Flusso's flow sensors excel in oxygen concentrators, delivering unmatched precision, rapid response, durability, compactness, and a dependable supply chain.

For optimal mechanical ventilation efficiency, accurate airflow meeting building needs is vital. Flusso sensors offer closed-loop fan control, countering overventilation's downsides.

VAV systems optimize HVAC in buildings with real-time airflow control. Flusso sensors can help enhance system performance, energy efficiency & user experience.

Efficient cordless vacuums are sought after. Flusso's flow sensors enable real-time suction adjustment, filter clogging detection and longer battery life, optimizing performance.

The integration of flow sensing technology in these systems offers numerous benefits, ranging from optimizing patient outcomes to enhancing device performance and safety.

Pneumatic systems are pricey. US DOE: 10-30% of US manufacturing energy costs. Electricity makes 80% of total cost. Priority: leak detection, pressure optimization.

Effective control of gas flow in ventilators is vital for optimizing patient care and for preventing respiratory complications, such as hypoxia and lung injury.

HVAC testing challenges: heavy tools, tight access, complex measurements. Solutions: portable, multifunctional instruments, accurate, longer battery life.

Flow sensor in indoor air quality (iAQ) offers enhanced monitoring, precise airflow data, efficient ventilation management, and early detection of anomalies.

Flow sensing was challenging in tiny battery-powered health devices. FLS110 fits inhalers, consumes <5 mA active, <1 μA idle. Calibration ensures <5% accuracy.

Sensirion's SFC5500 mass flow controller allows for easy exchange of gas connectors.

Amphenol's Telaire offers both single and dual wavelength CO2 sensing technologies.

Utility meters, motor commutation, and distance measurement are among a range of applications which require a measurement of rotation speed and/or direction of rotation.

The RedRock® TMR magnetic sensor is a three-terminal magnetic sensor, but with the simple resistor arrangement a 3-to-2 wire conversion circuitry is achieved.

When switching from passive sensors to active sensors such as the RedRock TMR sensors, a common concern is battery life in battery-powered applications.

Modernizing security systems with tmr for higher reliability, wider sensing range, and long battery life.

Options and Considerations to Extend Battery Life

By understanding where the sensor and magnet need to operate, and determining which specs make the ideal combination, one can achieve additional benefits.

Within an embedded system, a magnetic sensor’s role is to detect the presence and/or motion of a magnetic object and signal the microprocessor to execute a desired action.

Three types of magnetic sensors commonly used in such IoT devices are TMR sensors, bare reed switches and Hall sensors. Device designers should understand their options when making a determination of which magnetic sensor to choose for their designs.