1. The document discusses various methods for measuring different elements of screw threads and gears, including major diameter, minor diameter, effective diameter, pitch, flank angle, and roundness.
2. Thread measurement methods include using micrometers, V-blocks, taper parallels, and rollers. Pitch can be measured using a pitch gauge, toolmaker's microscope, or pitch measuring machine.
3. Effective diameter is typically measured using one, two, or three wire methods. Flank angles are measured using optical projection.
The document discusses various aspects of screw threads and their measurement. It defines key screw thread terminology like pitch, lead, major diameter, minor diameter, effective diameter, flank angle, etc. It describes different types of threads and their uses. It then explains various methods to measure elements of a screw thread like major diameter, minor diameter, pitch, effective diameter and flank angle. These include using a micrometer, bench micrometer, pitch measuring machine, toolmaker's microscope and different wire methods. The concept of best wire size for effective diameter measurement is also introduced.
Test for straightness by using spirit level and Autocollimator
The straightness of any surface could be determined by either of these instruments by measuring the relative angular positions of number of adjacent sections of the surface to be tested. First straight line is drawn on the surface then it is divided into a number of sections the length of each section being equal to the length of sprit level base or the plane reflector’ s base in case of auto collimator. The bases of the spirit level block or reflector are fitted with two feet so that only feet have line contact with the surface and the surface of base does not touch the surface to he tested. The angular division obtained is between the specified two points. Length of each section must be equal to distance between the centerlines of two feet. The special level can be used only for the measurement of straightness of horizontal surfaces while auto-collimator can be used on surfaces are any plane. In case of spirit level, the block is moved along the line equal to the pitch distance between the centerline of the feet and the angular variation of the direction of block. Angular variation can be determined in terms of the difference of height between two points by knowing the least count of level and length of the base.
This presentation gives the information about Screw thread measurements and Gear measurement of the subject: Mechanical measurement and Metrology (10ME32/42) of VTU Syllabus covering unit-4.
Form metrology Thread measurement in metrology.pptxBikash Choudhuri
1. Screw threads are used to transmit power and motion or fasten components like nuts and bolts. They come in different forms defined by their included angle, helix angle, and other properties.
2. Common types of screw threads include British, Whitworth, and Metric threads, which have specific dimensional relationships between the pitch, depth, and radius.
3. Measuring screw threads accurately is important. Key dimensions that must be measured include the major diameter, minor diameter, effective diameter, pitch, and flank angles. Various instruments like micrometers and comparators are used to measure these critical thread properties.
This document discusses methods for measuring various elements of screw threads, including major diameter, minor diameter, effective diameter or pitch diameter, pitch, flank angle, and thread form. Common measurement tools mentioned include micrometers, thread comparators, thread micrometers, tool makers microscopes, and optical projection. Methods like using setting gauges, V-pieces, taper parallels, rollers and slip gauges, and one-, two-, or three-wire techniques are described for different thread measurements.
Screw threads are used to fasten components and transmit motion or power. There are various types of screw threads classified by their form, included angle, and other geometric properties. Common thread types include British Standard, Whitworth, and metric threads. Screw thread geometry includes features like the crest, flanks, root, pitch, helix angle, and diameters. Errors in screw threads can occur during manufacturing and affect the thread form and fit. Measurement of screw threads involves determining dimensions like the major diameter, minor diameter, effective or pitch diameter, and pitch using instruments like micrometers, thread comparators, and slip gauges.
The document discusses methods for measuring the major and minor diameters of external and internal screw threads.
The major diameter of an external thread can be measured using an ordinary or bench micrometer. The bench micrometer provides greater accuracy. The minor diameter of an external thread is measured using a comparative method with V-pieces on a floating carriage micrometer.
For internal threads, the major diameter can be measured using a horizontal comparator with styli. The minor diameter can be found using taper parallels and a micrometer, or rollers and slip gauges inserted into the thread.
The document discusses various aspects of screw threads and their measurement. It defines key screw thread terminology like pitch, lead, major diameter, minor diameter, effective diameter, flank angle, etc. It describes different types of threads and their uses. It then explains various methods to measure elements of a screw thread like major diameter, minor diameter, pitch, effective diameter and flank angle. These include using a micrometer, bench micrometer, pitch measuring machine, toolmaker's microscope and different wire methods. The concept of best wire size for effective diameter measurement is also introduced.
Test for straightness by using spirit level and Autocollimator
The straightness of any surface could be determined by either of these instruments by measuring the relative angular positions of number of adjacent sections of the surface to be tested. First straight line is drawn on the surface then it is divided into a number of sections the length of each section being equal to the length of sprit level base or the plane reflector’ s base in case of auto collimator. The bases of the spirit level block or reflector are fitted with two feet so that only feet have line contact with the surface and the surface of base does not touch the surface to he tested. The angular division obtained is between the specified two points. Length of each section must be equal to distance between the centerlines of two feet. The special level can be used only for the measurement of straightness of horizontal surfaces while auto-collimator can be used on surfaces are any plane. In case of spirit level, the block is moved along the line equal to the pitch distance between the centerline of the feet and the angular variation of the direction of block. Angular variation can be determined in terms of the difference of height between two points by knowing the least count of level and length of the base.
This presentation gives the information about Screw thread measurements and Gear measurement of the subject: Mechanical measurement and Metrology (10ME32/42) of VTU Syllabus covering unit-4.
Form metrology Thread measurement in metrology.pptxBikash Choudhuri
1. Screw threads are used to transmit power and motion or fasten components like nuts and bolts. They come in different forms defined by their included angle, helix angle, and other properties.
2. Common types of screw threads include British, Whitworth, and Metric threads, which have specific dimensional relationships between the pitch, depth, and radius.
3. Measuring screw threads accurately is important. Key dimensions that must be measured include the major diameter, minor diameter, effective diameter, pitch, and flank angles. Various instruments like micrometers and comparators are used to measure these critical thread properties.
This document discusses methods for measuring various elements of screw threads, including major diameter, minor diameter, effective diameter or pitch diameter, pitch, flank angle, and thread form. Common measurement tools mentioned include micrometers, thread comparators, thread micrometers, tool makers microscopes, and optical projection. Methods like using setting gauges, V-pieces, taper parallels, rollers and slip gauges, and one-, two-, or three-wire techniques are described for different thread measurements.
Screw threads are used to fasten components and transmit motion or power. There are various types of screw threads classified by their form, included angle, and other geometric properties. Common thread types include British Standard, Whitworth, and metric threads. Screw thread geometry includes features like the crest, flanks, root, pitch, helix angle, and diameters. Errors in screw threads can occur during manufacturing and affect the thread form and fit. Measurement of screw threads involves determining dimensions like the major diameter, minor diameter, effective or pitch diameter, and pitch using instruments like micrometers, thread comparators, and slip gauges.
The document discusses methods for measuring the major and minor diameters of external and internal screw threads.
The major diameter of an external thread can be measured using an ordinary or bench micrometer. The bench micrometer provides greater accuracy. The minor diameter of an external thread is measured using a comparative method with V-pieces on a floating carriage micrometer.
For internal threads, the major diameter can be measured using a horizontal comparator with styli. The minor diameter can be found using taper parallels and a micrometer, or rollers and slip gauges inserted into the thread.
