion in the one direction.

A structure for strain detection is provided with a ceramic main body which is attached to a detection target, in which strain is to be detected, and a stress concentrated section which is formed in the main body and which is fractured at a predetermined strain or greater. Assuming the dimension of the entire main body in one direction is represented by Lm and the dimension of the stress concentrated section in the one direction is represented by Lc, then it holds that Lc<Lm. The stress concentrated section is constituted by a thin-walled portion in the one direction.

A tool is used in securing or clamping two or more workpieces together provides a visual indication to a user of the tool of an acceptable range of compression pressure exerted by the tool on a work surface of the workpieces and a visual indication of when a maximum compression pressure exerted by the tool on the work surface has been exceeded.

A tool is used in securing or clamping two or more workpieces together provides a visual indication to a user of the tool of an acceptable range of compression pressure exerted by the tool on a work surface of the workpieces and a visual indication of when a maximum compression pressure exerted by the tool on the work surface has been exceeded.

A stress sensing assembly includes: a stretchable substrate and at least one stress sensing line. The stress sensing line is disposed over the stretchable substrate and includes: rigid segments and flexible conductive segments. The rigid segments are separated from each other. Each of the flexible conductive segments is disposed between two adjacent rigid segments of the rigid segments and directly contacts the sidewalls of the two adjacent rigid segments of the rigid segments, and the Young's modulus of one of the flexible conductive segments is smaller than the Young's modulus of one of the rigid segments. A display device including stress sensing assembly is also disclosed herein.

A stress sensing assembly includes: a stretchable substrate and at least one stress sensing line. The stress sensing line is disposed over the stretchable substrate and includes: rigid segments and flexible conductive segments. The rigid segments are separated from each other. Each of the flexible conductive segments is disposed between two adjacent rigid segments of the rigid segments and directly contacts the sidewalls of the two adjacent rigid segments of the rigid segments, and the Young's modulus of one of the flexible conductive segments is smaller than the Young's modulus of one of the rigid segments. A display device including stress sensing assembly is also disclosed herein.

In one general aspect, a composite foam comprises a non-layered mixture of a polymeric foam with a plurality of voids; and a plurality of conductive fillers disposed in the polymeric foam. The conductive fillers are disposed in an even manner from outer surface to outer surface. In some implementations, the conductive fillers are up to 25% by weight of the composite foam. In some implementations, the composite foam may be used as padding. In some implementations, the composite foam may be used as a strain gauge.