The document discusses various topics related to metrology. It begins by defining metrology as the science of measurement and dividing it into two main types - industrial metrology and medical metrology. Some key points covered include the importance of length and time measurements, analyzing measurement errors, gauges design and manufacturing, and industrial inspection. It also discusses types of metrology like scientific, industrial, legal and fundamental metrology. Specific measuring instruments like vernier calipers, micrometers, and slip gauges are explained in detail. The document concludes by covering various other metrology topics such as measurement principles, linear measuring instruments, and applications of limit gauges.
Mechanical Engineering Technical Interview Q & A Metrology and precision inst...Er. Bade Bhausaheb
This document discusses various metrology and precision instruments used for measurement and inspection. It provides definitions and explanations of nominal size, actual size, basic size, fits, limits, tolerance, allowance and describes instruments like vernier calipers, micrometers, gauges, sine bars and templates. Key points covered are the working principles and uses of these instruments as well as concepts like interchangeability, selective and non-selective assembly, lapping and honing processes.
The document discusses various linear and angular measurement instruments. It describes different types of linear measurement devices including vernier calipers, micrometers, gauge blocks, and comparators. It also covers angular measurement tools such as bevel protractors, universal bevel protectors, clinometers, and angle gauges. The document provides details on the components, use, and reading of key linear and angular measuring instruments.
This document discusses various linear and angular measurement instruments. It describes scales, calipers, vernier calipers, micrometers, slip gauges, sine bars, bevel protractors, and auto-collimators. Linear measuring instruments are classified as direct or indirect and graduated or non-graduated. Precision is increased with vernier scales and indicators that allow for smaller unit measurements. Angular instruments like protractors and auto-collimators use optical principles to measure small angles. Accessories aid in applications like marking dimensions. Sources of error are also discussed to ensure accuracy.
These may be used as reference standards for transferring the dimension of the unit of length from the primary standard to gauge blocks of lower accuracy and for the verification and graduation of measuring apparatus. These are high carbon steel hardened, ground and lapped rectangular blocks, having cross sectional area 0f 30 mm
10mm. Their opposite faces are flat, parallel and are accurately the stated distance apart. The opposite faces are of such a high degree of surface finish, that when the blocks are pressed together with a slight twist by hand, they will wring together. They will remain firmly attached to each other. They are supplied in sets of 112 pieces down to 32 pieces. Due to properties of slip gauges, they are built up by, wringing into combination which gives size, varying by steps of 0.01 mm and the overall accuracy is of the order of 0.00025mm. Slip gauges with three basic forms are commonly found, these are rectangular, square with center hole, and square without center hole.
For a metric thread of 60° included angle:
Best wire diameter = 0.5774 * Pitch
= 0.5774 * 2.5 = 1.4435 mm
Rounded off to the nearest standard wire size, the best wire size is 1.5 mm.
The document discusses various methods for measuring lines, surfaces, and geometries. It describes common measurement tools like vernier calipers, micrometers, bore gauges, dial indicators, and slip gauges. It also covers methods for measuring threads, angles, and surface roughness. Key aspects include using a vernier scale to improve measurement resolution, using wire methods to measure thread pitch diameters, and parameters like roughness height and width to characterize surface texture.
The document discusses vernier calipers and micrometers. It describes the basic components and workings of each tool. Vernier calipers use a main scale and vernier scale to take more precise measurements than a simple caliper. A micrometer uses a precisely threaded screw that moves the spindle 0.5 mm with each full revolution. The least count of a micrometer, which is the smallest measurement it can make, depends on the screw pitch and number of divisions on the circular scale. Key parts of a micrometer include the frame, anvil, spindle, sleeve, screw, thimble, ratchet, and various scales.
UNIT II MEASUREMENT OF LINEAR, ANGULAR DIMENSIONS, ASSEMBLY AND TRANSMISSION ...prakashPrAkAsH143
This document provides information on various measurement instruments and gauges used for linear, angular, and dimensional measurements. It discusses different types of measuring instruments like vernier calipers, micrometers, slip gauges, comparators, as well as angular measuring instruments. It also covers limit gauges and their use in checking workpiece tolerances, and concepts of interchangeability and selective assembly in manufacturing.
Mechanical Engineering Technical Interview Q & A Metrology and precision inst...Er. Bade Bhausaheb
This document discusses various metrology and precision instruments used for measurement and inspection. It provides definitions and explanations of nominal size, actual size, basic size, fits, limits, tolerance, allowance and describes instruments like vernier calipers, micrometers, gauges, sine bars and templates. Key points covered are the working principles and uses of these instruments as well as concepts like interchangeability, selective and non-selective assembly, lapping and honing processes.
The document discusses various linear and angular measurement instruments. It describes different types of linear measurement devices including vernier calipers, micrometers, gauge blocks, and comparators. It also covers angular measurement tools such as bevel protractors, universal bevel protectors, clinometers, and angle gauges. The document provides details on the components, use, and reading of key linear and angular measuring instruments.
This document discusses various linear and angular measurement instruments. It describes scales, calipers, vernier calipers, micrometers, slip gauges, sine bars, bevel protractors, and auto-collimators. Linear measuring instruments are classified as direct or indirect and graduated or non-graduated. Precision is increased with vernier scales and indicators that allow for smaller unit measurements. Angular instruments like protractors and auto-collimators use optical principles to measure small angles. Accessories aid in applications like marking dimensions. Sources of error are also discussed to ensure accuracy.
These may be used as reference standards for transferring the dimension of the unit of length from the primary standard to gauge blocks of lower accuracy and for the verification and graduation of measuring apparatus. These are high carbon steel hardened, ground and lapped rectangular blocks, having cross sectional area 0f 30 mm
10mm. Their opposite faces are flat, parallel and are accurately the stated distance apart. The opposite faces are of such a high degree of surface finish, that when the blocks are pressed together with a slight twist by hand, they will wring together. They will remain firmly attached to each other. They are supplied in sets of 112 pieces down to 32 pieces. Due to properties of slip gauges, they are built up by, wringing into combination which gives size, varying by steps of 0.01 mm and the overall accuracy is of the order of 0.00025mm. Slip gauges with three basic forms are commonly found, these are rectangular, square with center hole, and square without center hole.
For a metric thread of 60° included angle:
Best wire diameter = 0.5774 * Pitch
= 0.5774 * 2.5 = 1.4435 mm
Rounded off to the nearest standard wire size, the best wire size is 1.5 mm.
