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11. REFERENCES
[1] AK SAWHNEY A Course In Electronics & Electrical Measurements And Instrumentation.pdf
[2] Electronic Instrumentation And Measurements by Cooper.pdf
[3] https://www.slideshare.net
[4] https://www.electronics-tutorials.ws/io/io_1.html
[5] https://en.wikibooks.org
[6] https://en.wikipedia.org](https://image.slidesharecdn.com/designoftransducertomeasurecomparativerotationin3dusinglvdt-210510132559/85/Design-of-transducer-to-measure-comparative-rotation-in-3-d-using-lvdt-10-320.jpg)
Design of transducer to measure comparative rotation in 3 d using lvdt
- 1. Electronics National Measurements UNDER THE GUIDANCE OF DR. CHANDRAJIT CHOUDHURY DEPT OF ELECTRONICS AND COMMUNICATION NIT SILCHAR 1 Department of Electronics and Communication Engineering ational Institute of Technology 2020 Measurements and Instrumentation Mini Project Submitted By: Group – 28 RanSher (1814110) HOUDHURY SIR COMMUNICATION ENGINEERING, Engineering Technology, Silchar Instrumentation
- 2. 2 Design of Transducer to measure comparative rotation in 3D using LVDT Ran Sher Department of Electronics and Communiction Engineering National Institute of Technology, Silchar ABSTRACT Transducers are excellent devices in converting the one form of energy to another. LVDTs are one of the famous transducer and well known for their ability to measure the linear displacement with high accuracy and precision. In this project we have designed a transducer device with the help of group of LVDTs to measure the comparative rotation in three dimensions. Three LVDTs situated on three perpendicular axes can measure the displacements produced by each, when rotated in specific direction. These displacements produced in each of the LVDT can be used to calculate the angle of rotation from any of the axes. TABLE OF CONTENTS Introduction…………………………………….2 Transducers……………………………….…....3 LVDTs……………………………..…………..3 Applications of LVDTs…..………………..….4 Design of Transducer……..………………..…. 5 Working of Transducer…………………….......5 Solutions for challenges in implementation……8 Results and discussion…………………………9 Conclusions…………………………………….9 Acknowledgement……………………………..9 References……………………………………...9 1. INTRODUCTION A transducer is an electronic device that converts energy from one form to another. Common examples include microphones, loudspeakers, thermometers, position and pressure sensors, and antenna. LVDT is a class of transducer, which works principle of mutual induction and can measure the linear displacement by determining difference in voltages. 3 LVDTs can be to design a transducer which can measure comparative rotation in 3D, by binding it to 3 perpendicular axes x, y and z with its centres kept at near origin. Rotating the designed transducer to some angles causes displacement in core of LVDTs, hence these displacements measured can be utilised to determine
- 3. 3 the angle of rotation about any axes using cosine formula discussed earlier. There are many challenges in physical implementations which can be solved by using suitable conditions and favourable precautions. 2. TRANSDUCERS Transducers are the electronic devices which can convert one form of energy to another. This ability of transducers can be utilized in measurements and instrumentation purposes in better manner. The word “Transducer” is the collective term used for both Sensors which can be used to sense a wide range of different energy forms such as movement, electrical signals, radiant energy, thermal or magnetic energy etc, and Actuators which can be used to switch voltages or currents. There are many different types of sensors and transducers, both analogue and digital and input and output available to choose from. The type of input or output transducer being used, really depends upon the type of signal or process being “Sensed” or “Controlled” but we can define a sensor and transducers as devices that converts one physical quantity into another. Devices which perform an “Input” function are commonly called Sensors because they “sense” a physical change in some characteristic that changes in response to some excitation, for example heat or force and covert that into an electrical signal. Devices which perform an “Output” function are generally called Actuators and are used to control some external device, for example movement or sound. Transducers can be classified as: On the basis of transduction form used. As primary and secondary transducers. As passive and active transducers. As analog and digital transducers 3. LVDTs The linear variable differential transformer (LVDT) is a type of electrical transformer used for measuring displacement. Working Principle: LVDT works under the principle of mutual induction, and the displacement which is an on electrical energy is converted into an electrical energy. And the way how the energy is getting converted is described in working of LVDT in a detailed manner. It consists of a cylindrical former where it is surrounded by one primary winding in the centre of the former and the two secondary windings at the sides. The number of turns in both the secondary windings are equal, but they are opposite to each other, i.e., if the left secondary windings is in the clockwise direction, the right secondary windings will be in the anti-clockwise direction, hence the net output voltages will be the difference in voltages between the two secondary coil.