Ch-3: Measurement of screw thread and gearSuraj Shukla
The document discusses measurement of screw thread elements. It begins by defining key screw thread terminology such as external thread, internal thread, pitch, lead, etc. It then describes various methods for measuring the major diameter, minor diameter, effective diameter (pitch diameter), and pitch of external screw threads. Methods discussed include using a micrometer, V-pieces, taper parallels, and wires/rods. The goal is to measure the critical geometric aspects that ensure interchangeability of threaded fasteners.
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.
This document discusses screw threads and methods for measuring their key parameters. It defines screw threads as helical ridges on cylinders or cones that allow rotational motion. Threads are classified as external or internal, right-handed or left-handed, single-start or multi-start. Common thread forms include Vee threads and transmission threads. Parameters like major diameter, minor diameter, pitch, and angle are measured using instruments like micrometers, parallels, and wires. Errors in threads can occur due to issues in manufacturing and include progressive, periodic, drunken, and irregular errors.
The document discusses different aspects of screw thread metrology. It describes the key elements of a screw thread such as major diameter, minor diameter, pitch diameter, pitch, lead, crest, root, depth of thread, flank, and angle of thread. It then discusses different forms of screw threads including British Standard Whitworth, British Association, American National Standard, Unified Standard, square, Acme, knuckle, and buttress threads. The final sections cover various methods for measuring elements of a screw thread such as major diameter, minor diameter, pitch diameter, pitch, and thread angle using instruments like micrometers, thread micrometers, pitch measuring machines, and tool makers microscopes.
The document discusses measurement and metrology of screw threads. It begins with definitions of screw thread terminology such as major diameter, minor diameter, pitch, angle, and forms of threads. It then describes methods for measuring the major diameter, minor diameter, effective diameter, and pitch of screw threads. The key measurement methods discussed are using micrometers, pitch gauges, and a tool maker's microscope. The goal is to understand principles and techniques for measuring characteristics of screw threads.
This document discusses screw threads, including their classification, measurement, and sources of errors. It defines a screw thread as a helical ridge on the external or internal surface of a cylinder or cone. Threads are classified by their location (external or internal) and direction of rotation (right-handed or left-handed). Methods to measure the major diameter, effective diameter, and pitch are described using instruments like micrometers and wires. Sources of errors in threads include issues with the major diameter, minor diameter, pitch, and form that can lead to interference or lack of contact between threads.
This document provides an overview of the Mechanical Measurement and Metrology subject for B.Tech Mechanical Engineering students. The objectives are to develop knowledge of measurement basics, methods, and devices. Key topics covered include linear, angular, thread and gear measurement, as well as force, torque, pressure, temperature and strain measurement. Specific techniques discussed include thread measurement methods using wires, gear metrology, and advancements like coordinate measuring machines and machine vision systems. Measurement of screw thread elements like diameter, pitch, and errors are explained in detail.
This document provides information on measuring various geometric features of screw threads and gears. It discusses measuring the major diameter, minor diameter, pitch, and other elements of threads using instruments like micrometers, thread gauges, and comparators. For gears, it describes measuring runout, pitch, profile, backlash, tooth thickness, and alignment using devices like dial indicators, involute measuring machines, and angular measurement techniques. The document also defines common terminology for screw thread and gear geometry.
This document defines screw thread terminology and describes methods for measuring screw thread features. It discusses thread elements such as major diameter, minor diameter, pitch diameter. It also explains different thread types and gauging methods used to check threads, including plug gauges, ring gauges, and micrometers. Measurement of pitch, form, and angle is described along with causes and measurement of pitch errors. Tolerances for screw threads based on ISO standards are also provided.
This document discusses various linear measurement instruments categorized as either non-precision or precision tools. Non-precision tools like steel rules and calipers provide measurements to the nearest line on the tool. Precision tools like vernier calipers, micrometers, and slip gauges provide highly accurate measurements. The document describes the parts and operating principles of vernier calipers, micrometers, height gauges, and slip gauges. It also provides formulas for calculating measurements and measurement errors using these precision tools.
The document discusses methods for measuring elements of internal screw threads, including major diameter, minor diameter, effective diameter, and pitch. It describes using tools like horizontal comparators, micrometers, taper parallels, slip gauges, and rollers to measure diameters. Effective diameter can be measured using ball-ended styli in a thread measuring machine. Pitch is measured using an adapter in a pitch measuring machine. The document also covers plug gauge types for internal threads and common errors in threads like errors in diameters, thread angle, and pitch.
This document provides information on measuring various geometric properties of screws, gears, and surfaces. It discusses measuring the thread properties like major diameter, minor diameter, pitch, and flank angle using tools like micrometers, thread gauges, and optical projectors. Gear measurement techniques are described for properties such as runout, pitch, profile, backlash, and tooth thickness. Methods for measuring radii, roundness, flatness, and surface finish are also summarized. The document aims to outline the different measurement techniques and terminology used for dimensional inspection of screws, gears, and surface geometry.
This document discusses various methods for measuring threads, including both external and internal threads. It describes using micrometers, thread gauges, and thread micrometers to measure the major diameter, minor diameter, pitch, angle, and form of threads. Specific thread measurement techniques are outlined, such as using GO and NO-GO plug gauges to check internal thread size limits. Measurement of thread elements includes the major diameter, minor diameter, effective diameter, and pitch. Instruments like screw thread micrometers and limit thread gauges are used to directly measure the pitch and check threads against pre-determined size limits.
This document discusses screw thread measurement and terminology. It defines a screw thread as a helical ridge on a cylinder or cone used to hold parts together or transmit motion. There are external and internal threads. Key terms are defined such as pitch, diameter, flank, and angle. Methods to measure major diameter, minor diameter, and effective diameter are described using instruments like micrometers and thread gauges. Sources of errors in threads are also outlined.
This document discusses the terminology and measurement of screw threads. It defines various elements of screw threads including the crest, root, flanks, pitch, and angle of the thread. It describes different types of errors that can occur in screw threads such as progressive, periodic, and drunken pitch errors. It also explains how to measure the major diameter using a bench micrometer or hand microscope by taking readings on a calibrated cylinder for accuracy. The minor diameter is measured using V-pieces that contact the root of the thread.
This document describes several common measuring instruments, including metre rules, measuring tapes, vernier callipers, and screw gauges. It explains what each instrument is used for and provides details on their construction and how measurements are taken. For example, it states that metre rules measure length using centimetre and millimetre markings, while vernier callipers can measure internal and external diameters using a main scale and movable vernier scale that has a least count of 0.1 mm. The document also discusses zero error and how to apply corrections.
This presentation by Hooria Shahzad is about measuring instruments in which we study metre rule, measuring tape, vernier callipers and screw gauge ; construction of vernier callipers and screw gauge.
This document discusses the measurement of screw threads. It defines various screw thread terminology such as crest, root, flank, pitch, and angle of thread. It describes common types of pitch errors in screw threads such as progressive, periodic, and drunken threads. It also outlines various methods for measuring important screw thread dimensions like major diameter, minor diameter, and effective diameter. These include using a bench micrometer, thread micrometer, and two-wire method. Accurately measuring thread features is important for evaluating thread quality and fit.