The document discusses various methods for measuring lines, surfaces, and geometries. It describes common measurement tools like vernier calipers, micrometers, bore gauges, dial indicators, and slip gauges. It also covers methods for measuring threads, angles, and surface roughness. Key aspects include using a vernier scale to improve measurement resolution, using wire methods to measure thread pitch diameters, and parameters like roughness height and width to characterize surface texture.
The document discusses vernier calipers and micrometers. It describes the basic components and workings of each tool. Vernier calipers use a main scale and vernier scale to take more precise measurements than a simple caliper. A micrometer uses a precisely threaded screw that moves the spindle 0.5 mm with each full revolution. The least count of a micrometer, which is the smallest measurement it can make, depends on the screw pitch and number of divisions on the circular scale. Key parts of a micrometer include the frame, anvil, spindle, sleeve, screw, thimble, ratchet, and various scales.
UNIT II MEASUREMENT OF LINEAR, ANGULAR DIMENSIONS, ASSEMBLY AND TRANSMISSION ...prakashPrAkAsH143
This document provides information on various measurement instruments and gauges used for linear, angular, and dimensional measurements. It discusses different types of measuring instruments like vernier calipers, micrometers, slip gauges, comparators, as well as angular measuring instruments. It also covers limit gauges and their use in checking workpiece tolerances, and concepts of interchangeability and selective assembly in manufacturing.
The document discusses linear and angular measurement instruments. It describes various instruments used for linear measurement such as vernier calipers, micrometers, slip gauges, interferometers, and comparators. It also discusses angular measurement instruments like sine bars and protractors. The key types of comparators are listed as mechanical, pneumatic, electrical, and optical comparators. Measurement systems are used for quality control and common measurements include linear dimensions, angles, and tapers.
This document provides instructions for experiments to be conducted in a metrology lab. It includes 10 experiments involving calibration of measurement tools like micrometers and dial gauges using slip gauges, measurement of angles using a bevel protractor and sine bar, measurement of gear features, surface roughness, and more. The document was prepared by B.Sudarshan, Assistant Professor of Mechanical Engineering, for students to record their experiment details, objectives, theories, procedures, observations and results.
Linear and angular measurements are fundamental concepts in metrology. There are several precision tools used for linear measurements, including rulers, vernier calipers, and micrometers. Vernier calipers use a vernier scale to measure lengths with an accuracy of 0.02mm or better. Micrometers can measure with an accuracy of 0.01mm or better using a screw mechanism. Other important linear measuring tools discussed include slip gauges, height gauges, and depth gauges. Angular measurements are also important and were historically used for navigation.
The document discusses various measurement and inspection tools used in manufacturing including vernier calipers, micrometers, dial indicators, surface plates, and various types of gauges. It defines nominal size, actual size, basic size, fits, limits, tolerance, and allowance. It also discusses features such as least count, zero error, backlash, and uses of tools like vernier height gauges, depth gauges, and bevel protractors. Reasons for potential false readings are outlined for various tools.
The document provides an overview of basic metrology practices and measuring instruments. It discusses principles of measurement using metric and imperial systems. It then describes various measuring tools including rules, calipers, gauges, micrometers, vernier calipers, and height gauges. For each tool, it explains how to use and read the tool, with pictures to illustrate parts and scales. The document aims to teach proper use and reading of common measurement devices.
This document discusses and defines various mechanical engineering measuring instruments and gauges. It begins by distinguishing measuring instruments, which can measure dimensions adjustable to 0.001mm, from gauges, which have fixed dimensions. It then provides descriptions and uses for 14 specific measuring instruments, including vernier calipers, height gauges, depth gauges, ring gauges, plug gauges, and micrometers. It concludes by defining tolerance as the difference between upper and lower dimension limits, and upper and lower deviations.
The document describes calibrating a dial gauge using a calibration tester and computerized calibrator. It provides background on dial gauges and their applications. The experimental procedure for manual and computerized calibration is described. Test results are shown in a table with go, return, limit, and average readings recorded at 0.1mm increments from 0-1.5mm. The data will be analyzed to determine errors at each reading point and compare the accuracy of the two calibration methods.
This document discusses various linear measurement instruments used in engineering. It begins by classifying linear measurement devices into low, medium, and high resolution. Low resolution devices include graduated rules and calipers. Medium resolution devices discussed are vernier calipers, micrometers, and dial gauges. High resolution devices able to measure to within microns include slip gauges and comparators. The document provides detailed descriptions and examples of how each of these tools is used to perform precise linear measurements.
This document provides an overview of metrology and measurements. It discusses key concepts in metrology including calibration, traceability, uncertainty, and accreditation. It defines metrology as the science of measurement and explains its importance. Metrology covers defining measurement units, establishing measurement standards, and documenting measurement accuracy. There are different categories of metrology including scientific, industrial, and legal metrology. The document also discusses various measurement tools and gauges used in industrial metrology.
This document discusses various measuring devices used for linear and angular measurements. It describes dimensions that are commonly measured and how measuring instruments are classified based on their resolution. Low, medium, and high resolution devices are explained. Specific linear measuring instruments like vernier calipers, micrometers, slip gauges, and comparators are also discussed. Comparators are mechanical, electrical or pneumatic devices used to compare unknown measurements to a known standard.
Unit 3 Lecture 1-2 Linear and Angular Measurement.pptxKhalil Alhatab
The document discusses various linear and angular measurement instruments. It begins by defining metrology and dimensional metrology. It then describes different types of linear measurement instruments including rules, calipers, micrometers, depth gauges, height gauges, and Vernier instruments. It discusses the design considerations and operating principles of these instruments. The document also covers angular measurement instruments and non-graduated gauges used for special purposes. In summary, the document provides an overview of common linear and angular measurement tools and their applications in dimensional metrology.
This document provides information about linear and angular measurement devices. It discusses various tools used for linear measurement such as vernier calipers, micrometers, slip gauges, comparators and tools for angular measurement including protractors, spirit levels, clinometers and sine bars. It also explains the working principles, applications and sources of error for some of these measurement devices.
The document provides instructions for calibrating precision measuring instruments and measuring lengths, diameters, and heights using vernier calipers, micrometers, and a vernier height gauge. Key steps include calibrating the instruments using slip gauges with known dimensions on a surface plate, then taking measurements of objects and recording the readings from the instruments along with any errors compared to the actual dimensions. Instruments are calibrated to determine their accuracy and establish a baseline before taking measurements.
Unit 3 Lecture 1-2 Linear and Angular Measurement.pdfKhalil Alhatab
The document discusses various linear and angular measurement instruments. It begins by defining metrology and dimensional metrology. It then describes different types of linear measurement instruments including rulers, calipers, micrometers, gauges and vernier calipers. For angular measurements, instruments discussed include protractors and sine bars. The document also covers topics like design considerations for measurement instruments and guidelines for using various tools.
