MECH 373 Instrumentation and Measurements

Slides:

Advertisements

Similar presentations

EE 4BD4 Lecture 15 Strain ( force) Gauges, pressure sensors and Load Cells 1.

Advertisements

Lecture 4: Signal Conditioning

Summing Amplifier -+-+ RFRF R4R4 + IFIF I4I4 VoVo R3R3 + I3I3 V3V3 V4V4 R2R2 + I2I2 V2V2 R1R1 + I1I1 V1V1 RLRL V id.

Series-Parallel Circuits

Case Study – Application of Sensors in measuring torque and thrust produced by propellers in small unmanned quad-rotor helicopter.

Lecture 31 Electrical Instrumentation. Lecture 32 Electrical Instrumentation Electrical instrumentation is the process of acquiring data about one or.

Lecture161 Instrumentation Prof. Phillips March 14, 2003.

Lecture 371 Norton Equivalent Circuits. Lecture 372 Introduction Any Thevenin equivalent circuit is in turn equivalent to a current source in parallel.

CHAPTER 5 DC AND AC BRIDGES.

electronics fundamentals

SENSORS AND TRANSDUCERS

Strain Gages By Dr. Sotiris Omirou.

Strain Gauges By Ross, James and Peter. What is a Strain Gauge? A strain gauge is a sensor that converts force, pressure, tension, weight etc into electrical.

Differential Transformer

ME 6405 Operational Amplifiers 10/2/12

The Potential Divider Electricity Lesson 10. Learning Objectives To know what a potential divider is. To derive and know how to use the potential divider.

Sensors Introduction Describing Sensor Performance Temperature Sensors

The SEN kg Load Cell And The Wheatstone Bridge.

Lecture 3: Bridge Circuits

Topic 1 different attributes that characterize sensors ETEC 6405.

EKT314/4 Electronic Instrumentation

Chapter 8 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Instrumentation Dr. Xiaofeng Wu 1 1.

With strain gauge sensors, a Wheatstone bridge may not bridge the gap This presentation is partially animated. Only use the control panel at the bottom.

Instrumentation (AMME2700) 1 Instrumentation Dr. Xiaofeng Wu.

Biomedical Electrodes, Sensors, and Transducers

The Wheatstone Bridge Figure 4.10 Using Kirchhoff’s Voltage Law: Using Kirchhoff’s Current Law:

Chapter 6 Series and Parallel Circuits 1 of 81 MECH of 81 Chapter 6 Series and Parallel Circuits MECH1100 Topics Identifying Series- Parallel Relationships.

Lecture 3: Bridge Circuits

Lecture 4: Signal Conditioning

EGR 1011 Chapter 6 Series-Parallel Circuits. EGR 1012 Examples of Series-Parallel Circuits.

Principles of Computer Engineering: Lecture 4: The Wheatstone Bridge

Engineering Science EAB_S_127 Electricity Chapter 3.

Potential Dividers and their application as sensors Electricity Lesson 9.

ELECTRONICS – Input Transducers Engineering Science – National 5.

Voltage Divider Circuits Input transducers Input transducers are devices that convert a change in physical conditions (for example, temperature) into a.

Balances The balance is an instrument which measures the mass of a body or substance using the gravity force which acts on that body At present, there.

Chapter 6 Series-Parallel Circuits. Objectives Identify series-parallel relationships Analyze series-parallel circuits Analyze loaded voltage dividers.

Signal Conditioning Elements (SCE). 6/13/2016Measurement & Transducers2 1. Voltage dividers Example :Potentiometer circuit.

The Wheatstone Bridge Using Kirchhoff’s Voltage Law:

1 Summary Lecture: Part 1 Sensor Readout Electronics and Data Conversion Discovering Sensor Networks: Applications in Structural Health Monitoring.

1 Transducers EKT 451 CHAPTER 6. 2 Definition of a Transducers   Transducer is any device that converts energy in one form to energy in another.  

Electric Pressure Transducer

Pusan National University power PNU 세계로 미래로 Electric Circuits Fall, 2014 Chapter 6 Series-Parallel Circuits.