The document provides an overview of theory of machines and machine elements design. It discusses kinematics, which is the study of motion without considering forces. Kinematics of machines deals with the relative motion between machine parts through displacement, velocity and acceleration. A mechanism is defined as part of a machine that transmits motion and power from input to output. Key concepts discussed include links, kinematic pairs, degrees of freedom, and inversions of mechanisms. Common mechanisms like slider crank chains and their inversions are presented. The document also discusses straight line motion generators, intermittent motion mechanisms, and mechanical advantage in mechanisms.
Homogeneous charge compression ignition (HCCI) engines and stratified charge engines are recent engine technologies that allow for lean combustion. HCCI engines use autoignition of a premixed fuel-air mixture, while stratified charge engines directly inject fuel near the spark plug. Common rail direct injection diesel engines and gasoline direct injection engines provide more precise fuel delivery compared to older fuel injection systems. Hybrid electric vehicles combine an internal combustion engine with electric motors and batteries to improve fuel efficiency. Variable geometry turbochargers, NOx absorbers, and electronic engine management systems also help improve engine performance and reduce emissions.
Ch-3: Measurement of screw thread and gearSuraj Shukla
The document discusses measurement of screw thread elements. It begins by defining key screw thread terminology such as external thread, internal thread, pitch, lead, etc. It then describes various methods for measuring the major diameter, minor diameter, effective diameter (pitch diameter), and pitch of external screw threads. Methods discussed include using a micrometer, V-pieces, taper parallels, and wires/rods. The goal is to measure the critical geometric aspects that ensure interchangeability of threaded fasteners.
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.
This document discusses screw threads and methods for measuring their key parameters. It defines screw threads as helical ridges on cylinders or cones that allow rotational motion. Threads are classified as external or internal, right-handed or left-handed, single-start or multi-start. Common thread forms include Vee threads and transmission threads. Parameters like major diameter, minor diameter, pitch, and angle are measured using instruments like micrometers, parallels, and wires. Errors in threads can occur due to issues in manufacturing and include progressive, periodic, drunken, and irregular errors.
The document discusses different aspects of screw thread metrology. It describes the key elements of a screw thread such as major diameter, minor diameter, pitch diameter, pitch, lead, crest, root, depth of thread, flank, and angle of thread. It then discusses different forms of screw threads including British Standard Whitworth, British Association, American National Standard, Unified Standard, square, Acme, knuckle, and buttress threads. The final sections cover various methods for measuring elements of a screw thread such as major diameter, minor diameter, pitch diameter, pitch, and thread angle using instruments like micrometers, thread micrometers, pitch measuring machines, and tool makers microscopes.
The document discusses measurement and metrology of screw threads. It begins with definitions of screw thread terminology such as major diameter, minor diameter, pitch, angle, and forms of threads. It then describes methods for measuring the major diameter, minor diameter, effective diameter, and pitch of screw threads. The key measurement methods discussed are using micrometers, pitch gauges, and a tool maker's microscope. The goal is to understand principles and techniques for measuring characteristics of screw threads.
This document discusses screw threads, including their classification, measurement, and sources of errors. It defines a screw thread as a helical ridge on the external or internal surface of a cylinder or cone. Threads are classified by their location (external or internal) and direction of rotation (right-handed or left-handed). Methods to measure the major diameter, effective diameter, and pitch are described using instruments like micrometers and wires. Sources of errors in threads include issues with the major diameter, minor diameter, pitch, and form that can lead to interference or lack of contact between threads.
This document provides an overview of the Mechanical Measurement and Metrology subject for B.Tech Mechanical Engineering students. The objectives are to develop knowledge of measurement basics, methods, and devices. Key topics covered include linear, angular, thread and gear measurement, as well as force, torque, pressure, temperature and strain measurement. Specific techniques discussed include thread measurement methods using wires, gear metrology, and advancements like coordinate measuring machines and machine vision systems. Measurement of screw thread elements like diameter, pitch, and errors are explained in detail.
This document provides information on measuring various geometric features of screw threads and gears. It discusses measuring the major diameter, minor diameter, pitch, and other elements of threads using instruments like micrometers, thread gauges, and comparators. For gears, it describes measuring runout, pitch, profile, backlash, tooth thickness, and alignment using devices like dial indicators, involute measuring machines, and angular measurement techniques. The document also defines common terminology for screw thread and gear geometry.
This document defines screw thread terminology and describes methods for measuring screw thread features. It discusses thread elements such as major diameter, minor diameter, pitch diameter. It also explains different thread types and gauging methods used to check threads, including plug gauges, ring gauges, and micrometers. Measurement of pitch, form, and angle is described along with causes and measurement of pitch errors. Tolerances for screw threads based on ISO standards are also provided.
This document discusses various linear measurement instruments categorized as either non-precision or precision tools. Non-precision tools like steel rules and calipers provide measurements to the nearest line on the tool. Precision tools like vernier calipers, micrometers, and slip gauges provide highly accurate measurements. The document describes the parts and operating principles of vernier calipers, micrometers, height gauges, and slip gauges. It also provides formulas for calculating measurements and measurement errors using these precision tools.
The document discusses methods for measuring elements of internal screw threads, including major diameter, minor diameter, effective diameter, and pitch. It describes using tools like horizontal comparators, micrometers, taper parallels, slip gauges, and rollers to measure diameters. Effective diameter can be measured using ball-ended styli in a thread measuring machine. Pitch is measured using an adapter in a pitch measuring machine. The document also covers plug gauge types for internal threads and common errors in threads like errors in diameters, thread angle, and pitch.
This document provides information on measuring various geometric properties of screws, gears, and surfaces. It discusses measuring the thread properties like major diameter, minor diameter, pitch, and flank angle using tools like micrometers, thread gauges, and optical projectors. Gear measurement techniques are described for properties such as runout, pitch, profile, backlash, and tooth thickness. Methods for measuring radii, roundness, flatness, and surface finish are also summarized. The document aims to outline the different measurement techniques and terminology used for dimensional inspection of screws, gears, and surface geometry.
This document discusses various methods for measuring threads, including both external and internal threads. It describes using micrometers, thread gauges, and thread micrometers to measure the major diameter, minor diameter, pitch, angle, and form of threads. Specific thread measurement techniques are outlined, such as using GO and NO-GO plug gauges to check internal thread size limits. Measurement of thread elements includes the major diameter, minor diameter, effective diameter, and pitch. Instruments like screw thread micrometers and limit thread gauges are used to directly measure the pitch and check threads against pre-determined size limits.
This document discusses screw thread measurement and terminology. It defines a screw thread as a helical ridge on a cylinder or cone used to hold parts together or transmit motion. There are external and internal threads. Key terms are defined such as pitch, diameter, flank, and angle. Methods to measure major diameter, minor diameter, and effective diameter are described using instruments like micrometers and thread gauges. Sources of errors in threads are also outlined.
This document discusses the terminology and measurement of screw threads. It defines various elements of screw threads including the crest, root, flanks, pitch, and angle of the thread. It describes different types of errors that can occur in screw threads such as progressive, periodic, and drunken pitch errors. It also explains how to measure the major diameter using a bench micrometer or hand microscope by taking readings on a calibrated cylinder for accuracy. The minor diameter is measured using V-pieces that contact the root of the thread.