The document discusses different types of vernier micrometers used for various measuring applications. It describes depth micrometers which measure depth, inside micrometers which measure inside diameters and surfaces, and tubular inside micrometers which are useful for internal cylindrical measurements. It also discusses micrometer parts like the ratchet, lock nut, and changeable anvils. Methods for measuring thread diameters and pitches using special thread micrometers are provided. Recent micrometer designs include indicating, direct reading, dual reading, and all-electronic models.
This document provides an overview of mechanical measurements and metrology. It discusses key concepts like accuracy, precision, types of errors in measurement, calibration, standards, and classification of measuring instruments. The objectives of metrology are outlined as ensuring measuring instruments are adequate and maintained through calibration. Factors affecting measurement accuracy are explored including the standard, workpiece, instrument, operator, and environment. Common methods of measurement and classification of instruments are also summarized.
The document describes laboratory experiments for testing the strength of materials and fluid mechanics. It includes 13 experiments such as Rockwell hardness testing, Brinell hardness testing, Izod impact testing, Charpy impact testing, torsion testing, deflection testing, and heat treatment processes. Details are provided on the procedure, theory, apparatus, and formulas for calculating results for Rockwell hardness testing, Brinell hardness testing, Izod impact testing and Charpy impact testing. The aim is to determine the hardness and impact strength of various metal specimens.
This document provides an overview of shaper, milling, and gear cutting machines. It discusses the main components and operations of shaper machines, including the shaper mechanism and work holding devices. It also covers drilling machines, boring operations, and different types of milling machines. Finally, it summarizes gear cutting and generation processes, including gear shaping, planning, and hobbing, as well as methods for finishing gears.
The document discusses linear and angular measurement instruments. It describes various instruments used for linear measurement such as vernier calipers, micrometers, slip gauges, interferometers, and comparators. It also discusses angular measurement instruments like sine bars and protractors. The key types of comparators are listed as mechanical, pneumatic, electrical, and optical comparators. Measurement systems are used for quality control and common measurements include linear dimensions, angles, and tapers.
This document provides instructions for experiments to be conducted in a metrology lab. It includes 10 experiments involving calibration of measurement tools like micrometers and dial gauges using slip gauges, measurement of angles using a bevel protractor and sine bar, measurement of gear features, surface roughness, and more. The document was prepared by B.Sudarshan, Assistant Professor of Mechanical Engineering, for students to record their experiment details, objectives, theories, procedures, observations and results.
Linear and angular measurements are fundamental concepts in metrology. There are several precision tools used for linear measurements, including rulers, vernier calipers, and micrometers. Vernier calipers use a vernier scale to measure lengths with an accuracy of 0.02mm or better. Micrometers can measure with an accuracy of 0.01mm or better using a screw mechanism. Other important linear measuring tools discussed include slip gauges, height gauges, and depth gauges. Angular measurements are also important and were historically used for navigation.
The document discusses various measurement and inspection tools used in manufacturing including vernier calipers, micrometers, dial indicators, surface plates, and various types of gauges. It defines nominal size, actual size, basic size, fits, limits, tolerance, and allowance. It also discusses features such as least count, zero error, backlash, and uses of tools like vernier height gauges, depth gauges, and bevel protractors. Reasons for potential false readings are outlined for various tools.
The document provides an overview of basic metrology practices and measuring instruments. It discusses principles of measurement using metric and imperial systems. It then describes various measuring tools including rules, calipers, gauges, micrometers, vernier calipers, and height gauges. For each tool, it explains how to use and read the tool, with pictures to illustrate parts and scales. The document aims to teach proper use and reading of common measurement devices.
This document discusses and defines various mechanical engineering measuring instruments and gauges. It begins by distinguishing measuring instruments, which can measure dimensions adjustable to 0.001mm, from gauges, which have fixed dimensions. It then provides descriptions and uses for 14 specific measuring instruments, including vernier calipers, height gauges, depth gauges, ring gauges, plug gauges, and micrometers. It concludes by defining tolerance as the difference between upper and lower dimension limits, and upper and lower deviations.
The document describes calibrating a dial gauge using a calibration tester and computerized calibrator. It provides background on dial gauges and their applications. The experimental procedure for manual and computerized calibration is described. Test results are shown in a table with go, return, limit, and average readings recorded at 0.1mm increments from 0-1.5mm. The data will be analyzed to determine errors at each reading point and compare the accuracy of the two calibration methods.
This document discusses various linear measurement instruments used in engineering. It begins by classifying linear measurement devices into low, medium, and high resolution. Low resolution devices include graduated rules and calipers. Medium resolution devices discussed are vernier calipers, micrometers, and dial gauges. High resolution devices able to measure to within microns include slip gauges and comparators. The document provides detailed descriptions and examples of how each of these tools is used to perform precise linear measurements.
This document provides an overview of metrology and measurements. It discusses key concepts in metrology including calibration, traceability, uncertainty, and accreditation. It defines metrology as the science of measurement and explains its importance. Metrology covers defining measurement units, establishing measurement standards, and documenting measurement accuracy. There are different categories of metrology including scientific, industrial, and legal metrology. The document also discusses various measurement tools and gauges used in industrial metrology.
This document discusses various measuring devices used for linear and angular measurements. It describes dimensions that are commonly measured and how measuring instruments are classified based on their resolution. Low, medium, and high resolution devices are explained. Specific linear measuring instruments like vernier calipers, micrometers, slip gauges, and comparators are also discussed. Comparators are mechanical, electrical or pneumatic devices used to compare unknown measurements to a known standard.
Unit 3 Lecture 1-2 Linear and Angular Measurement.pptxKhalil Alhatab
The document discusses various linear and angular measurement instruments. It begins by defining metrology and dimensional metrology. It then describes different types of linear measurement instruments including rules, calipers, micrometers, depth gauges, height gauges, and Vernier instruments. It discusses the design considerations and operating principles of these instruments. The document also covers angular measurement instruments and non-graduated gauges used for special purposes. In summary, the document provides an overview of common linear and angular measurement tools and their applications in dimensional metrology.
This document provides information about linear and angular measurement devices. It discusses various tools used for linear measurement such as vernier calipers, micrometers, slip gauges, comparators and tools for angular measurement including protractors, spirit levels, clinometers and sine bars. It also explains the working principles, applications and sources of error for some of these measurement devices.
