A sheet electrical resistance measuring device includes: a housing having a gap for receiving a sheet therein; a sheet pulling member comprising a first and second rotating rollers that are disposed in the housing and pulls the sheet inserted into the gap; a stopper that is disposed in the housing and causes the sheet pulling member to stop pulling the sheet; and a pair of electrodes that is disposed in the housing and measures electrical resistance of the sheet which is stopped and brought into contact with the pair of electrodes. The sheet electrical resistance measuring is capable of reducing the likelihood of wrinkles to be occurred when inserting the sheet, thereby increasing measurement accuracy of the sheet electrical resistance measuring device.

An electric measurement method and apparatus for detecting a mass by an electric capacity (permittivity) or a material's dielectric constant, or alternatively, electric inductance (permeability). The mass may be any phase or combination of phases. The mass may be stationary or flowing. It may comprise discrete particles such as grain, or manufactured products such as ball bearings or threaded fasteners, etc. The mass may be a flow element in a rotameter or similar flow measurement device. The sensor comprises a volume which may be completely full or only partially full of the material. The material may be discrete components or a continuum. Sensor signals may be received by existing planter monitoring systems. In some embodiments the flow sensors are positioned external to the application port. In some embodiments sensors may be utilized which are responsive to the refractive index variation of specific chemicals.

In a dielectric characteristic measurement method, a step of mounting a sample of which dielectric characteristic is measured on an open resonator and adjusting a position of the sample includes: a first measurement step for performing a first resonance measurement by sweeping a predetermined sweep frequency range at a first number of measurement points; and a second and subsequent measurement steps for performing a plurality times of resonance measurement following the first resonance measurement, wherein each of the plurality times of resonance measurement is performed by sweeping a sweep frequency range specified based on an immediately preceding resonance measurement at a second number of the measurement points which is less than the first number of the measurement points, and the sweep frequency range of a second resonance measurement in the plurality times of resonance measurement is specified based on the first resonance measurement.

An electric measurement method and apparatus for detecting a mass by an electric capacity (permittivity) or a material's dielectric constant, or alternatively, electric inductance (permeability). The mass may be any phase or combination of phases. The mass may be stationary or flowing. It may comprise discrete particles such as grain, or manufactured products such as ball bearings or threaded fasteners, etc. The mass may be a flow element in a rotameter or similar flow measurement device. The sensor comprises a volume which may be completely full or only partially full of the material. The material may be discrete components or a continuum. Sensor signals may be received by existing planter monitoring systems. In some embodiments the flow sensors are positioned external to the application port. In some embodiments sensors may be utilized which are responsive to the refractive index variation of specific chemicals.

A method and a device for detection of metal and non-metal particle concentration of an electrical discharge machining liquid are disclosed. The method comprises steps of: (A) filling a tank with the electrical discharge machining liquid, wherein the tank comprises a tank wall, a first conductor, and a second conductor; (B) measuring a voltage between the first conductor and the second conductor by an electronic device, wherein the electronic device electrically connects to the first conductor and the second conductor, and the electronic device comprises a capacitance detection circuit; and (C) calculating a particle concentration or an equivalent dielectric constant of the electrical discharge machining liquid on the basis of the measured voltage.

A dielectric constant microscope to observe a shape of a micro organic specimen includes first and second insulating films that are disposed to oppose each other such that the organic specimen along with the solution is interposed therebetween, and application-side conductive films P1 to Pn (where n is an integer greater than 1). The application-side conductive films are separated from each other on an outward surface of the first insulating film. Additionally, the dielectric constant microscope includes measurement-side conductive films p1 to pm (where m is an integer greater than 1) that are separated from each other on an outward surface of the second insulating film. Input signals Sf1 to Sfn having potential change at different frequencies are applied to the application-side conductive films P1 to Pn, potential change is measured for each of the measurement-side conductive films p1 to pm, and the organic specimen is visualized from a dielectric constant distribution between the first and second insulating films obtained by separating the potential change depending on the frequencies.

The method comprises the steps of: first, providing a sensor, the sensor consisting of a group of PCB copper foils; second, providing a depth detection signal Ftest which can change the detection frequency along with the change in detection depth, and applying the depth detection signal Ftest to the big and small polar plates of the sensor in the step S01 to form an electromagnetic field between the big polar plate and the small polar plates; third, providing a self-calibration signal Fcal acting on the big polar plate, to adjust a phase difference between the big polar plate and the small polar plates, thereby improving the detection sensitivity; and finally, performing shaping and phase comparison on signals output from the big and small polar plates driven by the depth detection signal Ftest, and processing signals output after filtering the phase-compared signals to judge the condition of a medium at the current detection depth.

A transparency, e.g. an aircraft laminated windshield, includes one or more moisture sensors to monitor moisture penetration to monitor performance of the moisture barrier. At least one of the moisture sensors includes a dielectric between and in electrical contact with two electrically conductive electrodes. Alternating electrical current is applied to the electrodes to measure the complex impedance (ohms) of the dielectric to determine the amount of moisture within the laminated windshield in the area of the moisture sensor. With the information provided by the moisture sensors performance of the windshield is available to schedule timely repair or replacement of the windshield that is performing outside of acceptable limits.

A transparency, e.g. an aircraft laminated windshield, includes one or more moisture sensors to monitor moisture penetration to monitor performance of the moisture barrier. At least one of the moisture sensors includes an electrolyte between and in ionic contact with two electrically conductive electrodes. Measuring the potential between the first and second electrode and/or the current through the electrodes to determine the amount of moisture within the laminated windshield in the area of the moisture sensor. With the information provided by the moisture sensors performance of the windshield is available to schedule timely repair or replacement of the windshield that is performing outside of acceptable limits.

A transparency, e.g. an aircraft laminated windshield, includes one or more moisture sensors to monitor moisture penetration to monitor performance of the moisture barrier. At least one of the moisture sensors includes an electrolyte between and in ionic contact with two electrically conductive electrodes. Measuring the potential between the first and second electrode and/or the current through the electrodes to determine the amount of moisture within the laminated windshield in the area of the moisture sensor. With the information provided by the moisture sensors performance of the windshield is available to schedule timely repair or replacement of the windshield that is performing outside of acceptable limits.