This document describes several common measuring instruments, including metre rules, measuring tapes, vernier callipers, and screw gauges. It explains what each instrument is used for and provides details on their construction and how measurements are taken. For example, it states that metre rules measure length using centimetre and millimetre markings, while vernier callipers can measure internal and external diameters using a main scale and movable vernier scale that has a least count of 0.1 mm. The document also discusses zero error and how to apply corrections.
This presentation by Hooria Shahzad is about measuring instruments in which we study metre rule, measuring tape, vernier callipers and screw gauge ; construction of vernier callipers and screw gauge.
This document discusses the measurement of screw threads. It defines various screw thread terminology such as crest, root, flank, pitch, and angle of thread. It describes common types of pitch errors in screw threads such as progressive, periodic, and drunken threads. It also outlines various methods for measuring important screw thread dimensions like major diameter, minor diameter, and effective diameter. These include using a bench micrometer, thread micrometer, and two-wire method. Accurately measuring thread features is important for evaluating thread quality and fit.
The document provides an overview of theory of machines and machine elements design. It discusses kinematics, which is the study of motion without considering forces. Kinematics of machines deals with the relative motion between machine parts through displacement, velocity and acceleration. A mechanism is defined as part of a machine that transmits motion and power from input to output. Key concepts discussed include links, kinematic pairs, degrees of freedom, and inversions of mechanisms. Common mechanisms like slider crank chains and their inversions are presented. The document also discusses straight line motion generators, intermittent motion mechanisms, and mechanical advantage in mechanisms.
Homogeneous charge compression ignition (HCCI) engines and stratified charge engines are recent engine technologies that allow for lean combustion. HCCI engines use autoignition of a premixed fuel-air mixture, while stratified charge engines directly inject fuel near the spark plug. Common rail direct injection diesel engines and gasoline direct injection engines provide more precise fuel delivery compared to older fuel injection systems. Hybrid electric vehicles combine an internal combustion engine with electric motors and batteries to improve fuel efficiency. Variable geometry turbochargers, NOx absorbers, and electronic engine management systems also help improve engine performance and reduce emissions.
The document discusses various alternative fuels to gasoline and diesel, including alcohols (methanol and ethanol), vegetable oils, biodiesel, natural gas, liquefied petroleum gas, and hydrogen. It describes the need for alternate fuels, production methods of different fuels, advantages and disadvantages, and usage in spark ignition and compression ignition engines. Specific focus is given to the properties and use of methanol, ethanol, vegetable oils, biodiesel, compressed natural gas, and liquefied natural gas as potential fuel alternatives.
The document discusses the curriculum for a course on advanced internal combustion engines. It covers 5 units: spark ignition engines, compression ignition engines, emission formation and control, alternate fuels, and recent trends. Unit 3 specifically focuses on the formation of emissions like NOx, CO, HC and particulate matter from diesel and gasoline engines. It also discusses emission control methods like catalytic converters, particulate traps, and exhaust gas recirculation that are used to reduce these emissions. Emission measurement equipment like non-dispersive infrared analyzers and flame ionization detectors are also introduced.
The document discusses compression ignition engines, including the stages of combustion in diesel engines, factors that affect knocking, different injection systems and combustion chamber types, turbocharging, and an introduction to analyzing the thermodynamics of the combustion process in CI engines.
The document provides an overview of internal combustion engines. It discusses the history and invention of the engine by Nikolas Otto in 1876. It defines engines as devices that convert heat energy from fuel combustion into mechanical energy. Engines are classified based on factors like the number of strokes, fuel used, working cycle, design, ignition method, and application. The major parts of an IC engine are described along with diagrams. The working principles of two-stroke and four-stroke engines, petrol engines, diesel engines, and the differences between engine types are explained over multiple pages.
This document discusses advances in metrology, specifically laser metrology and interferometry. It begins by explaining the principles and components of lasers and how they are used for precision measurement. Examples of laser measuring machines described include laser telemetric systems, laser and LED distance measuring instruments, scanning laser gauges, and laser interferometers. Interferometry uses laser beams to perform highly accurate linear and angular measurements. Coordinate measuring machines and digital devices for computer-aided inspection are also summarized.
The document discusses different methods for measuring mechanical parameters such as torque, temperature, and force. It describes techniques like bimetallic strips, thermocouples, pyrometers, and resistance temperature detectors for temperature measurement. For torque measurement, it mentions the Prony brake arrangement. It also outlines load cells and different types of dynamometers for measuring force and dynamic force.
1. The document discusses the syllabus for the course 20ME601 - Metrology and Measurements.
2. The syllabus is divided into 5 units which cover topics like basics of metrology, linear and angular measurements, form measurement, measurement of mechanical parameters, and advances in metrology including laser interferometers, CMM, and machine vision systems.
3. Key aspects of metrology discussed include measurement systems, standards, measurement methods and types of instruments, factors affecting accuracy and precision, and different types of errors in measurement.
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
Low power architecture of logic gates using adiabatic techniquesnooriasukmaningtyas
The growing significance of portable systems to limit power consumption in ultra-large-scale-integration chips of very high density, has recently led to rapid and inventive progresses in low-power design. The most effective technique is adiabatic logic circuit design in energy-efficient hardware. This paper presents two adiabatic approaches for the design of low power circuits, modified positive feedback adiabatic logic (modified PFAL) and the other is direct current diode based positive feedback adiabatic logic (DC-DB PFAL). Logic gates are the preliminary components in any digital circuit design. By improving the performance of basic gates, one can improvise the whole system performance. In this paper proposed circuit design of the low power architecture of OR/NOR, AND/NAND, and XOR/XNOR gates are presented using the said approaches and their results are analyzed for powerdissipation, delay, power-delay-product and rise time and compared with the other adiabatic techniques along with the conventional complementary metal oxide semiconductor (CMOS) designs reported in the literature. It has been found that the designs with DC-DB PFAL technique outperform with the percentage improvement of 65% for NOR gate and 7% for NAND gate and 34% for XNOR gate over the modified PFAL techniques at 10 MHz respectively.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapte...University of Maribor
Slides from talk presenting:
Aleš Zamuda: Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapter and Networking.
Presentation at IcETRAN 2024 session:
"Inter-Society Networking Panel GRSS/MTT-S/CIS
Panel Session: Promoting Connection and Cooperation"
IEEE Slovenia GRSS
IEEE Serbia and Montenegro MTT-S
IEEE Slovenia CIS
11TH INTERNATIONAL CONFERENCE ON ELECTRICAL, ELECTRONIC AND COMPUTING ENGINEERING
3-6 June 2024, Niš, Serbia
A review on techniques and modelling methodologies used for checking electrom...nooriasukmaningtyas
The proper function of the integrated circuit (IC) in an inhibiting electromagnetic environment has always been a serious concern throughout the decades of revolution in the world of electronics, from disjunct devices to today’s integrated circuit technology, where billions of transistors are combined on a single chip. The automotive industry and smart vehicles in particular, are confronting design issues such as being prone to electromagnetic interference (EMI). Electronic control devices calculate incorrect outputs because of EMI and sensors give misleading values which can prove fatal in case of automotives. In this paper, the authors have non exhaustively tried to review research work concerned with the investigation of EMI in ICs and prediction of this EMI using various modelling methodologies and measurement setups.
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.
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.