The document provides instructions for calibrating precision measuring instruments and measuring lengths, diameters, and heights using vernier calipers, micrometers, and a vernier height gauge. Key steps include calibrating the instruments using slip gauges with known dimensions on a surface plate, then taking measurements of objects and recording the readings from the instruments along with any errors compared to the actual dimensions. Instruments are calibrated to determine their accuracy and establish a baseline before taking measurements.
Unit 3 Lecture 1-2 Linear and Angular Measurement.pdfKhalil Alhatab
The document discusses various linear and angular measurement instruments. It begins by defining metrology and dimensional metrology. It then describes different types of linear measurement instruments including rulers, calipers, micrometers, gauges and vernier calipers. For angular measurements, instruments discussed include protractors and sine bars. The document also covers topics like design considerations for measurement instruments and guidelines for using various tools.
The document discusses different types of vernier micrometers used for various measuring applications. It describes depth micrometers which measure depth, inside micrometers which measure inside diameters and surfaces, and tubular inside micrometers which are useful for internal cylindrical measurements. It also discusses micrometer parts like the ratchet, lock nut, and changeable anvils. Methods for measuring thread diameters and pitches using special thread micrometers are provided. Recent micrometer designs include indicating, direct reading, dual reading, and all-electronic models.
This document provides an overview of mechanical measurements and metrology. It discusses key concepts like accuracy, precision, types of errors in measurement, calibration, standards, and classification of measuring instruments. The objectives of metrology are outlined as ensuring measuring instruments are adequate and maintained through calibration. Factors affecting measurement accuracy are explored including the standard, workpiece, instrument, operator, and environment. Common methods of measurement and classification of instruments are also summarized.
The document describes laboratory experiments for testing the strength of materials and fluid mechanics. It includes 13 experiments such as Rockwell hardness testing, Brinell hardness testing, Izod impact testing, Charpy impact testing, torsion testing, deflection testing, and heat treatment processes. Details are provided on the procedure, theory, apparatus, and formulas for calculating results for Rockwell hardness testing, Brinell hardness testing, Izod impact testing and Charpy impact testing. The aim is to determine the hardness and impact strength of various metal specimens.
This document provides an overview of shaper, milling, and gear cutting machines. It discusses the main components and operations of shaper machines, including the shaper mechanism and work holding devices. It also covers drilling machines, boring operations, and different types of milling machines. Finally, it summarizes gear cutting and generation processes, including gear shaping, planning, and hobbing, as well as methods for finishing gears.
This document summarizes an experimental study of HCCI (Homogeneous Charge Compression Ignition) engines. HCCI engines have the potential for high efficiency and low emissions compared to spark ignition and compression ignition engines. However, controlling autoignition in HCCI engines is challenging. The document discusses various control methods for HCCI combustion including variable compression ratio, intake air heating, and variable valve timing. It also covers dual combustion modes, engine performance characteristics, recent HCCI engine prototypes, and conclusions about controlling premixed ratios in HCCI combustion for emissions and efficiency.
The document provides an overview of hydraulic circuits and components. It discusses key considerations in designing hydraulic circuits such as satisfying operational specifications safely, performing smooth operations, and reducing costs and heat generation. Hydraulic circuits are graphical diagrams that indicate the operation of components in hydraulic systems. The document also covers various types of circuits like speed control, pressure control, unloading, sequencing and accumulator circuits. It emphasizes understanding the application and selecting components appropriately based on factors like required forces, speeds, flows and pressures.
This document provides an overview of the laws of thermodynamics:
- The first law states that energy is conserved and the change in internal energy of a system equals heat added minus work done. Key processes like adiabatic, isothermal, isobaric, and isochoric are also introduced.
- The second law introduces the concept of entropy and states that heat cannot spontaneously flow from a cooler to a warmer body. It describes irreversible processes and defines the efficiency of heat engines.
- The third law states that absolute zero cannot be reached with a finite number of steps. This established the Kelvin temperature scale.
- The zeroth law establishes that if two bodies are in thermal
This document outlines the syllabus for a course on hydraulics and pneumatics. The course aims to provide students with knowledge of fluid power applications in industry and an understanding of hydraulic and pneumatic components and systems. The syllabus covers topics like fluid power principles, hydraulic pumps, actuators and controls, hydraulic circuits, pneumatic systems, troubleshooting, and applications. Upon completing the course, students will be able to explain fluid power operation, hydraulic components, hydraulic circuits systems, pneumatic circuits and systems, and troubleshoot hydraulic and pneumatic systems. The textbook and references for the course are also listed.
This document outlines the syllabus for a course on hydraulics and pneumatics. The course aims to provide students with knowledge of fluid power applications in industry and an understanding of hydraulic and pneumatic components and systems. The syllabus covers topics like fluid power principles, hydraulic pumps, actuators and controls, hydraulic circuits, pneumatic systems, troubleshooting, and applications. Upon completing the course, students will be able to explain fluid power operations, hydraulic components and circuits, pneumatic systems, and troubleshoot hydraulic and pneumatic issues. The document also lists two textbooks and four references for the course.
This document summarizes an experimental study of HCCI (Homogeneous Charge Compression Ignition) engines. HCCI engines have the potential for high efficiency and low emissions compared to spark ignition and compression ignition engines. However, controlling autoignition in HCCI engines is challenging. The document discusses various control methods for HCCI combustion including variable compression ratio, intake air heating, and variable valve timing. It also covers dual combustion modes, engine performance characteristics, recent HCCI engine prototypes, and conclusions about controlling premixed ratios in HCCI combustion for emissions and efficiency.
Fluid power systems use liquids or gases to transmit power and control movement. This document discusses fluid power applications and different fluid power systems. It compares hydraulic and pneumatic systems, lists their advantages and disadvantages, and explains their industrial uses. Key points covered include properties of hydraulic fluids, types of hydraulic fluids and factors influencing fluid selection, components of hydraulic systems, and distribution of fluids through pipes, tubes, hoses and connectors.
Form measurement includes measuring screw threads, gears, radii, surface finish, straightness, and roundness. Screw threads are classified as external or internal and have specific geometric features like crests, flanks, roots, pitch, and diameters that are measured using instruments like micrometers and comparators. The major diameter of external threads can be measured using an ordinary or bench micrometer by taking readings on a setting gauge and the thread. The minor diameter and pitch are measured using comparative methods with V-blocks or rollers and slip gauges or pitch measurement machines that precisely measure the distance between thread features.
Batteries -Introduction – Types of Batteries – discharging and charging of battery - characteristics of battery –battery rating- various tests on battery- – Primary battery: silver button cell- Secondary battery :Ni-Cd battery-modern battery: lithium ion battery-maintenance of batteries-choices of batteries for electric vehicle applications.
