A dual-use level and temperature probe includes a stem configured to contact liquid, at least one sensor coupled to the stem, and a controller in signal communication with the sensor. The sensor includes an input terminal configured to receive electrical current and an output terminal configured to provide a return path for the electrical current. The controller is configured to deliver the input current to the input terminal and configured to monitor a voltage across the input and output terminals. The controller is configured to perform both a liquid level measurement and a temperature measurement based on the voltage.

Systems and methods for storing fluid and sensing volume are described. In some embodiments, a system may include a container having an internal volume that is configured to change as fluid enters or exits the container, a first loop disposed on a first side of the container, and a second loop disposed on a second side of the container. A first current traveling through one of the first loop and the second loop may induce a second current in the other of the first loop and the second loop, and a magnitude of the second current may vary based on changes in the internal volume of the container.

A rapid rise in the temperature of a liquid level sensor is prevented even at close to a vacuum atmosphere. In a material supply system that is equipped with a tank containing a liquid material and with the liquid level sensor that is provided inside the tank, and in which the liquid level sensor is a self-heating type of sensor that, when the liquid level sensor is generating heat as a result of being supplied with a predetermined normal energy, detects a liquid surface, there are provided a monitoring portion that monitors a detection value from an output signal from the liquid level sensor, and an energy control portion that, when the monitored detection value reaches a predetermined upper limit value, performs control in such a way that the energy supplied to the liquid level sensor is low-level energy that is lower than the normal energy.

A method of installing a probe for monitoring a surface level of a fluid in a vessel inside the vessel from outside the vessel, the method includes providing a vessel side wall with a first opening, providing the vessel side wall with a second opening, passing the second end of the probe, a second device for fastening the probe and a detection unit of the probe through the first opening and inside the vessel, orienting the second end of the probe towards the second opening, attaching the second end of the probe to the side wall of the vessel at the second opening, and fastening the first end of the probe to the side wall of the vessel at the first opening.

A liquid reservoir includes at least one liquid surface level detection unit in the liquid reservoir. The at least one liquid surface level detection unit includes a plurality of liquid surface level detection units. The plurality of liquid surface level detection units each include a plurality of self-heating sensors. The plurality of self-heating sensors are positioned at different heights.

Systems and methods for monitoring temperature distribution in downhole equipment using magnetostrictive probes. In one embodiment, an ESP motor has a stator with a rotor and shaft rotatably positioned within the stator. Magnetostrictive sensors are positioned within the motor. Each magnetostrictive sensor has a transducer, a probe, and electronic circuitry coupled to the transducer. The circuitry generates an initial electrical signal that is conveyed to the transducer. The signal passes through one or more coils in the transducer, generating magnetic fields that induce an acoustic signal in the probe. The acoustic signal propagates through the probe and waves are reflected from reflection points in the probe. The transducer senses the reflected acoustic waves and provides corresponding electrical signals to the circuitry, which determines timing intervals associated with the reflected waves and uses this information to determine temperatures at one or more locations in the probe (hence in the monitored equipment).

Disclosed are a water storage tank and a method for controlling the full water level thereof. The water storage tank according to one embodiment of the present invention comprises: a tank main body for storing water which flows in through a water inlet and discharging water through an outlet; and a control unit for controlling inflow and outflow of water into and from the tank main body, wherein the control unit can change the height of the full water level of the tank main body according to a user's selection or the degree of water discharge from the tank main body.

A thermal mass dispersion flow rate sensing transducer and transducer assembly or instrument for improved functional life of the transducer without degradation in sensing accuracy. Several aspects of the transducer components and structure reduce thermal leakage within the transducer so the sensor (RTD) output signal is accurately transmitted to the signal processor, resulting in precise T determinations and consequent precise determinations of mass flow rate of the fluid flowing in the conduit. Additionally, the same components and structure also have long life without appreciable degradation, thereby delaying any basis for the need for recalibration of the instrument.

A heater system includes an integrated heater device. The integrated heater device includes at least one multiportion resistive element having a first portion defined by a first conductive material and a second portion defined by a second conductive material having a lower temperature coefficient of resistance (TCR) than that of the first conductive material. The second portion is coupled to the first portion so as to extend along an axis, and the at least one multiportion resistive element is operable as a heater to generate heat and as a sensor.

Apparatuses are provided to facilitate sensing fluid within a fluid system, such as a coolant-based cooling apparatus for removing heat generated by one or more electronic components. The apparatus includes a plug configured to couple to a wall of the fluid system at an opening in the wall and to form a fluid-tight seal about the opening. The plug includes a fluid a fluid-sensor-receiving space configured to receive a fluid sensor, and when the plug is coupled to the wall at the opening, to position the fluid sensor at the opening in a manner to facilitate sensing of fluid within the system. The fluid sensor is removable from the plug without requiring uncoupling of the plug from the wall. In one implementation, the fluid sensor is a proximity sensor, and the plug is fabricated of a non-conductive material, and the wall a conductive material.