6th International Conference on Machine Learning & Applications (CMLA 2024)ClaraZara1
6th International Conference on Machine Learning & Applications (CMLA 2024) will provide an excellent international forum for sharing knowledge and results in theory, methodology and applications of on Machine Learning & Applications.
2. Thread Measurement: Terminologies, Errors - External Thread Measurement:
Pitch Gauge, Tool Maker's microscope, Floating Carriage micrometer with One,
Two and Three wires - Internal Thread Measurement: Taper Parallels and Rollers
method.
Gear Measurement: Terminologies, Errors, Gear Tooth Vernier caliper, Profile
Projector, Base pitch measuring instrument, David Brown Tangent Comparator,
Involutes tester, Parkinson Gear Tester, External and Internal Radius
measurements
Roundness measurement: Circumferential confining gauge, Assessment using V
block and Rotating centres.
3. • Introduction:
• Screw threads are used to transmit power and motion and also used to fasten two components
with the help of nuts, bolts and studs.
• The screw threads are mainly classified into: 1) External Screw Threads 2) Internal Screw
Threads.
Screw Thread Measurement
External Screw Threads Internal Screw Threads
5. 1. Screw Thread: It is a continuous helical groove of specified cross-section produced on the
external or internal surface.
2. Crest: It is the top surface joining two sides of thread.
3. Root: The bottom of the groove between the two flanks of the thread.
4. Flank: It is the surface between crest and root or it is the thread surface that connects crest with
root.
5. Lead: The distance a screw thread advances in one turn. For a single start threads, lead=pitch,
For double start, lead=2xpitch, & so on.
6.Pitch: The distance from a point on a screw thread to a corresponding point on the next thread
measured parallel to the axis.
7. Helix Angle: The angle made by the helix of the thread at the pitch line with the axis is called
as helix angle.
8. Flank angle: It is half the included angle of the thread or angle made by the flank of the thread
with the perpendicular to the thread axis.
6. 9. Depth of thread: It is the distance between crest and root measured perpendicular to axis of
screw.
10. Angle of thread: It is the angle included between the flanks of a thread measured in an axial
plane.
11. Major Diameter: This is the diameter of an imaginary cylinder, co-axial with the screw,
which just touches the crests of an external thread or roots of an internal threads. It is also
called as ‘Nominal diameter’.
12. Minor diameter: This is the diameter of an imaginary cylinder, co-axial with the screw which
just touches the roots of an external thread or the crest of an internal thread. This is also
referred to as ‘root’or ‘core diameter’.
13. Effective diameter or Pitch diameter: It is the diameter of an imaginary cylinder coaxial
with the axis of the thread and intersects the flanks of the thread such that width of the threads
& width of spaces between threads are equal.
14. Addendum: It is the distance between the crest and the pitch line measured perpendicular to
axis of the screw.
15. Dedendum: It is the distance between the pitch line & the root measured perpendicular to
axis of the screw.
7. Tofind out the accuracy of a screw thread it will be necessary to measure the following:
1. Measurement of Major diameter:
a. Ordinary micrometer b. Bench micrometer.
2. Measurement of Minor diameter:
a. Using taper Parallels b. Using rollers
3. Measurement of Effective diameter:
a. One wire method b. Two wire method c. Three wire method d. Using Thread MM
4. Measurement of Pitch:
a. Pitch Measuring Machine b. Tool Makers Microscope c. Screw Pitch Gauge
5. Thread angle and form
Measurement of various elements in Screw Threads
8. 1. Measurement of Major diameter
Measurement Processes
a. Ordinary micrometer
b. Bench micrometer
i) Ordinary Micrometer:
• In this the micrometer is used as a comparator.
• This micrometer is first set over the cylinder standard having approx. same dimension.
• This standard is called setting gauge.
9. After taking this reading ‘R1’the micrometer is set on the major diameter of the thread, and
the new reading is ‘R2’and then the diameter is measured by following equation:.
Then the major diameter, D=S ± (R1 - R2)
S = Size of setting gauge
R1 = Micrometer reading over setting gauge.
R2 = Micrometer reading over thread.
• This micrometer is used gently during reading because their might come error by
applying extra force which will form deformation of crest of the thread
10. ii) Measurement by Bench micrometer:
• Bench micrometer is designed by the NPL to remove
deficiencies inherent in the hand micrometer.
• In this the fiducial micrometer is used to ensure that all the
readings are taken at the same pressure.
• The instrument has a micrometer head having Vernier scale
to read to the accuracy of 0.002mm.
• This instrument is also used as the comparator to avoid the
pitch errors of micrometer threads, zero error setting etc.
• Then the process is same as of the ordinary micrometer.
Calibrated setting cylinder having the same diameter as the
major diameter of the thread to be measured is used as
setting standard.
• After setting the standard, the setting cylinder is held
between the anvils and the reading is taken.
• Then the cylinder is replaced by the threaded work piece
and the new reading is taken.
11. 2. Measurement of Minor diameter
Minor diameter is the imaginary diameter of thread which
would touch the roots of the external and crest of the
internal threads.
For measuring minor diameter of external
following methods are used:
1. Two V pieces method
2. By projecting the thread on the screen
threads
For measuring minor diameter of internal thread following
methods are used:
1. Using taper parallels
2. By using rollers and slip gauges
12. V pieces method
• The minor diameter is measured by a comparative method by using floating carriage
diameter measuring machine and small ‘V’ pieces which make contact with the root of
the thread.
• These V pieces are made in several sizes, having suitable radii at the edges. V pieces are
made of hardened steel.
• The floating carriage diameter-measuring machine is a bench micrometer mounted on a
carriage.
13. Measurement Process:
• The threaded work piece is mounted between the centres of the instrument and the V
pieces are placed on each side of the work piece and then the reading is noted.
• After taking this reading the work piece is then replaced
cylindrical setting gauge.
• The minor diameter of the thread = D ± (R2 –R1)
• Where, D = Diameter of cylindrical gauge
by a standard reference
R2 = Micrometer reading on threaded workpiece,
R1 = Micrometer reading on cylindrical gauge.
14. • If the threads are very sharp or have no radius at the
root.
• The measurement of minor diameter is done by
projecting the thread form on a screen.
• This projected form is compared with the use of the
Tool Makers Microscope.
By projecting thread on screen
15. For measuring minor diameter of internal thread:
a. Using taper Parallels b. Using rollers
Using taper Parallels
• For the internal thread of the minor diameter of
diameter less than 200mm is measured using the
taper parallels.
• The taper parallels are the pairs of the wedges having
parallel outer edges.
• The taper parallels are inserted inside the thread and
adjusted until firm contact is not established with the
minor diameter.
• Then the diameter of the outer edges of the taper
parallels is measured using the micrometer.
16. 2. Using Rollers:
• For more than 200mm diameter this method is used.
• Precision rollers are inserted inside the thread and
proper slip gauge is inserted between the rollers.
• The minor diameter is then the length of slip gauges
plus twice the diameter of roller.
17. • Effective diameter is the imaginary diameter in between major
and minor diameter.
• The effective diameter measurement is carried out by the following
methods.
1. Wire Methods
2. Thread Micrometer
3. Measurement of Effective diameter
18. 3. Measurement of Effective diameter – Wire Method
•The effective diameter measurement is carried out by the following methods.
