Embodiments relate to a method and apparatus for investigating the uniformity of concrete and/or grout. Embodiments can identify the existence of one or more anomalies in the uniformity of concrete and/or grout, and/or determine or estimate the size, shape, type, and/or location of one or more anomalies in the uniformity of concrete and/or grout. Embodiments can utilize a string of temperature measuring sensors placed within one or more access bore(s), such as tube(s), positioned at least partially within the concrete and/or positioned proximate the concrete. The measurements obtained from the temperature measuring sensors can then be used to assist in the identification of existence of, size of, type of, shape of, and/or location of anomalies in the concrete and/or grout.

A stretchable temperature sensor includes one or more elastomeric ionic conducting layers; at least two electronic conducting elements, wherein the one or more ionic conducting layers and one or more electronic conducting elements are configured and arranged to provide at least one electrical double layer at a first contact area between the ionic conducting layer and a first electronic conducting element in a sensing end and at least one electrical double layer at a contact area between the ionic conducting layer and a second electronic conducting element in an open end of the temperature sensor; wherein the second electronic conducting element provides a connection at the open end to an external circuit for measuring a signal generated in response to a temperature condition at the sensing end.

A stretchable temperature sensor includes one or more elastomeric ionic conducting layers; at least two electronic conducting elements, wherein the one or more ionic conducting layers and one or more electronic conducting elements are configured and arranged to provide at least one electrical double layer at a first contact area between the ionic conducting layer and a first electronic conducting element in a sensing end and at least one electrical double layer at a contact area between the ionic conducting layer and a second electronic conducting element in an open end of the temperature sensor; wherein the second electronic conducting element provides a connection at the open end to an external circuit for measuring a signal generated in response to a temperature condition at the sensing end.

A system for storing and monitoring grain includes a grain bin for storing grain and a plurality of sensor cables suspended within the grain bin, the sensor cables comprising sensors for sensing one or both of the temperature and humidity of the grain. The system further includes a mobile device for reading codes on each of the sensor cables, wherein the mobile device assigns a cable location inside the grain bin to each of the sensor cables. In a manual setup, the mobile device displays a representation of a cable configuration, displays a request to connect the sensor cables in indicated locations and then assigns the cable locations to each sensor cable.

A system for storing and monitoring grain includes a grain bin for storing grain and a plurality of sensor cables suspended within the grain bin, the sensor cables comprising sensors for sensing one or both of the temperature and humidity of the grain. The system further includes a mobile device for reading codes on each of the sensor cables, wherein the mobile device assigns a cable location inside the grain bin to each of the sensor cables. In a manual setup, the mobile device displays a representation of a cable configuration, displays a request to connect the sensor cables in indicated locations and then assigns the cable locations to each sensor cable.

The present disclosure describes methods and apparatus for remote sensing with data science. The methods and apparatus have many applications including monitoring the quality of grain during storage and/or transport. The present disclosure describes a way to collect temperature and other environmental data to describe and predict quality of stored grains, current and future, based on a myriad factors including fumigation, external temperature and humidity, in storage grain temperature and humidity.

A method comprising obtaining a desired storage criterion for each of a plurality of products, the desired storage criteria including at least one condition, the at least one condition including a product temperature range; based on the product temperature range setting for each product at least one alert temperature range; calculating a current temperature of each of the plurality of products located in a compartment at a current time; calculating future temperatures of each of the plurality of products at a plurality of future times based on the current temperatures and expected changes between the current time and the plurality of future times; and for each of the plurality of products raising an alert if the current or calculated future temperature exceeds the product temperature range for that product.

A method comprising obtaining a desired storage criterion for each of a plurality of products, the desired storage criteria including at least one condition, the at least one condition including a product temperature range; based on the product temperature range setting for each product at least one alert temperature range; calculating a current temperature of each of the plurality of products located in a compartment at a current time; calculating future temperatures of each of the plurality of products at a plurality of future times based on the current temperatures and expected changes between the current time and the plurality of future times; and for each of the plurality of products raising an alert if the current or calculated future temperature exceeds the product temperature range for that product.

A method including steps of (1) heating, with a heating system, an apparatus comprising an enclosure assembly and a temperature emulation assembly positioned within said enclosure assembly; (2) thermally isolating said temperature emulation assembly from said heating system with said enclosure assembly; (3) permitting conductive heat transfer to said temperature emulation assembly only through an enclosure assembly-leading end of said enclosure assembly; and (4) representing a hottest temperature and a coldest temperature of an article being emulated by said apparatus with said temperature emulation assembly.

An improved thermocouple includes a drawn coaxial thermocouple wire pair having a more precise hot junction at which a first and second metallic material electrically connect with each other for measuring temperature. Adapted for use with an electrophysiologic catheter, the improved thermocouple comprising an elongated body having a proximal end and a distal end. The body includes a core of a first metallic material, a first coaxial layer of ceramic material, and a second coaxial layer of a second metallic material. The thermocouple further includes a solder cap on the distal end, the solder cap electrically connecting the core and the second layer at the distal end. A method of manufacturing includes drawing the body through a die, and applying solder on a distal end of the body to electrically connect the two metallic materials at the distal end.