حسگرها (دريابه)و مبدل ها Sensors & Transducer. حسگر يا مبدل هر دو از اجزاء وسايل اندازه گيری هستند هر دو کميتی فيزيکی را به شکل قابل استفاده ای تبديل.

MECH 373 Instrumentation and Measurements

Topics Identifying Series- Parallel Relationships

TRANSDUCERS PRESENTATION BY: Dr.Mohammed Abdulrazzaq

(3) Signal Conditioning

MECH 373 Instrumentation and Measurements

(2) Bridge Circuits.

MECH 373 Instrumentation and Measurements

MECH 373 Instrumentation and Measurements

MECH 373 Instrumentation and Measurements

Temperature Compensation

Measurement of Pressure

ME 322: Instrumentation Lecture 7

Operational Amplifiers (Op Amps) in Chemical Instrumentation

The resistance of a thermistor changes from 30k to 12k when the temperature changes from 20C to 70 C Calculate the sensitivity if resistance is taken.

Potential Dividers Electric Circuits ☞.

Electric Circuits Fundamentals

WHEAT STONE BRIDGE INSTRUMENTATION AND MEASUREMENTS FMPE-501 PRESENTED BY: SEHR FATIMA 16-ARID-4780.

MECH 373 Instrumentation and Measurements

Series-Parallel Circuits

TOPIC- Load cell A load cell is a transducer that is used to create an electrical signal whose magnitude is directly proportional to the force being.

EC 217 MEASUREMENTS AND INSTRUMENTATION

Presentation transcript:

MECH 373 Instrumentation and Measurements Lecture 18 Measurement of Solid-Mechanical Quantities (Chapter 8) Strain Gauge Signal Conditioning

Strain measurements Measuring gauge resistance before and after loading – Not practical - Significant error– Resistance change in the order of measuring device resolution. Better approach – Device to measure the resistance change rather than resistance, i.e., Wheatstone bridge.

Wheatstone Bridge Four identical resistors. Voltages at points B and D – same – V0 = 0.0, bridge = balance. Active strain gauge R3 , Load R3 – bridge is unbalanced and V0 ≠ 0.0. Adjust R2 – equal to R3, then V0 = 0.0 – bridge is balanced – Amount of adjustment = change of resistance in R3. DAS.

Strain measurements Modern computer DAS – Balance the bridge initially. No need to re-balance it when the active gauge under-strained . Output voltage proportional to change in gauge resistance. (later slides)

Wheatstone bridge

Strain measurements

Strain measurements

Strain measurements

Strain measurements In practice, gauges used are not truly identical. Uncertainty in an order of 0.1%. Vo – nonzero even before the strain applied – Offset – Symmetric error. Adjust the resistor to bring the bridge into initial balance. If not – subtract it from the actual readings.

Strain measurements To improve the sensitivity of circuit for a given small strain. Application – Symmetrical loading situations – Same strain but opposite sign – tension and compression – e.g. sensor – load cells. R1 and R3 – Tensile gauges. R2 and R4 – Compressive gauges. Full bridge = 4 times the quarter bridge.

Temperature compensation

Temperature compensation Affect resistivity, hence gauge factor S = dR/R/εa. Cause differential thermal expansion = structure and gauge, hence strain without mech. load. Minimize the temp effects: Connect R2 and R3 in structure with the same temperature., R3 = Active gauge, R2 = dummy (compensating) gauge – Temp change on both R2 and R3 in same direction, hence no strain. (Note, R2 can be active gauge if strain is equal and opposite to R3.)

Strain gauge in practical set-up

Strain gauge in practical set-up Required many gauges to measure structure strain/stress. Separate bridge for each gauge. Connect output terminals of each bridge to input channels of DAS. Use common power supply. R1 and R4 = Dummy gauges. Each active gauge paired with a fixed gauge R2 (compensating or active). Bridge always complete. Continuous recording or switch to screen for monitoring (critical gauges)

Example – Quarter bridge

Example Full bridge