1. One Wire Method 2. Two Wires Method 3. Three Wires Method
• This methods are based on the size of the wire.
• The size of the wire whose diameter makes the contact with the
flank of the thread on the effective diameter this size of wire
is known as Best Size of Wire.
• This size is decided by the following equation:
Where p= pitch and θ= thread angle
19. • In this method, only one wire is used. The wire is placed
between the two threads at one side and on the other side the
anvil of the measuring micrometer contacts the crests.
• First, the micrometer reading ‘d1’ is noted on a standard gauge
whose dimension is approximately same to be obtained by this
method.
• Now, the setting gauge is replaced by thread and the new
reading is taken i.e. ‘d2’then effective diameter D = S± (d1-d2).
Where, S = Size of setting gauge.
• Actual measurement over wire on one side and threads on
other side = size of gauge ± difference in two micrometer
readings.
One Wire Method
20. The effective diameter can not be measured directly but
can be calculated from the measurements made.
In this method, wires of exactly known diameters are
chosen such that they contact the flanks at their straight
portions.
If the size of the wire is such it contacts the flanks at the
pitch line, it is called the ‘best size’ of wire which can be
determined by geometry of screw thread.
The screw thread is mounted between the centers &
wires are placed in the grooves and reading M is taken.
Two Wire Method
21. Measuring Process
Effective diameter E is calculated by E = T + P
Where, T = Dimension under the wires = M - 2d
M = Dimension over the wires
d = Diameter of each wire
P = Compensating factor should be added to T value and it
depends on diameter of wire, pitch & angle of the screwthread.
Here, The diameter under the wires ‘T’can also be determined by,
T= S - (R1 – R2)
Where, S = The diameter of the standard.
R1 = Micrometer reading over standard andwires.
R2 = Micrometer reading over screw thread andwires
P= 0.866 p - d => For metric thread.
P= 0.9605 p - 1.1657 d => For Whitworththread.
Where, p= Pitch
22. The three-wire method is the accurate method.
In this method, three wires of equal and precise diameter are placed in the grooves at
opposite sides of the screw.
In this, one wire on one side and two on the other side are used.
The wires either may be held in hand or hung from a stand. This method ensures the
alignment of micrometer anvil faces parallel to the thread axis.
Three Wire Method
23. Case i) In case of Whitworth Thread:
M = D + 3.1657d – 1.6p
where, D = Outside Diameter
Case ii) In case of Metric Thread:
M = D + 3d – 1.5155p
We can practically measure the value of M & then compare with the theoretical values
using the formula derived above. After finding the correct value of M, as d is known, E
can be found out.
24. Best Size Wire:
Best size wire is one in which, the wire is having such a diameter that it makes contact
with the flanks of the thread on the effective diameter or pitch line.
It is recommended that for measuring the effective diameter, always the best size wire
should be used and for this condition the wire touches the flank at mean diameter line
within ±1/5 of flank length.
25. Effective Diameter Measurement
This method is simple and rapid.
The thread micrometer is same as ordinary micrometer except that it
has special contact points to suit the end screw threads form that is to
be checked.
The contact points are selected on the basis of the types of the thread
and the pitch of the thread to be measured.
Then the anvils are then made to contact the thread to be checked and
the reading is taken, which will give the pitch diameter or effective
diameter.
In this the actual reading is the
measurement of the major diameter on one side and minor diameter of
the other side which gives us the effective diameter.
If the thread is of the whithworth thread the relation between the outer
diameter and the pitch is as follow: E = 𝐷 − 0.6403𝑝
Thread Micrometer
26. i) Pitch Measuring Machine:
The principle of this method of measurement is to move the stylus
along the screen parallel to the axis from one space to the next.
The pitch-measuring machine provides a relatively simple and
accurate method of measuring the pitch.
Initially, the micrometer reading is set near the zero on the scale.
Spring loaded head permits the stylus to move up the flank of the
thread and down into the next space as it is moved along.
Accurate positioning of the stylus between the two flanks is
obtained by ensuring that the pointer T is always opposite to its
index mark when readings are taken.
When the pointer is accurately placed in position, the micrometer
reading is noted.
The stylus is then moved along into the next thread space, by
rotation of the micrometer, and a second reading taken.
The difference between the two readings is the pitch of the thread.
Readings are taken in this manner until the whole length of the
screw thread has been covered.
4. Pitch Measurement
27. ii.Tool Makers Microscope:
• Worktable is placed on the base of the instrument.
• The optical head is mounted on a vertical column it can be
moved up and down.
• Work piece is mounted on a glass plate.
• A light source provides horizontal beam of light which is
reflected from a mirror by 90 degree upwards towards the
table.
• Image of the outline of contour of the work piece passes
through the objective of the optical head.
• The image is projected by a system of three prisms to a ground
glass screen.
• The measurements are made by means of cross lines engraved
on the ground glass screen.
• The screen can be rotated through 360°.
• Different types of graduated screens and eyepieces are used.
28. Applications:
1. Linear measurements.
2. Measurement of pitch of the screw.
3. Measurement of pitch diameter.
4. Measurement of thread angle.
5. Comparing thread forms.
6. Centre to center distance measurement.
29. iii. Screw pitch gauge:
• It is used to directly compare the pitch by just selecting the proper pitch value entered in
the pitch gauge and comparing it with the actual screw thread.
30. 5. Flank Angle and Thread form Measurement
Flank angle
•Flank Angle is the angle formed by a flank and a perpendicular
to the thread axis in an axial plane.
•It is also called the half thread angle.
•For this measurement we have to measure the thread angle.
•To measure the thread angle the following methods is used:
1. Optical Projection
31. 5. Thread form and flank angle Measurement
Thread form
The ideal and actual forms are compared for the measurement.
Types of thread gauges are,
1. Plug Screw Gauge 2. Ring Screw Gauge 3. Caliper Screw Gauge
32. The error in screw thread may arise during the manufacturing or storage of threads. The error either
may cause due to the following six main elements in the thread.
2. Minor diameter error
5. Flank angles error
3. Effective diameter error
6. Crest and root error
1. Major diameter error
4. Pitch error
1. Major diameter error
It may cause reduction in the flank contact and interference with the matching threads.
2. Minor diameter error
It may cause interference, reduction of flank contact.
3. Effective diameter error
If the effective diameter is small the threads will be thin on the external screw and thick on an
internal screw.
4. Pitch error
Pitch error is defined as the total length of thread engaged either too high or too small. The
various pitch errors may be classified into
1. Progressive error 2. Periodic error. 3. Drunken error 4. Irregular error.
Errors in Screw Threads
33. This error occurs
i) Progressive Pitch error:
The pitch of the thread is uniform but is longer or shorter its nominal value and this is called
progressive error. This error occurs whenever the tool–work velocity ratio is incorrect but
constant.
Causes of Progressive error:
1. Incorrect linear and angular velocity ratio.
2. Incorrect gear train and lead screw.
3. Saddle fault.
4. Variation in length due to hardening.
ii) Periodic Pitch error:
In this the pitch error causes the errors to repeat at certain time of interval.
when the tool–work velocity ratio is not constant.
