A method of operating a temperature calibrator for calibrating a temperature sensor having a calibration block into which the temperature sensor is introduced and having a heating means by which the calibration block is heated and having a cooling unit by which the calibration block is cooled and an actuator by which the cooling unit is brought into thermal conductivity contact with the calibration block during cooling and is spatially separated from the calibration block during heating while forming an air gap. The invention further relates to a temperature calibrator is also disclosed.

A low-temperature dry body temperature calibrator used for temperature calibration of an element, and including a furnace body, a control panel assembly and a housing of modular design, the furnace body and control panel are assembled in the housing, the top surface of the housing has a plurality of heat dissipation holes, the top of the control panel assembly is spaced apart from the top surface of the housing, a flow guiding fan is at the top of the control panel assembly, and a flow guiding plate inclined to the heat dissipation holes on the top surface of the housing is above the flow guiding fan. The furnace body has a compact structure, and the radiators have a light weight and a high heat dissipation efficiency, improving the operation stability and temperature measurement accuracy of the furnace body, and the furnace body is suitable for temperature measurement of low-temperature elements.

Various dry well temperature calibration systems, as well as other temperature control systems, are disclosed. The system can include a well configured to receive a unit under test, a heater configured to heat the well, and a temperature sensor configured to detect a temperature of the well. The system can include a helical airflow groove around the well. A venturi pump unit can be in fluid communication with the airflow groove. The venturi pump unit can be configured to draw a flow of air through the airflow groove, thereby cooling the well.

One or more embodiments are directed to zero-rate level compensation systems. One such system includes stationary detection circuitry that receives gyroscope signals output by a gyroscope and determines whether the gyroscope is stationary based on the gyroscope signals. The stationary detection circuitry generates a stationary gyroscope signal indicating the gyroscope is stationary based on a determination that the gyroscope is stationary. A temperature sensor senses temperature and outputs temperature signals. Zero-rate level estimation circuitry receives the stationary gyroscope signal and a temperature signal associated with the stationary gyroscope signal, and iteratively estimates one or more zero-rate level compensation parameters based on the stationary gyroscope signal and the temperature signal.

A temperature controlled calibration source for thermal imaging that provides for extremely inexpensive, mass producible, field deployable thermal calibration in specific, relatively low temperature ranges, and in particular temperatures near nominal human body temperature. A calibration source suitable for such applications may be implemented primarily as a suitable designed Printed Circuit Board (PCB), packaged in a thermally isolating housing and powered of commonly available power sources such as USB chargers.

A temperature monitoring system for accurate and real-time temperature monitoring may be employed at a conduit and/or a temperature control element. The conduit is configured to transport a fluid along the length of the conduit, and the conduit may comprise a variety of conduit structures having numerous cross-sections, shapes, orientation, geometry, operating conditions, operation functions, etc. The temperature control element operatively coupled to the conduit may be utilized to control the temperature of the fluid within the conduit. Typically, the temperature control element is configured to heat or cool the fluid within the conduit. The temperature monitoring system may further comprise one or more temperature sensors, such as distributed temperature sensor(s) or discrete temperature sensor(s), operatively coupled to the conduit and/or the temperature control element. The temperature sensor(s) are configured to capture temperature readings at one or more locations along the length of the conduit or the temperature control element.

The present invention discloses methods for detecting and improving temperature stability in measurements performed by a dry block, i.e. a temperature calibrator. The dry block comprises a heating and cooling device. An energy metering integrated circuit measures an applied input power to the heating elements of the heating and cooling device. Additionally, a real-time compensation algorithm uses measurement results obtained by the energy metering integrated circuit, and outputs a control signal to the heating elements. The arrangement may comprise a back draft damper adjacent to a fan. The fan position may be selected. Stability criteria may be set. Leaning of the dry block can be tracked. Different sensors are used for the temperature control and for the temperature stability indication.

The present invention combines the functionalities of a multifunctional process calibrator with a heating and/or cooling unit (also called as a dry block). The heating and/or cooling unit and the process calibrator are integrated in a single housing forming the arrangement. The arrangement allows using several digital communication protocols i.e. fieldbus protocols. Temperature sensor simulation is possible as well. Pressure measurement and/or calibration is also enabled. The arrangement is supplied with internal rechargeable battery, which enables all other functionalities without mains power, except the use of the heating and/or cooling unit, where the mains power is required.

The present invention discloses a temperature calibrator, which comprises or has an externally attached inclination angle sensing means. A temperature sensor and an internal battery is applied as well, together with a fan. The temperature calibrator comprises regular heating elements, a processor, and a User Interface. The system measures the inclination angle and internal temperature of the temperature calibrator. If the angle or temperature value or both exceed a certain threshold value, the system is configured to switch off the heating elements immediately, and to show or send a warning indicator or signal to the user or manager of the device via the UI 22, e.g. through a red LED light, a beeping sound or a warning message on the screen of the temperature calibrator or of the remote device.

A flow guiding and heat dissipating type dry block temperature calibrator, which belongs to the temperature calibration field. The temperature calibrator includes a furnace body located in a housing and at least one air flow generating device. The air flow generating device is on one side or at the periphery of the furnace body, and is one or a combination of a gas passage, a flow guiding fan, an air pump and a blower. The air flow generated by the air flow generating device is blown toward a handle of a device being tested that is inserted in the furnace body, such that the handle is cooled, thereby preventing the sensor inside the handle from failing due to high temperature, facilitating the heat dissipation of the internal electronic components of the instrument itself, and extending the service life of the temperature calibrator.