Fuel Cells: Introduction- importance and classification of fuel cells - description, principle, components, applications of fuel cells: H2-O2 fuel cell, alkaline fuel cell, molten carbonate fuel cell and direct methanol fuel cells.
Understanding Inductive Bias in Machine LearningSUTEJAS
This presentation explores the concept of inductive bias in machine learning. It explains how algorithms come with built-in assumptions and preferences that guide the learning process. You'll learn about the different types of inductive bias and how they can impact the performance and generalizability of machine learning models.
The presentation also covers the positive and negative aspects of inductive bias, along with strategies for mitigating potential drawbacks. We'll explore examples of how bias manifests in algorithms like neural networks and decision trees.
By understanding inductive bias, you can gain valuable insights into how machine learning models work and make informed decisions when building and deploying them.
Electric vehicle and photovoltaic advanced roles in enhancing the financial p...IJECEIAES
Climate change's impact on the planet forced the United Nations and governments to promote green energies and electric transportation. The deployments of photovoltaic (PV) and electric vehicle (EV) systems gained stronger momentum due to their numerous advantages over fossil fuel types. The advantages go beyond sustainability to reach financial support and stability. The work in this paper introduces the hybrid system between PV and EV to support industrial and commercial plants. This paper covers the theoretical framework of the proposed hybrid system including the required equation to complete the cost analysis when PV and EV are present. In addition, the proposed design diagram which sets the priorities and requirements of the system is presented. The proposed approach allows setup to advance their power stability, especially during power outages. The presented information supports researchers and plant owners to complete the necessary analysis while promoting the deployment of clean energy. The result of a case study that represents a dairy milk farmer supports the theoretical works and highlights its advanced benefits to existing plants. The short return on investment of the proposed approach supports the paper's novelty approach for the sustainable electrical system. In addition, the proposed system allows for an isolated power setup without the need for a transmission line which enhances the safety of the electrical network
Literature Review Basics and Understanding Reference Management.pptxDr Ramhari Poudyal
Three-day training on academic research focuses on analytical tools at United Technical College, supported by the University Grant Commission, Nepal. 24-26 May 2024
ACEP Magazine edition 4th launched on 05.06.2024Rahul
This document provides information about the third edition of the magazine "Sthapatya" published by the Association of Civil Engineers (Practicing) Aurangabad. It includes messages from current and past presidents of ACEP, memories and photos from past ACEP events, information on life time achievement awards given by ACEP, and a technical article on concrete maintenance, repairs and strengthening. The document highlights activities of ACEP and provides a technical educational article for members.
CHINA’S GEO-ECONOMIC OUTREACH IN CENTRAL ASIAN COUNTRIES AND FUTURE PROSPECTjpsjournal1
The rivalry between prominent international actors for dominance over Central Asia's hydrocarbon
reserves and the ancient silk trade route, along with China's diplomatic endeavours in the area, has been
referred to as the "New Great Game." This research centres on the power struggle, considering
geopolitical, geostrategic, and geoeconomic variables. Topics including trade, political hegemony, oil
politics, and conventional and nontraditional security are all explored and explained by the researcher.
Using Mackinder's Heartland, Spykman Rimland, and Hegemonic Stability theories, examines China's role
in Central Asia. This study adheres to the empirical epistemological method and has taken care of
objectivity. This study analyze primary and secondary research documents critically to elaborate role of
china’s geo economic outreach in central Asian countries and its future prospect. China is thriving in trade,
pipeline politics, and winning states, according to this study, thanks to important instruments like the
Shanghai Cooperation Organisation and the Belt and Road Economic Initiative. According to this study,
China is seeing significant success in commerce, pipeline politics, and gaining influence on other
governments. This success may be attributed to the effective utilisation of key tools such as the Shanghai
Cooperation Organisation and the Belt and Road Economic Initiative.
Embedded machine learning-based road conditions and driving behavior monitoringIJECEIAES
Car accident rates have increased in recent years, resulting in losses in human lives, properties, and other financial costs. An embedded machine learning-based system is developed to address this critical issue. The system can monitor road conditions, detect driving patterns, and identify aggressive driving behaviors. The system is based on neural networks trained on a comprehensive dataset of driving events, driving styles, and road conditions. The system effectively detects potential risks and helps mitigate the frequency and impact of accidents. The primary goal is to ensure the safety of drivers and vehicles. Collecting data involved gathering information on three key road events: normal street and normal drive, speed bumps, circular yellow speed bumps, and three aggressive driving actions: sudden start, sudden stop, and sudden entry. The gathered data is processed and analyzed using a machine learning system designed for limited power and memory devices. The developed system resulted in 91.9% accuracy, 93.6% precision, and 92% recall. The achieved inference time on an Arduino Nano 33 BLE Sense with a 32-bit CPU running at 64 MHz is 34 ms and requires 2.6 kB peak RAM and 139.9 kB program flash memory, making it suitable for resource-constrained embedded systems.
gray level transformation unit 3(image processing))
UNIT-I PPT EMM.ppt
1. Basics of metrology
Metro-Measurement, Logy-Science.
Important parameter is length.
Metrology of length and metrology of time.
IMPORTANCE
Errors of measurement and developing new methods.
Researching the causes of measuring error.
Industrial inspection in various techniques.
Design and manufacturing and testing in various
guages.
2. Need and importance of
metrology
Metrology is solving for all technical
problems of engineering field.
The design engineer not only checked
from design and production point of view
dimensions also measured.
To achieve quality of production.
To reduce rejection rate in quality unit.
To develop inspection procedure and cost,
and instrument measuring time.
3. TYPES OF METROLOGY
Scientific metrology - Development of measurement standards.
Industrial metrology- proper measuring instrument are used.
Legal metrology - NSLM ( National service of legal measurement).
A) industrial measurement b) Commercial transaction c) Public
health and human safety.
Fundamental metrology - scientific measurement.
Dynamic metrology - measurement of small variation electronic
equipment ( CADD OPTIC FIBER LASER INSTRUMENT).
Deterministic metrology - Replace measurement of CNC control
system.
4. MEASUREMENT
Measurement is comparison of a given unknown
quantity with one of its predetermined standard
values adopted as a unit.
The standard are used and accurate of
accepted internationally.
The apparatus and process used for comparison
is proved.
5. Metrology:
Metrology is defined as the science of measurement.
Metrology divided into two types:
1.Industrial Metrology
2.Medical Metrology
Metrology Mainly Concerned with:
Unit of Measurement and their standards
Errors of measurement
Ensuring the uniformity of measurements
Developing new methods of measurements
Analyzing this new methods and their accuracy
Gauges design and manufacturing
Researching the causes of measuring errors.