Causes of Periodic error:
1. Un-uniform tool work velocity ratio.
2. Teeth error in gears.
3. Lead screw error.
4. Eccentric mounting of the gears.
34. (iii) Drunken error:
It is error due to the irregular form of helical groove on a cylindrical
surface. In this case pitch measured parallel to the axis is always same,
but problem is with the thread is not cut to its true helix.
Due to this flank surface will not be as a straight edge, it will be as
curved form.
(iv) Irregular error:
These are the errors randomly take place on threads without any specific reason.
Causes of Irregular error:
1. Machine fault.
2. Non-uniformity in the material.
3. Cutting action is not correct.
4. Machining disturbances.
Effect of pitch error:
1. It increases the effective diameter of the bolt and decreases the diameter of nut.
2. The functional diameter of the nut will be less.
3. It reduces the clearance.
4. It increases the interference between mating threads.
35. • Gears are mechanical drives which transmit power through toothed wheel.
• In this gear drive, the driving wheel is in direct contact with driven wheel.
• The accuracy of gearing is very important factor when gears are manufactured.
• The transmission efficiency is almost 99% for gears.
• So, it is very important to test and measure the gears precisely.
• For proper inspection of gear, it is very important to concentrate on the raw materials, which
are used to manufacture the gears.
• Also very important to check the machining of the blanks, heat treatment and finishing of
teeth.
• The gear blanks should be tested for dimensional accuracy and tooth thickness for the forms of
gears.
Gear Measurements
36. The most commonly used forms of gear teeth are
1.Involute 2.Cycloidal
The involute gears also called as straight tooth or spur gears.
The cycloidal gears are used in heavy and impact loads.
The involute rack has straight teeth.
The involute pressure angle is either 20̊ or 14.5
Types of Gears
1.Spur gear
Cylindrical gear whose tooth traces is straight line.
These are used for transmitting power between parallel-shafts.
2.Spiral gear
The tooth of the gear traces is in the form of curved lines.
37. 3. Helical gears
These gears are used to transmit the power between parallel shafts as well as non-parallel and non-
intersecting shafts. It is a cylindrical gear whose tooth traces is straight line.
4. Bevel gears
The tooth traces are straight-line generators of cone. The teeth are cut onthe conical surface. It is
used to connect the shafts at right angles.
5. Worm and Worm wheel
It is used to connect the shafts whose axes are non-parallel and non-intersecting.
6. Rack and Pinion
Rack gears are straight spur gears with infinite radius.
39. 1. Tooth Profile: It is the shape of any side of gear tooth in its cross section.
2.Base circle: It is the circle of gear from which the involute profile is derived. Base circle diameter =
Pitch circle diameter x Cosine of pressure angle of gear
3. Pitch circle diameter (PCD): It is the diameter of a circle which will produce the same motion as the
toothed gear wheel.
4.Pitch circle: It is the imaginary circle of gear that rolls without slipping over the circle of its mating
gear.
5. Addendum circle: The circle that coincides with the crests (or) tops of teeth.
6. Dedendum circle (or) Root circle: This circle that coincides with the roots (or) bottom of teeth.
7. Pressure angle (α): It is the angle made by the line of action with the common tangent to the pitch
circles of mating gears.
𝑑
8. Module (m): It is the ratio of pitch circle diameter to the total number of teeth. m =
Where, d = Pitch circle diameter, n =Number of teeth.
𝑛
Spur Gear Terminology
40. 9. Circular pitch: It is the distance along the pitch circle between corresponding points of
adjacent teeth.
c 𝑛
P = 𝜋𝑑
= 𝜋m
10. Diametral pitch (Pd): Number of teeth per inch of the PCD.
d 𝑑 𝑚
P = 𝑛
= 1
Where, m = Module
11. Addendum: It is the radial distance between tip circle and pitch circle.
Addendum value = 1 module.
11. Dedendum: It is the radial distance between pitch circle and root circle.
Dedendum value=1.25 module.
13. Clearance(c): The distance covered by the tip of one gear with the root of mating gear.
Clearance = Difference between Dedendum and addendum values.
14. Blank diameter: It is the diameter of the blank upto outer periphery.
Blank diameter = PCD+2m
41. 9. Face: It is the part of the tooth in the axial plane lying between tip circle and pitch circle.
10. Flank: It is the part of the tooth lying between pitch circle and root circle.
11. Helix angle: It is the angle between the tangents to helix angle.
12. Top land: Top surface of a tooth is called as top land.
13.Lead angle: It is the angle between the tangent to the helix and plane perpendicular to the axis
of cylinder.
14. Backlash: It is the difference between the tooth thickness and the space into which it meshes.
If we assume the tooth thickness as ‘t1 ’and width ‘t2 ’then
42. 1. Profile error: The maximum distance is at any point on the tooth profile form to the design
profile.
2. Pitch error: It is the difference between actual and design pitch.
3. Cyclic error: Error occurs in each revolution of gear.
4.Run out: Total range of a fixed indicator with, the contact points applied to a surface rotated,
without axial movement, about a fixed axis.
5. Eccentricity: It is the half radial run out.
6. Wobble: Run out is measured parallel to the axis of rotation at a specified distance from the
axis.
7. Radial run out: Run out is measured along a perpendicular to the axis of rotation.
8. Undulation: It is the periodical departure of the actual tooth surface from the design surface.
9. Axial run out: Run out is measured parallel to the axis of rotation at a speed.
10. Periodic error: Error occurs at regular intervals.
Errors in Gear
43. The inspection of the gears consists of the following elements in which manufacturing error
may be present.
1. Runout
2. Pitch
3. Profile
4. Lead
5. Backlash
6. Tooth thickness
Spur Gear Measurement
44. 1. Measurement of Runout
• the run out is an amount a gear moves in and out away
from it true centre as it is rotated.
• If runout is excessive, the gear wobbles as it rotates.
Runout is also the eccentricity in the pitch circle of gear.
• Gears that are eccentric tend to have vibration per
revolution.
• It may cause an abrupt gear failure.
• The gear is held on a mandrel in the centers and the dial
indicator of the tester holds a special tip descending
upon the module of gear being tested.
• The tip is inserted between the tooth spaces and dial
indicator reading is noted.
• The gear is rotated tooth by tooth and dial readings are
recorded the maximum variation is noted from the dial
indicator reading and that gives the run out of the gear
45. Pitch is the distance between corresponding points on equally spaced and adjacent teeth. Pitch
error is the difference in distance between equally spaced adjacent teeth and the measured distance
between any two adjacent teeth.
There are two ways for measuring the pitch.
a) Point to point measurement (i.e. One tooth point to next tooth point)
b) Direct angular measurement
2. Measurement of Pitch
46. a) Tooth to Tooth measurement:
The instrument has three tips. One is fixed measuring
tip and the second is sensitive tip, whose position can
be adjusted by a screw and the third tip is adjustable or
guide stop. The distance between the fixed and
sensitive tip is equivalent to base pitch of the gear. All
the three tips are made in contact with the tooth by
setting the instrument and the reading on the dial
indicator is the error in the base pitch.
b) DirectAngular Measurement:
It is the simplest method for measuring the error by
using set dial gauge against a tooth. In this method, the
position of a suitable point on a tooth is measured after
the gear has been indexed by a suitable angle. If the
gear is not indexed through the angular pitch the
reading differs from the original reading. This
difference is the cumulative pitch error.
