Medical or dental instruments, preferably handpieces, can have different temperature-measuring devices for measuring the temperature in the instrument or of at least a part of the instrument. The temperature-measuring devices can be designed, for example, to measure the temperature contactlessly by detection of electromagnetic radiation or to measure the temperature of an interior of the instrument that can be heated by a heat source. The temperature-measuring devices may be designed, for example, as electrical temperature-measuring devices or may have a magnetic material whose magnetic property is a function of temperature and/or has a temperature-dependent course. The temperature-measuring device may have, for example, an electrical switching device and a signal device wherein the signal device is switched at least between a first signal condition and a second signal condition when a temperature limit value is reached or exceeded or is underrun.

In one example, the present disclosure describes a magnetic temperature sensor. For instance, in one example, an apparatus includes a first magnet, a magnetometer housing the first magnet, and a temperature converter coupled to the magnetometer. The first magnet includes a material having a magnetic field whose strength fluctuates in response to changes in temperature. The magnetic field induces an electric current in the magnetometer. The temperature converter then converts a measurement of the electric current to a corresponding measurement of temperature.

A wireless temperature sensor includes an electrical conductor and a material spaced apart from the conductor and located within one or more of the responding electric field and responding magnetic field of the conductor. The conductor is electrically unconnected and is shaped for storage of an electric field and a magnetic field. In the presence of a time-varying magnetic field, the conductor resonates to generate harmonic electric and magnetic field responses, each of which has a frequency associated therewith. The material is selected such that it experiences changes in one of dielectric properties and magnetic permeability properties in the presence of a temperature change. Shifts from the sensor's baseline frequency response indicate that the material has experienced a temperature change.

A wireless temperature sensor includes an electrical conductor and a material spaced apart from the conductor and located within one or more of the responding electric field and responding magnetic field of the conductor. The conductor is electrically unconnected and is shaped for storage of an electric field and a magnetic field. In the presence of a time-varying magnetic field, the conductor resonates to generate harmonic electric and magnetic field responses, each of which has a frequency associated therewith. The material is selected such that it experiences changes in one of dielectric properties and magnetic permeability properties in the presence of a temperature change. Shifts from the sensor's baseline frequency response indicate that the material has experienced a temperature change.

The present disclosure relates to a system for monitoring a predeterminable temperature comprising a monitoring unit comprising a reference element composed at least partially of a material in which a phase transformation occurs at a phase transformation temperature, which lies in the region of the predetermined temperature, in which phase transformation the material remains in the solid phase, and a detection unit embodied to detect the occurrence of the phase transformation based on an abrupt change at least one physical or chemical parameter characteristic for the reference element and to generate a report concerning ex- or subceeding of the predeterminable temperature. Furthermore, the present disclosure relates to a monitoring unit and to a detection unit for application in a system of the disclosure as well as to a method for monitoring the predeterminable temperature by means of a system of the disclosure.

The present disclosure relates to a system for monitoring a predeterminable temperature comprising a monitoring unit comprising a reference element composed at least partially of a material in which a phase transformation occurs at a phase transformation temperature, which lies in the region of the predetermined temperature, in which phase transformation the material remains in the solid phase, and a detection unit embodied to detect the occurrence of the phase transformation based on an abrupt change at least one physical or chemical parameter characteristic for the reference element and to generate a report concerning ex- or subceeding of the predeterminable temperature. Furthermore, the present disclosure relates to a monitoring unit and to a detection unit for application in a system of the disclosure as well as to a method for monitoring the predeterminable temperature by means of a system of the disclosure.

Systems and methods for sensing, measuring, or monitoring the temperature of an electrical transmission line of an electrical cable, are provided. A temperature sensitive inductor is disposed in thermal contact with the electrical transmission line. The temperature of the electrical transmission line can be sensed, measured, or monitored by measuring the inductance of the temperature sensitive inductor. Mechanisms and methods to eliminate, minimize, or account for the magnetic coupling between the current carried by the electrical transmission line and the temperature sensitive inductor are provided.

Systems and methods for sensing, measuring, or monitoring the temperature of an electrical transmission line of an electrical cable, are provided. A temperature sensitive inductor is disposed in thermal contact with the electrical transmission line. The temperature of the electrical transmission line can be sensed, measured, or monitored by measuring the inductance of the temperature sensitive inductor. Mechanisms and methods to eliminate, minimize, or account for the magnetic coupling between the current carried by the electrical transmission line and the temperature sensitive inductor are provided.

A passive temperature-sensing apparatus, which includes a capacitive sensing element that includes a capacitive sensing composition that includes a ferroelectric ceramic material that exhibits a measurable electrical Curie temperature that is below 30 degrees C. The capacitive sensing composition exhibits a negative slope of capacitance versus temperature over the temperature range of from 30 degrees C. to 150 degrees C.

A passive temperature-sensing apparatus, which includes a capacitive sensing element that includes a capacitive sensing composition that includes a ferroelectric ceramic material that exhibits a measurable electrical Curie temperature that is below 30 degrees C. The capacitive sensing composition exhibits a negative slope of capacitance versus temperature over the temperature range of from 30 degrees C. to 150 degrees C.