Industrial Inspection
6. Legal Metrology:
Is the part of Metrology and it is directed by National organization
which is called" National service of legal metrology”
Main objective of Legal Metrology:
To maintain uniformity of measurement in a particular country.
Functions of NSLM:
To ensure conversation of industrial standards
Guarantee their accuracy by comparison with
International standards
To organize training in this field
Regulate, Supervise and control the manufacturer
Giving advice to repair of measuring instruments
To inspect and detect guilty of measurement.
7. Applications of Legal Metrology:
Industrial Measurement
Commercial Transactions
Public health and human safety ensuring
Dimensional Measurements:
Very common measurement is that of a dimension,i.e length,
Width or height of an object.
Depending on the quality of requirement the instruments
are classified into the following type.
oLow Resolution
oMedium Resolution
oHigh Resolution
8. Low Resolution Devices(upto 0.25mm):
Steel rule
Steel rule with the assistance of calipers, dividers
and surface gauges
Thickness gauges
Medium Resolution Devices(upto 0.0025mm):
Micrometers
Vernier
Dial indicators
Measuring Microscope
9. High Resolution Devices(Less than microns):
Gauge Blocks
Gauge blocks with
Mechanical Comparators
Electrical Comparators
Pneumatic Comparators
Optical Flats
10. Linear Measuring Instruments:
It Includes the Measurement of
Length
Diameter
Heights
Thickness
Basic Principal of Linear Measuring Instruments:
Comparison with standards Dimensions on a suitably
engraved instrument or device.
11. Various Devices Used for Measuring the
Linear Measuring Instruments:
1. Vernier Caliper
2. Micrometers
3. Slip gauge or gauge blocks
4. Comparators
Vernier Caliper:
The Vernier Caliper is a precision instrument that can be
used to measure internal and external distances extremely
accurately.
13. Least count (L.C):
The least count of the vernier can be measured by
using the formula stated below.
Least count (L.C) = 1 M.S.D - 1 V.S.D
Example;
vernier scale is constructed by taking 49 main scale
divisions
dividing them into 50 divisions
i.e.. 49mm divided into 50 parts
therefore
1 Vsd=49/50 mm=0.98mm
1 MSD=1mm
substituting in formula
L.C = 1 M.S.D - 1 V.S.D
L.C=1-0.98=0.02mm
15. MATHEMATICAL METHOD
A. The main metric scale is read first and this shows that there
are 13 whole divisions before the 0 on the hundredths scale.
Therefore, the first number is 13.
B. The’ hundredths of mm’ scale is then read. The best way to do this
is to count the number of divisions until you get to the division that
lines up with the main metric scale. This is 21 divisions on the
hundredths scale.
C. This 21 is multiplied by 0.02 giving 0.42 as the answer
(each division on the hundredths scale is equivalent to 0.02mm).
D. The 13 and the 0.42 are added together to give the final
measurement of 13.42mm (the diameter of the piece of round section steel)
17. Types of Vernier Calipers: TYPE A
Accuracy – 0.02mm
Jaws are provided on both sides for internal and External measurements
One blade is fitted to measure the depth of the part
18. TYPE B
Accuracy - 0.05mm
Jaws are provided on only one side for internal and External measurements
19. TYPE C
Accuracy - 0.1mm
Jaws are provided on both sides for internal and External measurements
20. Errors in measurements with vernier calipers:
Errors may arise in manipulation of vernier caliper.
Jaw movement should be perpendicular to the scale readings.
Contact portions of measuring jaws should be good conditions
During internal measurements, the jaws may be bowlegged
21. Care and Precautions:
Jaws should not be used as wrench or hammer Because vernier is not
a rugged instrument
Instrument should be kept in box and not suddenly dropped and turned up
and down
Vernier caliper should not be used in oil, grit and chip area
One hand should be used for stationary jaw and the other hand for
Supporting Movable jaw
Operator should wear eye glass and magnifying glass during measurements
23. Micrometer:
is a device incorporating a calibrated screw used widely for precise
measurement of small distances in mechanical engineering.
24. Parts:
1.Frame:
The C-shaped body that holds the anvil and barrel in constant relation to each other.
It is thick because it needs to minimize flexion, expansion, and contraction,
which would distort the measurement.
The frame is heavy and consequently has a high thermal mass, to prevent substantial
heating up by the holding hand/fingers.
It is often covered by insulating plastic plates which further reduce heat transference.
2.Anvil:
The fixed anvil of the micrometer protrudes for 3mm form frame to support the part
at the end
The measuring face of the anvil should be strong enough to reduce wear and tear
The face of the anvil is tipped with tungsten carbide.
25. 3.Spindle:
The spindle is placed inside the barrel to slide freely
Bush is placed in the space between barrel and spindle to ensure free running of spindle
Light non corrosive oil is used to lubricate the spindle and screw.
4.Ratchet driver:
Wear resistant material is used to make ratchet
5.Thimble and barrel:
Graduations are made on both barrel and thimble
Parts are made by using high wear resistant material
6.Adjusting nut:
Adjusting nuts are used to get zero reading
Accuracy of the measurement is depends on original accuracy and function of
lock nut
26. Types of Micrometer:
1.Outside Micrometer:
It consists of two scales, Main scale and thimble scale
While the pitch of barrel screw is 0.5mm,the thimble has graduation of 0.01mm
The least count of this micrometer is 0.01mm
27. 2.Inside Micrometer:
Used for measuring internal dimensions.
It consists of mainly four parts such as measuring head, extension rods,
spacing collars and handle.
The range of measurement can be varied by using different lengths of extension
rods and spacing collars
28. 3.Stick Micrometer:
Inside micro meters can be used to measure only smaller lengths
A Micrometer to measure longer lengths is known as stick micrometer
These Micrometers are formed by connecting 150mm or 300mm micrometer unit
29. 4.Micrometer depth gauge:
Mainly used to measure depth of holes, slots and recesses
Shoulder act as a reference surface
While measuring reference surface slides up and down
It is held tightly perpendicular to the axis of the hole
30. 5.Thread Micrometer:
Thread micrometer is used to measure threads within certain range of thread pitches
The end of the spindle is pointed to the ‘V’ thread form with a corresponding Vee - reces
in the fixed anvil.
31. Advantages:
The only method is to show the variation in drunken thread
Limitations:
It must be set to a standard thread plug
When setting standard plug gauge the reading is not exactly zero
32. 6. V-anvil micrometer caliper:
The running error can be checked quickly by V-anvil micrometer caliper in grinding
and other special machines.
