The present invention relates to a method for contactlessly measuring the amount of menstrual blood in a menstrual cup. The amount of menstrual blood that has been stored in a menstrual cup can be simply measured by using a contactless sensor means, thereby enabling the user to periodically check the amount of menstrual blood. This enables early detection and treatment of uterine fibroid, which may even lead to hysterectomy.

The present invention relates to a method for contactlessly measuring the amount of menstrual blood in a menstrual cup. The amount of menstrual blood that has been stored in a menstrual cup can be simply measured by using a contactless sensor means, thereby enabling the user to periodically check the amount of menstrual blood. This enables early detection and treatment of uterine fibroid, which may even lead to hysterectomy.

A method comprising measuring a number of gamma-ray counts in a gamma-ray sensitive detector (60) that is placed outside a biological shield (10) near a primary cooling circuit (30) of a nuclear power plant, and determining the thermal power of the nuclear power plant based on the number of gamma-ray counts measured in the gamma-ray sensitive detector (60).

A method comprising measuring a number of gamma-ray counts in a gamma-ray sensitive detector (60) that is placed outside a biological shield (10) near a primary cooling circuit (30) of a nuclear power plant, and determining the thermal power of the nuclear power plant based on the number of gamma-ray counts measured in the gamma-ray sensitive detector (60).

A temperature measurement sensor for use in a nuclear reactor is described. The sensor includes a first neutron detector member and a second neutron detector member. The first neutron detector includes an outer shield material with an effective neutron capture cross section that is temperature dependent. The first neutron detector member outputs a first current signal and the second neutron detector member outputs a second current signal. An electrical connection between the first and second neutron detector members produces a net current that is the difference in current between the first and second signals. The difference is proportional to changes in temperature.

A method of stabilizing temperature sensing in presence of temperature-sensing component temperature variation includes steps of: obtaining response value caused by black body at first temperature of a thermal imager core chip; obtaining high-temperature first-order linear function of high-temperature black body response value versus thermal imager core chip temperature; obtaining low-temperature first-order linear function of low-temperature black body response value versus thermal imager core chip temperature; obtaining response value of high-temperature first-order linear function at first temperature, response value of high-temperature first-order linear function at second temperature of the thermal imager core chip, response value of low-temperature first-order linear function at first temperature, response value of low-temperature first-order linear function at second temperature, and response value of black body and substituting the five values into an equation for correcting the response values; and obtaining instant corrected value of the response value of the black body.

A method of stabilizing temperature sensing in presence of temperature-sensing component temperature variation includes steps of: obtaining response value caused by black body at first temperature of a thermal imager core chip; obtaining high-temperature first-order linear function of high-temperature black body response value versus thermal imager core chip temperature; obtaining low-temperature first-order linear function of low-temperature black body response value versus thermal imager core chip temperature; obtaining response value of high-temperature first-order linear function at first temperature, response value of high-temperature first-order linear function at second temperature of the thermal imager core chip, response value of low-temperature first-order linear function at first temperature, response value of low-temperature first-order linear function at second temperature, and response value of black body and substituting the five values into an equation for correcting the response values; and obtaining instant corrected value of the response value of the black body.

An acoustic lens suitable for a CMUT array (74) is provided. The acoustic lens comprising: a first layer (47) comprising a thermoset elastomer having a polymeric material selected from hydrocarbons, wherein the first layer has an inner surface (72) arranged to face the array and an outer convex shaped surface (40) arranged to oppose the inner surface; and a second layer (42) coupled to the outer surface of the first layer and comprising thermoplastic polymer polymethylpentene and an elastomer selected from the polyolefin family (POE) blended therein, wherein the outer layer located at the outer surface of the acoustic window layer, wherein the first layer has a first acoustic wave velocity (v1) and the second layer has a second acoustic wave velocity (v2), said second velocity is larger than the first acoustic wave velocity.

A sensor assembly includes: a sensor module including a cylindrical portion into which a measurement target fluid is introduced and a diaphragm including a first surface in contact with the measurement target fluid and a second surface provided with a detector; a joint provided with a pressure introduction port for introducing the measurement target fluid to the sensor module; a cylindrical base member surrounding the sensor module; an electronic circuit attached to the base member to receive a detection signal outputted by the detector; and a temperature sensor electrically connected with the electronic circuit. The temperature sensor includes a temperature detector for detecting temperature, and a lead wire electrically connecting the temperature detector and the electronic circuit. The base member is provided with a receiver for receiving the temperature detector and the lead wire.

A sensor assembly includes: a sensor module including a cylindrical portion into which a measurement target fluid is introduced and a diaphragm including a first surface in contact with the measurement target fluid and a second surface provided with a detector; a joint provided with a pressure introduction port for introducing the measurement target fluid to the sensor module; a cylindrical base member surrounding the sensor module; an electronic circuit attached to the base member to receive a detection signal outputted by the detector; and a temperature sensor electrically connected with the electronic circuit. The temperature sensor includes a temperature detector for detecting temperature, and a lead wire electrically connecting the temperature detector and the electronic circuit. The base member is provided with a receiver for receiving the temperature detector and the lead wire.