A temperature calibration method for an ear thermometer with a probe cover is provided. The temperature calibration method includes: providing the ear thermometer with the probe cover, the ear thermometer including a plurality of activation elements which are configured to sense an infrared transmittance of the probe cover to obtain a measured transmittance value; using the ear thermometer to measure an object to be tested to obtain an uncalibrated temperature; obtaining an infrared radiation energy emitted by the object to be tested, according to the uncalibrated temperature, the measured transmittance value, a preset transmittance value, and a radiation energy measurement formula; and calibrating the uncalibrated temperature to a calibrated temperature, according to a temperature calibration function.

An infrared thermometer, having an upper shell, a lower shell, an ear temperature probe, and a forehead temperature head; the ear temperature probe is provided with an infrared sensor, an infrared sensor copper sleeve and a probe body; a piece of flat and smooth transparent glass is provided between an end of the probe body having a smaller inner diameter and the infrared sensor copper sleeve, so that the end of the ear temperature probe inserted into the ear canal is configured as a flat surface by the transparent glass.

An infrared thermometer capable of switching a forehead temperature measurement mode and an ear temperature measurement mode and a switching method are disclosed. The infrared thermometer includes an infrared thermometer body and a forehead temperature measurement cover. The infrared thermometer body has a measuring probe and a printed circuit board. The printed circuit board is connected with a first electrical contact. The forehead temperature measurement cover has a thermistor and a second electrical contact. The forehead temperature measurement cover is detachably connected to the infrared thermometer body to selectively cover or expose the measuring probe for switching the forehead temperature measurement mode and the ear temperature measurement mode.

The present disclosure discloses an infrared thermometer for a magnetic induction identification probe cap, including the body of the infrared thermometer, at an upper end of which is a temperature probe designed with a cap, of which an inner side wall is beset with a magnet block; in the infrared thermometer body ata lower end of the temperature probe is a magnetic induction element connected with a main control unit of the body of the infrared thermometer; when the cap covers the temperature probe or is removed there-from, the magnetic induction between the magnet block and the magnetic induction element enables magnetic induction output control signals. For the infrared thermometer applicable for both forehead temperature measurement and ear canal temperature measurement, the magnetic induction identification probe cap switches between a forehead temperature measurement mode and an ear canal temperature measurement mode.

The application provides an ear thermometer with a probe cover ejection device. The ear thermometer comprises a holding body and a measuring assembly disposed at one end of the holding body, which comprises a probe, a rotating member, and a socket. The rotating member includes a ring cover with an opening formed in a middle of the ring cover, at least one first abutting portion axially extended from a lateral side of the ring cover, and a lever portion radially extended from the lateral side of the ring cover. The socket includes a circular bottom surface and a closed section and an open section defined on a periphery of the circular bottom surface, a side wall surface vertically provided on the closed section, an accommodating space sandwiched between the side wall surface and the circular bottom surface, and at least one second abutting portion formed on the circular bottom surface. In this way, the dual motions of the radial and axial directions can be used to ensure that the probe cover can be reliably ejected and removed from the probe.

A protective cover for an insertion probe of a medical instrument. The cover contains a flexible tubular body that compliments the probe geometry and a radially disposed flange that surrounds the proximal end of the body. A series of snap-on fasteners removably connect the cover to the instrument. A camming surface is located on the outer face of the flange which coacts with a cam follower that is movably mounted upon the instrument to flex the cover sufficiently to open the fastener and release the cover from the instrument and move the cover axially toward the distal end of the tip.

A cap for a thermometer having a probe configured to be placed in contact with a patients body or to be inserted into a body cavity of the patient and a temperature sensor includes a cap housing, a proximity sensor and a proximity sensor electrical conductor. The cap housing is configured to selectively connect with and to be selectively detached from the thermometer and at least partially surround the probe of the thermometer when connected with the thermometer. The proximity sensor is connected with the cap. The proximity sensor electrical conductor is connected with the cap and electrically connected with the proximity sensor. A thermometer including the cap is also provided.

A detection device of the present invention includes a temperature sensor configured to detect a temperature of an eardrum of a human, a supporting member including a columnar portion, to a distal end of which the temperature sensor is attached, a cover that covers the temperature sensor, and a heat shrinkable tube that adheres tightly to a peripheral wall of the cover and a side surface of the columnar portion in a state in which the heat shrinkable tube is shrunk after being heated.

A probe cover for an ear thermometer includes a conical main body, an annular elastomer, a flange and a plurality of convex rib structures. The conical main body includes a closed end and an open end. The annular elastomer is connected with the open end of the conical main body. The flange is connected with the annular elastomer. The annular elastomer is arranged between the conical main body and the flange. The flange has a first surface and a second surface. The convex rib structures are disposed on the flange and spaced apart from each other, and the concave rib structures protrude upwardly from the first surface.

An infrared thermometer, having an upper shell, a lower shell, an ear temperature probe, and a forehead temperature head; the ear temperature probe is provided with an infrared sensor, an infrared sensor copper sleeve and a probe body; a piece of flat and smooth transparent glass is provided between an end of the probe body having a smaller inner diameter and the infrared sensor copper sleeve, so that the end of the ear temperature probe inserted into the ear canal is configured as a flat surface by the transparent glass.