The accuracy is high because all parts involved in this caliper are highly precision.
But error may become due to incorrect handling of micrometer caliper, inadequate
aligning wear and tear etc.
33. 7. Blade type Micrometer:
This is best suitable for measuring circular formed tools, diameter of narrow grooves
Slots and key ways.
It has non-rotating spindle.
The rate of measurement is fast.
34. 8. Micrometer for measuring thickness of cylindrical walls:
The anvil of thickness micrometer is in spherical form
The axis of spindle is perpendicular to the spherical surface
35. 9.Dial Micrometer caliper:
oDial indicator is connected with the movable anvil.
oThe slight movement of this anvil is directly indicated on the dial of the dial indicator
oThis type of micrometer is very much useful for statistical quality work for different
size variation
36. 10.Bench micrometer:
All parts of the micrometer are mounted on the bench.
Fixed anvil is fitted at the one end of the micrometer.
Movable anvil along with dial is fitted on the other end of the bench
Slight movement of the movable anvil will be indicated correspondingly
on the dial as deflection.
37. 11.Taper screw operated internal micrometer:
Taper screw threads are formed at the end of the main spindle
The screw threads are just made to the feeler
For measurement the same procedure is followed as that of conventional type.
When he ratchet is revolved, the vibration will be adjusted itself in the bore.
Due to this the sense of feel is sensed by the operator quickly
38. 12. Groove Micrometer:
Specially designed for grooves, recess and shoulders which are located centrally
These are stain chrome finished throughout to ensure high precision
Not only used to measure thickness and spacing but also to measure the distance
between Edge to land.
39. 13.Digital Micrometer:
All the measurements will be indicated as numerical values
Interpolations can be avoided when the measurements is in between to divisions
Accuracy will be higher
Spindle can be locked at any desired position
Zero setting is done by pressing push button
40. 14.Differential screw micrometer:
Micrometer is designed in such a way that to get differential movement
Spindle advancement is larger when compared to conventional micrometer.
Measurement obtained is very high accuracy
Theoretical value of accuracy is 0.002mm
42. Interval of measurement:
Slip Gauges:
Slip gauges are blocks of steel that have been hardened and stabilized
by heat treatment.
Surface of slip gauges are made to a high degree of accuracy
Distance between two opposite faces indicates the size of the gauge
The accuracy and finish is so high that two or more slip gauges may be
wrung together
43. Classification of slip gauges:
Based on their use classified into the following:
1. Grade 2
2. Grade1
3. Grade 0
4. Grade 00
5. Calibration Grade
44. Grade2:
It is a workshop grade
Used for setting tools
Cutters and
Checking dimensions roughly
Grade 1:
Used for precise work in tool rooms
Grade 0:
This is Inspection grade, Used in Inspection Department
45. Grade 00:
Used in high precision works in the form of error detection in instruments.
Calibration Grade:
Actual size of the slip gauge is calibrated on a chart supplied by the
manufacturers.
47. Inferometers are used to check the surface quality of the slip gauges
Instruments consists essentially of a mercury - vapour lamp
Whose Radians are passed through a green filter
Thus removing all other colour, and leaving green mono-chromatic light
Wavelength is very closer to 0.5µm.
Light is focused into a pinhole
This gives intense point source of monochromatic light which is in the
focal plane Beam of the light.
The beam is directed onto the gauge to be tested via an optical flat so that
Interference are formed across the face of the gauge.
Fringes being viewed from directly above the face of the gauge
The glass plate semi reflector set at 45° to the optical axis.
48. Advantage:
We can test parallelism between two gauge surface
Two methods are used:
1.For gauges below 25mm in length
2.For gauges greater than 25mm in length
When shorter gauges are used ,interference fringes will be focused
Both on the gauge surface and the base plate.
As the gauge is wrung on the base plate, its underside is parallel with its base plate
It means the gauges are parallel.
49. If the gauge is more than 25mm in length the fringe pattern on the
base plate is difficult to observe but the base plate is rotary and its under side
is lapped Truly parallel with its working surface.
If it is non parallel, If the table is turned through 180°, the surface is now less paralle
With the optical plate, and a greater number of fringes are observed.
50. Application of Limit gauges:
Thread Gauges
Form Gauges
Screw pitch Gauges
Radius and fillet gauges
Feeler gauges
Plate gauge and wire gauges
Indicating gauges
Air gauges
51. Thread Gauge:
Threads are checked with the help of thread gauges
Internal Thread - Plug thread gauges are used
External Thread - Ring thread gauges are used
52. Form Gauge:
To be used to check the contour of a profile
of a work piece
Form gauges are nothing but template gauges
Made of steel sheet.
53. Screw pitch Gauge:
Used to Check the pitch of the thread immediately.
It is very much in every day tool used to pick out a
required screw
54. Radius and fillet gauges:
Radius of curvature can be measured by using
these gauges.
Radius may be either inner or outer
For inner radius end of the blade made in convex
For outer radius end of the blade made in concave
55. Feeler Gauge:
Used for checking the clearance between mating surfaces
Mainly used in adjusting the valve clearance in automobiles
They are made from 0.03mm to 1.0mm thick of 100mm long
The blades are pivoted in a holder
56. Plate Gauge and Wire gauge:
Thickness of sheet metal is checked by plate gauge
Diameter of wire is checked by wire gauge
57. Indicating Gauge:
Mainly designed for measuring errors in geometrical
Form and size, and for testing surfaces for their true
position with respect to one another.
Run out of toothed wheels,pullyes and various revolving
parts
58. Air Gauge:
Primarily used for determining the inside characteristics
of a hole by means of Compressed air.
59. Comparators:
Comparators is a precision instrument employed
to compare the dimension of a given Component
with a working standard (usually slip gauges).
Comparators will not show the actual dimension
This will shown only the deviation in size
Types of Comparators are:
Mechanical Comparators
Electrical Comparators
Optical Comparators
Pneumatic Comparators
60. Mechanical Comparators:
It Employs mechanical means for Magnifying small deviations
Method of magnifying small movement of the in all mechanical comparators
are effected by means of levers, gear trains or combinations of these elements.
Mainly used for inspection of small parts machined to close limits
62. Dial gauge is used as a mechanical Comparators
Essential parts are Small clock with a plunger projecting
at the bottom
Very Slight Upward movement on the plunger moves it upward
and the movement is indicated by the dial pointer.
