Piezo resistive Pressure Transmitter

A piezoresistive pressure transmitter is a type of pressure sensor that utilizes the piezoresistive effect to measure pressure changes. This type of pressure transmitter is commonly used in a wide range of industrial applications for accurate and reliable pressure measurement.

Piezo resistive pressure transmitter working:

1. Sensing element: The pressure transmitter contains a sensing element made of a piezo resistive material, such as silicon. The sensing element consists of a diaphragm that deforms under applied pressure.
2. Piezoresistive effect: The piezoresistive material used in the sensing element exhibits a change in its electrical resistance when subjected to mechanical stress or strain. As the diaphragm deforms under pressure, it causes mechanical stress in the piezoresistive material, leading to a change in its resistance.
3. Wheatstone bridge circuit: The piezoresistive sensing element is connected in a Wheatstone bridge configuration, which is an electrical circuit used to measure small changes in resistance. The bridge typically consists of four resistors, including the piezoresistive element. The bridge is initially balanced with no pressure applied, meaning the resistances in the bridge are equal.
4. Pressure-induced resistance change: When pressure is applied, the diaphragm deforms, causing mechanical stress in the piezoresistive material. This stress alters the resistance of the piezoresistive element. The change in resistance creates an imbalance in the Wheatstone bridge circuit.
5. Output signal: The imbalance in the Wheatstone bridge circuit is measured and converted into an electrical output signal. The output signal can be in the form of voltage or current, depending on the design of the transmitter. The magnitude of the output signal is proportional to the applied pressure.
6. Signal conditioning: The output signal from the Wheatstone bridge circuit is typically very small and needs to be amplified and conditioned for further processing. Signal conditioning circuitry is included in the transmitter to amplify, filter, and linearize the output signal. This ensures that the output signal accurately represents the pressure measurement.
7. Calibration: Piezoresistive pressure transmitters often require calibration to ensure accurate pressure measurement. Calibration involves comparing the output signal of the transmitter with known reference pressures and adjusting the output signal accordingly. This process establishes a linear relationship between the applied pressure and the output signal.

Piezo resistive pressure transmitters offer several advantages, including high accuracy, stability, and compatibility with various pressure ranges. They are commonly used in applications such as industrial process control, automotive systems, HVAC systems, medical equipment, and more, where precise pressure measurement is critical.

Following are the common applications :

1. Industrial process control: Piezoresistive pressure transmitters find extensive use in industrial process control applications. They are employed for measuring pressures in pipelines, tanks, reactors, and other process equipment in industries such as oil and gas, chemical processing, pharmaceuticals, food and beverage, and more. Accurate pressure monitoring allows for efficient process control, ensuring safety, and preventing equipment failures.
2. Automotive industry: Piezoresistive pressure transmitters are widely used in the automotive industry. They are employed for measuring pressures in engine cylinders, fuel systems, braking systems, and exhaust systems. Accurate pressure measurement is crucial for optimizing engine performance, monitoring fuel efficiency, ensuring proper braking, and diagnosing engine issues.
3. HVAC systems: Piezoresistive pressure transmitters are used in heating, ventilation, and air conditioning (HVAC) systems. They are employed for measuring pressures in air ducts, pipes, and HVAC equipment. Accurate pressure measurement is essential for maintaining proper airflow, controlling ventilation rates, and ensuring efficient HVAC system operation.
4. Medical equipment: Piezoresistive pressure transmitters are utilized in medical equipment and devices. They are employed in applications such as blood pressure monitors, dialysis machines, respiratory systems, anesthesia equipment, and patient monitoring devices. Accurate pressure measurement is critical for patient care, treatment, and monitoring.
5. Aerospace and aviation: Piezoresistive pressure transmitters are extensively used in the aerospace and aviation industry. They are employed in aircraft and spacecraft systems to measure pressures in hydraulic systems, fuel systems, pneumatic systems, and other critical components. Accurate pressure measurement is vital for safe and efficient operation of aircraft and spacecraft.
6. Energy generation: Piezoresistive pressure transmitters are utilized in power generation plants, including thermal power plants, hydroelectric plants, and renewable energy facilities. They are used for measuring pressures in steam systems, hydraulic systems, and gas pipelines. Accurate pressure measurement is essential for efficient and safe energy generation.
7. Water and wastewater treatment: Piezoresistive pressure transmitters are commonly used in water and wastewater treatment facilities. They are employed for measuring pressures in pipes, pumping stations, filtration systems, and water distribution networks. Accurate pressure monitoring helps ensure proper operation, detect leaks, and optimize treatment processes.
8. Refrigeration and refrigeration systems: Piezoresistive pressure transmitters find application in refrigeration systems for measuring pressures in refrigerant lines and components. They are crucial for monitoring system performance, ensuring proper refrigerant flow, and maintaining optimal cooling efficiency.