A liquid consumption monitoring device for monitoring and encouraging consumption of a liquid includes a cup and a lid, which is selectively engageable to the cup to close a top thereof. The user is positioned to tilt the cup to dispense a liquid from the cup, through an opening positioned in the lid, into a mouth of the user. A flow meter engaged to the cup, proximate to the opening, measures a volume of the liquid passing through the opening. An interface is engaged to at least one of the cup and the lid and is operationally engaged to the flow meter. The interface receives a signal from the flow meter when the liquid passes through the opening. The interface selectively actuates at least one of a speaker and a bulb, upon receipt of the signal from the flow meter, to provide a sensory reward to the user.

Systems and methods for determining a weight of a quantity of fluid, or a flow rate of the fluid by weight. An acoustic sensor positioned on an exterior wall of a vessel containing the fluid determines a fill level of the fluid. A computerized device calculates a weight of the quantity of fluid using a size of the vessel, the determined fill level, a temperature of the fluid, and the fluid identity and/or a fluid density. Flow rate of the fluid through a pipe is determined using two or more acoustic sensors positioned at different locations on a pipe, and a temperature sensor. A computer calculates a differential time of flight of the fluid based on readings of the acoustic sensor, a distance therebetween, the temperature sensor, the pipe volume, and the fluid identity and/or a fluid density. A flow by weight of the quantity of fluid is determined.

A method of measuring airflow from an HVAC outlet vent using a volume fill airflow measurement device having a LIDAR or Time-of-Flight (ToF) laser-ranging sensor to detect a filled state of a volume capture element or bag, comprising placing a frame having the bag sealably attached thereto over the vent to be measured, starting a timer, stopping the timer automatically in response to the LIDAR or Time-of-Flight (ToF) laser-ranging sensor measuring the distance to be within a predetermined range, and calculating the measured airflow based on the volume of the bag and the time for the airflow to fill the bag. The measured airflow is then displayed on the device display.

One or more techniques and/or systems are disclosed for accurately determining the volume of liquid in a container, such as after or prior to a fluid transfer into/from the container. The volume of liquid flowing through a flow meter can be measured at multiple data intervals by a flow meter. Further, the height of a liquid inside the container can be measured by a liquid level sensor at the multiple data intervals. A register can receive data indicative of the respective measurements, and the volume of liquid in the container can be determined based on the relationship between data indicative of the measurement of the volume of liquid flowing through a flow meter at the multiple data intervals and the measurement of the height of a liquid inside the container at the multiple data intervals.

An automated urine-output-measurement system can include single-patient equipment and multi-patient equipment. The single-patient equipment can include a urinary catheter and a urine-collection system. The urine-collection system can include drainage tubing and a drainage receptacle. The multi-patient equipment can include a urine monitor. The urine monitor can include a housing having a cavity configured to house the drainage receptacle, a urine-measurement means for measuring urine-output into the drainage receptacle, and an integrated display screen configured to display patient information including measurements of the urine output. A method of the automated urine-output-measurement system can include placing the drainage receptacle in the urine monitor of the automated urine-output-measurement system, and confirming a volume of urine in the drainage receptacle with that indicated on the urine monitor once a patient has produced urine.

Systems for monitoring fluidics in reagent cartridges and related methods. An apparatus includes a system includes a reagent cartridge receptacle and a flow cell assembly. The apparatus includes a reagent cartridge receivable within the reagent cartridge receptacle and adapted to carry the flow cell assembly. The reagent cartridge includes a reagent reservoir fluidically coupled to the flow cell assembly. The apparatus includes a sensor module adapted to be positioned adjacent the reagent reservoir. The sensor module is adapted to generate a signal associated with a volume of reagent contained within the reagent reservoir.

Systems for analyzing and monitoring deionization tank system performance in a fluid flow system and generating delivery schedules for servicing deionization tanks can include a conductivity sensor and a fluid flow meter. Data regarding the amount and conductivity of fluid flowing through the deionization tank system can be used to predict a remaining capacity of the deionization tank system. A central server can determine the remaining capacity of deionization tank systems at a plurality of service locations. The central server can generate a delivery schedule for servicing deionization tank systems at each of the plurality of service locations based on the determined remaining capacities. Other parameters can be used to optimize efficiency of the delivery schedule while meeting the needs of each of the service locations.

Systems and methods for monitoring complex transactions, such as international physical oil and petroleum trading and shipping transactions are disclosed. The disclosed systems include equipment installed on a vessel, such as a tanker, configured to monitor the quality and quantity of oil loaded onto and discharged from the vessel. The system also includes a remote data center configured to receive the cargo information from the vessel-board equipment. The remote data center is also configured to securely maintain information and documents generated during the transaction, such as financial documents, quality and quantity reports, bills of lading, and the like. The system provides a portal whereby stakeholders in the transaction can monitor all aspects of the transaction.

Systems and methods for determining a weight of a quantity of fluid, or a flow rate of the fluid by weight. An acoustic sensor positioned on an exterior wall of a vessel containing the fluid determines a fill level of the fluid. A computerized device calculates a weight of the quantity of fluid using a size of the vessel, the determined fill level, a temperature of the fluid, and the fluid identity and/or a fluid density. Flow rate of the fluid through a pipe is determined using two or more acoustic sensors positioned at different locations on a pipe, and a temperature sensor. A computer calculates a differential time of flight of the fluid based on readings of the acoustic sensor, a distance therebetween, the temperature sensor, the pipe volume, and the fluid identity and/or a fluid density. A flow by weight of the quantity of fluid is determined.

Systems and methods for determining a weight of a quantity of fluid, or a flow rate of the fluid by weight. An acoustic sensor positioned on an exterior wall of a vessel containing the fluid determines a fill level of the fluid. A computerized device calculates a weight of the quantity of fluid using a size of the vessel, the determined fill level, a temperature of the fluid, and the fluid identity and/or a fluid density. Flow rate of the fluid through a pipe is determined using two or more acoustic sensors positioned at different locations on a pipe, and a temperature sensor. A computer calculates a differential time of flight of the fluid based on readings of the acoustic sensor, a distance therebetween, the temperature sensor, the pipe volume, and the fluid identity and/or a fluid density. A flow by weight of the quantity of fluid is determined.