- 4. 4 Case 1: On applying an external force which is the displacement, if the core reminds in the null position itself without providing any movement then the voltage induced in both the secondary windings are equal which results in net output is equal to zero. Case 2: Due to external force if the steel iron core moves in the right hand side direction then the voltage induced in the secondary coil 2 is greater when compared to the voltage induced in the secondary coil 1. Case 3: Due to external force if the steel iron core moves in the left hand side direction then the voltage induced in the secondary coil 1 is greater when compared to the emf voltage induced in the secondary coil 2. Advantages and Disadvantages of LVDTs Advantages of LVDT LVDT has High Range. LVDT is a frictionless device. LVDT has low hysteresis. Disadvantages of LVDT Sensitive to a stray magnetic field. Performance is affected by vibrations. Temperature affects the performance. 4. APPLICATIONS OF LVDTs In applications where both accuracy and reliability are key; an LVDT is well suited and recommended. Some benefits to choosing LVDTs are: Friction Free – they are non-contacting and therefore friction free meaning they offer long life. Fast Response – the fast response time of the LVDT means that time can be managed effectively during use. Robust – being robust means that LVDTs can be used in extreme applications and environments. Versatile – different configurations are available to suit different applications. Contact Ixthus to find the right LVDT for your application. Used in applications where displacements ranging from fraction of mm to few cm are to be measured. Acts as the secondary transducers. Power turbines Hydraulics Aircrafts Satellites Nuclear reactors Factory automation Servo mechanisms
- 5. 5 Weight sensitive applications General industrial applications Process and control 5. DESIGN OF TRANSDUCER Three similar LVDT, numbered with LVDT1, LVDT2 and LVDT3 are kept at x-axis, y-axis and z- axis respectively. They are attached in such a way that middle portion of each LVDT lies at the origin ideally. LVDTs can freely rotate in any direction about origin. Initially, LVDT 3, which lies on z-axis has maximum displacement of core (let say L) and LVDT 1 and LVDT 2 has zero displacement of core. Any rotation about origin will tend to decrease the value of L (displacement of core of LVDT 3) and tend to increase the value of core displacement of LVDT 1 and LVDT 2. 6. WORKING OF TRANSDUCER According to principle of LVDT, when core of LVDT is displaced from the centre machanically, the voltage difference of two secondary coils becomes non-zero and hence displaced position of core can be measured easily. Weight of the core is responsible for its displacement from the centre. When LVDT is vertical, it has maximum core displacement whereas when it is horizontal, it has minimum displacement. Let’s displacement along x-axis, y-axis and z-axis is denoted by 𝑑 , 𝑑 and 𝑑 . State 1: LVDT 3(z-axis) is fixed and LVDT1(x-axis) and LVDT 2(y-axis) is rotated x-y plane.
- 6. 6 Here, 𝑑 = 0 𝑑 = 0 , 𝑑 = L (let) Therefore, if 𝛼 is the angle with x, Then, cos 𝛼 = , i.e., 𝛼 = 90 State 2: LVDT 2 (y-axiz) is fixed Motion in x-z plane OR LVDT 1 (x-axis) is fixed, Motion in y-z plane. Due to rotation in x-z plane, there will be increase in 𝑑 and decrease 𝑑 while 𝑑 remains constant. 𝑑 = L’ (let) 𝑑 = 0 𝑑 = L – L’ {since increase displacement of LVDT 1 will be same as decrease in LVDT 3 }
- 7. 7 cos 𝛼 = = ( ) hence, 𝛼 = cos−1( ( ) ) State 3: All LVDTs are rotated by angle 𝛼 . Let say L’ is increase in displacement of LVDT1 and LVDT2 and it is known that there is same decrease in LVDT 3, hence 𝑑 = L’ (let) 𝑑 = L’ 𝑑 = L – L’ {since increase displacement of LVDT 1 will be same as decrease in LVDT 3 } cos 𝛼 = = = ( ) hence, 𝛼 = cos−1( ( ) ) State 4: LVDT 1 , LVDT 2 and LVDT 3 are rotated by angle α, β and γ respectively from x, y ,z axes .
- 8. 8 Let say Lx’ and Ly’ are increase in displacement of LVDT1 and LVDT2 and Lz’ is decrease in LVDT 3, hence 𝑑 = Lx’ (let) 𝑑 = Ly’ 𝑑 = L – Lz’ {since increase displacement of LVDT 1 will be same as decrease in LVDT 3 } cos 𝛼 = = ( ) hence, 𝛼 =cos−1( ( ) ) Similarly β = cos−1( ( ) ) and γ = cos−1( ( ) ) Next Step Three dampers is added at the centre of the designed LVDT ,in such a way that when LVDT at any time starts moving away from the central point in uncontrolled acceleration, then damper comes into effect to start damping force to stop or to oppose the LVDT in opposite direction of its motion.
- 9. 9 7. SOLUTIONS FOR CHALLENGES IN IMPLEMENTATION Centres of all three LVDTs should lie on origin initially, which is not possible in real senario. Solution: Although it is not possible, but it can be achieved to near ideal value by reducing the thickness of LVDTs to minimum value. During rotation, centrifugal force comes into effect which causes vary in actual displacement in cores of LVDTs. Solution: Measurement readings should be taken during equilibrium condition, which can reduce this error. Accuracy can be hampered by Temperature and Hysteresis. Solution: Temperature must be kept constant by cooling and soft iron core can be used for reduction in losses due to hysteresis. 8. RESULT AND DISCUSSION A transducer designed with the help of LVDTs is found to be theoretically satisfactory and working according to the principles of LVDT. The linear displacement produced by the LVDTs was used to calculate the angle of rotation using the cosine formula which is given as cos 𝛼 = where 𝛼 is the angle of rotation Various challenges are there in the practical implementation of the device is discussed earlier and it was found that device can work efficiently. 9. CONCLUSIONS After studying transducers and their properties in view of LVDTs, we can conclude that LVDTs are excellent devices to measure the linear displacement and these linear displacements can be used to measure the angular rotation in three dimensions. The design of above transducer can have some practical challenges which can be solved by following some ideal situations 10. ACKNOWLEDGEMENT The author is thankful to Dr. Chandrajit Choudhury, Assistant Professor, National Institute of Technology Silchar for his guide, advise and motivation throughout the completion of this report. Author would also like to express his gratitude to his college, National Institute of Technology, Silchar for providing him with such a strong platform and enabling him to harness his talents. Lastly, he would like to express his appreciation to his parents for providing him moral support and encouragement.
- 10. 10 11. REFERENCES [1] AK SAWHNEY A Course In Electronics & Electrical Measurements And Instrumentation.pdf [2] Electronic Instrumentation And Measurements by Cooper.pdf [3] https://www.slideshare.net [4] https://www.electronics-tutorials.ws/io/io_1.html [5] https://en.wikibooks.org [6] https://en.wikipedia.org