A thermoplastic composite welding microwire temperature measurement system broadly comprises a plurality of moveable antennae configured to transmit interrogation signals, a rail system including a motorized linear stage configured to move the antennae along a weld line, and a reader or processor configured to determine a position of the microwire temperature sensor and determine a welding temperature based on response signals of the sensor. The interrogation signal corresponds to two different maximum ramp current amplitudes to create two re-magnetization pulses non-overlapping in the time domain.

Described herein are devices, methods and systems for measuring temperature in Automated Fiber Placement materials without contacting same via an antennae to measure current induced within an electromagnetic coil to accurately measure the temperature of the materials employed in the Automated Fiber Placement process.

Described herein are devices, methods and systems for measuring temperature in Automated Fiber Placement materials without contacting same via an antennae to measure current induced within an electromagnetic coil to accurately measure the temperature of the materials employed in the Automated Fiber Placement process.

The application describes embodiments including, e.g., a measurement device comprising: a casing, a first magnet arranged within the casing such that it is rotatable out of an equilibrium orientation responsive to an external magnetic torque acting on the first magnet, a second magnet to provide a restoring torque to force the first magnet back into the equilibrium orientation responsive to an external magnetic torque rotating the first magnet out of the equilibrium orientation, allowing for a rotational oscillation of the first magnet, which is excited by the external magnetic torque, with a resonant frequency, and a temperature sensitive magnetic material to modify the resonant frequency.

The application describes embodiments including, e.g., a measurement device comprising: a casing, a first magnet arranged within the casing such that it is rotatable out of an equilibrium orientation responsive to an external magnetic torque acting on the first magnet, a second magnet to provide a restoring torque to force the first magnet back into the equilibrium orientation responsive to an external magnetic torque rotating the first magnet out of the equilibrium orientation, allowing for a rotational oscillation of the first magnet, which is excited by the external magnetic torque, with a resonant frequency, and a temperature sensitive magnetic material to modify the resonant frequency.

A temperature-regulating unit includes a base, a resonant tank, and a controller. The base is configured to support a pan. The resonant tank includes a coil and a capacitor. The resonant tank has a resonant frequency that is affected by a material of the pan and a temperature of the pan. The controller is configured to receive a temperature setting, monitor the resonant frequency, determine the material of the pan based on the resonant frequency, determine the temperature of the pan based on the resonant frequency, and adaptively control a thermal element based on the temperature of the pan, the material of the pan, and the temperature setting.

A method of detecting temperature of an electrical terminal. The method includes: applying a material patch to a surface of the electrical terminal, the material patch containing a polymer matrix with a polymeric positive temperature coefficient material which contains a mixture of electrically conductive magnetic particles, whereby the material patch does not appreciably increase the electrical resistance or thermal capacitance of the electrical terminal; and remotely sensing a change in the material patch with an electrically isolated circuit which is external to the electrical terminal to determine if the electrical terminal is operating at a safe temperature to optimize current flow across the electrical terminal.

A device for measuring the temperature in a conductor includes at least one temperature sensor emitting a signal having a frequency changing due to a temperature change. The signals of the temperature sensor are transported through the conductor and the signals are inductively or capacitively coupled out of the conductor and into an evaluation unit for measuring the temperature through coupling elements.

A device for measuring the temperature in a conductor includes at least one temperature sensor emitting a signal having a frequency changing due to a temperature change. The signals of the temperature sensor are transported through the conductor and the signals are inductively or capacitively coupled out of the conductor and into an evaluation unit for measuring the temperature through coupling elements.

An apparatus for determining thermograms of blood plasma or serum includes two or more reaction vessels that each comprise a temperature sensing coil and a heating coil that is coaxial with and exterior to, or interleaved with, the temperature sensing coil. The apparatus also includes a heat conductive body having two or more cavities formed therein for receiving the reaction vessels. A corresponding method includes activating the heating coils of the reaction vessels and collecting temperature data for the reaction vessels with the temperature sensing coils.