The Dial is graduated into 100 divisions
A full revolution of the pointer about this scales corresponds
to 1mm travel of the plunger
Thus, a turn of a pointer by one scale division represents a plunge
travel of 0.01mm
64. The setup consists of work table, dial indicator and vertical post
Dial indicator is fitted to a vertical post by on adjusting screw
Vertical post is fitted on the work table
Surface of the work table is fine finished
Dial gauge can be adjusted vertically and locked in position
by a screw
Initially, this height is built up with slip gauges.
The slip gauge blocks are placed under the stem of the dial gauge
The pointer in the dial gauge is adjusted to zero
The slip gauges are removed
Now the component to be checked is introduced under
the stem of the dial gauge if there is any deviation in the
height of the component, it will be indicated by the pointer
65. Mechanism:
The plunger has rock teeth
Set of gears engage with the rocks
The pointer is connected to a small pinion
Small pinion is independently hinged
(i.e. It is not connected to the plunger)
Vertical movement of the plunger is
transmitted to the pointer through a
set of gears
Spring gives constant downward pressure
to the plunger
67. Transducer:
An iron armature is provided in between two coils held by a leaf spring
at one end
The other end is supported against a plunger
The two coils act as two arms of an A.C wheat stone bridge circuit
Amplifier:
Is nothing but a device which amplifies the given input signal frequency into
magnified output.
Display device or meter:
The amplified signal is displayed on some terminal stage instruments.
Here the terminal instrument is meter.
68. Working principle:
Since the armature is centrally located between the coils, the inductance
of both the coils Will be equal but in opposite direction with the sign change.
Due to this, Wheatstone bridge is balanced
Therefore the meter will read zero value
But practically it is not possible
In real time, the armature may be lifted up or lowered down by the plunger
during measurement.
This would upset the balance of the Wheatstone circuit
Due to this change in current is introduced correspondingly
On that time the meter will indicate some value as displacement
69. Optical Comparator:
In Optical Comparators, a small plunger displacement is amplified by
both mechanical and Optical System.
The Amplification is first done by a pivoted lever and then by simple optical
system.
70. Construction Details:
It Consists of the following parts,
Pivoted Lever, Objective Lens,scale,Plunger,Table and Base, and Mirror
Pivoted lever:
The Pivoted lever amplifies the plunger movement mechanically
It is pivoted near the plunger
One end is fitted with the plunger and the other end is fitted with a mirror.
Objective Lens:
Main Function is to convert the incoming light rays from the source
into Parallel Beams.
71. Screen and scale:
This is a final display device from which the readings can be obtained.
This is nothing but a semi-transparent glass.
Plunger:
It is a reciprocating member.
During the measurement, the plunger actuates
Table:
The work is placed on the table to carry our task.
72. Base:
It is a rigid support over which the table is mounted
Mirror:
It reflect the incoming light rays
from the source which is hinged at the other
end of the lever.
73. Working Principle:
During the measurement, the vertical displacement of the plunger is magnified
by the ratio of the lever arm
The lever tilts the mirror about its hinge to again magnify.
The light rays from the lamp are condensed by a condensing lens.
Then the condensed light falls on the objective lens
Here the light rays are converted into parallel beams
Again the parallel beams of light ray fall on the mirror.
The mirror reflects the light rays on a screen.
AS the screen is a semi-transparent glass, the image of the work placed over
the screen.
Now the projected image is compared with the master drawing
This type is used for to inspect small thread gear teeth, cutting tools,needles,cam profile
etc.,
74. Pneumatic Comparators:
The pressurized air is used as the working medium in pneumatic comparator
Classified into two types:
1.Flow or Velocity type
2.Back pressure type
76. Principle of working:
The readings are obtained by sensing and indicating the rate of
airflow through a tapered glass tube.
77. The glass tube is already calibrated to the required dimensions by
a suitable device called Slip Gauges
Then the Compressed air from the Compressor is passed through the filter and
Pressure regulator.
Then it is passed through a tapered glass tube from which the air is passed through
A plastic tube to the measuring head.
The measuring head has a orifices through which the air escapes to the atmosphere
The position of float depends on the gap between the internal dimensions and the
Gauging head.
If more displacement for the float requires with high amplification, the following
Modification has to implement.
The plastic tube is extended to supply air through the bottom of the glass tube.
Thus higher magnification can be obtained.
The bleed valve is fitted in the top to rest the float at any required position
(i.e Setting Zero reading).
78. A bleed valve is the valve through which air can be escaped to the atmosphere
Without passing to measuring head.
In measuring head, the orifices are recessed to avoid the direct contact of air wit
Work piece.
Hence, Surface wear will not occur on the specimen.
79. Back Pressure Type:
In this type, the air flows to the atmosphere
at a constant pressure through orifices.
When the orifice O2 is fully Closed, the
pressure Ps and Pi will be equal.
The Pressure Ps ans Pi are equal to zero
when the Orifice O2 is in full opening
Condition.
Pressure Ps and Pi varies when the distance d Varies.
If there is any variation in pressure of Ps and Pi which can be measured by suitable
measuring device.
This type is mainly used in backpressure type pneumatic Comparators.
Ex:Solex air gauge.
80. Sine Bar:
Sine bars are always used along with slip gauges
Used to:
Measures angles very accurately
Locate the work piece to a given angle with very high precision.
81. Sine bars are made from high corbon,high chromium, and corrosion steels
Materials are highly hardned,ground and stabilized
Two Cylinders of equal diameters are attached at the ends with its axis mutually
parallel to each other
Also at equal distance from upper surface of the sine bar.
Sine bar Ranges 100mm,200mm and 300mm
Cylindrical holes are provided to reduce the weight of sine bar
82. Most preferred sine bar, Since the distance between rollers can be adjusted exactly.
Also it is easy to set on steep angle without the slip gauges.
83. Most commonly used form of sine bar
Rollers are arranged in such a way that their outside surface on one side is level wit
the plane top surface of the sine bar.
84. Hollow rollers are integral with the sine bar and the outside diameter of the rollers
Is equal to the width of the sine bar
85. Special form of sine bar
This type is used where ordinary type cannot be used on the top surface due to
interruption
87. Working is based on trigonometry principle
To measure the angle of the given specimen, one roller of the sine bar is placed on the
Surface plate and another one roller is placed over the surface of the slip gauges.
h – Height of the slip gauge
L- Distance between roller centers
88. Accuracy Requirement of a sine bar:
Rollers must have equal diameter and equal cylinders
Rollers should be placed parallel to each other and also to the upper surface
The accurate center to center of rollers must be known
The top surface of the bar must be flat with high degree of accuracy
89. Classification of sine bars:
Classified into two Categories:
According to accuracy of centre distance:
1.Grade A
2.Grade B
According to availability of different designs
Type 1
Type 2
Type 3
Type 4