2. Measurement of Pitch
47. i. Optical projection method:
The profile of the gear is projected on the
screen by optical lens and then the projected
value is compared with master profile.
ii. Involute measuring machine:
In this method, the gear is held on a mandrel
and circular disc of same diameter as the base
circle of gear for the measurement is fixed on
the mandrel. After fixing the gear on the
mandrel, the straight edge of the instrument is
brought in contact with the base circle of the
disc. Now, the gear and disc are rotated and the
edge moves over the disc without slip. The
stylus moves over the tooth profile and the error
is indicated on the dial gauge.
3. Measurement of Profile
48. Tooth thickness is generally measured at pitch circle and also in most cases the chordal thickness
measurement is carried out .i.e. the chord joining the intersection of the tooth profile with the pitch
circle. The methods which are used for measuring.
The gear tooth thickness are
a) Gear tooth Vernier caliper method
b)Constant chord method
c)Base tangent method
d) Measurement over pins or ball
6. Measurement of Tooth Thickness
49. It is used to measure the thickness of gear teeth at the pitch line or
chordal thickness of teeth and the distance from the top of a tooth to
the chord.
The tooth vernier caliper consists of vernier scale and two
perpendicular arms. In the two perpendicular arms one arm is used
to measure the thickness and other arm is used to measure the depth.
Horizontal vernier scale reading gives chordal thickness (W) and
vertical vernier scale gives the chordal addendum. Finally the two
values compared.
This method is simple and inexpensive.
Disadvantages of Gear Tooth Vernier method:
1.Not closer to 0.05mm.
2.Two Vernier readings are required.
3.Measurement is done by edge of measuring jaw and not by face.
Gear tooth Thickness – Gear Tooth Vernier
50. • A constant chord is defined as, the chord, joining those points,
on opposite faces of the tooth, which make contact with the
mating teeth, when the center line of the tooth lies on the line
of the gear centers.
• Constant chord of a gear is measured where the tooth flanks
touch the flanks of the basic rack.
• The teeth of the rack are straight and inclined to their centre
lines at the pressure angle.
• Also the pitch line of the rack is tangential to the pitch circle
of the gear, the tooth thickness of the rack along this line is
equal to the arc tooth thickness of the gear round its pitch
circle.
• Now, since the gear tooth and rack space are in contact in the
symmetrical position at the points of contact of the flanks, the
chord is constant at this position irrespective of the gear of the
system in mesh with the rack.
Gear tooth Thickness – Constant Chord Method
51. Gear tooth Thickness – Base Tangent Method
• It is the most commonly used method for checking the tooth
thickness of gear.
• The advantage of this method is that, it depends only on one vernier
reading unlike gear tooth vernier Caliper where we require two
vernier readings.
• The base tangent length is the distance between the two parallel
planes which are tangential to the opposing tooth flanks.
• The measurements made across these opposed involutes by span
gauging will be constant and equal to the arc length of the base
circle between the origins of involutes.
• The value of the distance between two opposed involutes, or the
dimension over parallel faces is equal to the distance round the base
circle between the points where the corresponding tooth flanks.
52. • The master gear is fixed on vertical spindle and the gear to be
tested is fixed on similar spindle which is mounted on a carriage.
• The carriage which can slide both side and these gears are
maintained in mesh by spring pressure.
• When the gears are rotated, the movement of sliding carriage is
indicated by a dial indicator and these variations are the measure
of any irregularities in the gear under test.
• The variation's recorded in a recorder which is fitted in the form
of a waxed circular chart.
• In fig, the gears are fitted on the mandrels and are free to rotate
without clearance.
• Left mandrel moves along the table and the right mandrel moves
along the spring-loaded carriage.
• The two spindles can be adjusted so that the axial distance is
equal and a scale is attached to one side and vernier to the other,
this enables center distance to be measured to with in 0.025mm.
Parkinson Gear Tester – Gear profile inspection
53. • If errors occur in the tooth form when gears will be in closer mesh, pitch or concentricity of pitch
line will cause a variation in center distance from this movement of carriage as indicated to the
dial gauge will show the errors in the gear test.
• The recorder is also fitted in the form of circular or rectangular chart and the errors are recorded.
Limitations of Parkinson gear tester:
1.Accuracy ±0.001mm
2.Maximum gear diameter is 300mm
3.Errors are not clearly identified.
4.Measurement is dependent upon the master gear.
5.Low friction in the movement of the floating carriage.
54. • By definition, roundness or circularity is the radial uniformity of work surface measured from
the center line of the workpiece.
• Circularity is specified by circularity tolerance. For example, if it is specified that circularity of
a feature is to be 0.1mm, than it means that the circumference of each cross section of the
feature should be contained between two coplanar concentric circles that are 0.1mm apart.
• Error in roundness is defined as the radial distance between the minimum inscribing circle and
maximum inscribing circle, that contain the actual profile of the surface at a section
perpendicular to the axis of rotation.
Roundness Measurement
55. • Methods for Measuring Roundness:
a) V-block and dial indicator method
V-block and dial indicator method:
b) Roundness Measuring Machine
• The arrangement consists of a V-block that is placed on the surface plate. The workpiece to be
tested is placed in the V-groove of the V-block as shown in the figure.
• The feeler of a sensitive dial indicator (held firmly by a stand) is made to rest on the workpiece.
• Now the workpiece is rotated about the diameter to be checked. The dial indicator will indicate
variations in the dimensions caused due to out of roundness.
56. • Plotting a Polar Graph: An idea of the actual shape of the workpiece can be obtained by
plotting a polar graph. 12 equispaced markings at an angle of 30̊ are made in the face of the
workpiece to be measured. The workpiece is placed on the V-block.
• The dial indicator is made to touch the workpiece at its center. Now when the workpiece is
rotated and when the marking comes exactly under the plunger of the dial indicator, the reading
is noted.
• Hence 12 readings will be obtained. The procedure is repeated thrice to get average values for
each marking. Now for plotting the polar graph, a proper scale is selected.
• A circle of diameter equal to four times the maximum reading of the dial indicator is drawn.
Another concentric circle is drawn in this circle. The values of the dial indicator are plotted in
radial direction by taking the smallest circle as the reference circle. The individual points are
joined by straight lines to get the actual profile of the workpiece.
•
57. • Error is measured as the radial distance between the maximum and minimum inscribing circle
for the profile obtained.
Roundness error = 𝑀𝑒𝑎𝑠𝑢𝑟𝑒𝑑 𝑒𝑟𝑟𝑜𝑟 𝑓𝑟𝑜𝑚 𝑝𝑜𝑙𝑎𝑟 𝑔𝑟𝑎𝑝ℎ
𝐾
Where, K is a constant (This constant depends on the shape of the workpiece and angle of V-
block)
• The position of the indicating instrument, the number of lobes on the workpiece and the angle
of the V-block have an influence on the determination of roundness error.
58. Roundness Measuring Machine:
• The machine is also called as Taly-round Instrument or precision spindle method.
• The main parts of the instrument are a truly running spindle that is mounted on precision ball
bearing and micron indicator.
• The indicating pointer is rotated around the workpiece about an accurately stable axis. The
indicator shows deviations from roundness. As the output of the indicator is connected to an
amplifier unit and pen recorder, a polar graph of the out line of the workpiece is obtained.
• This is an accurate method. Automatic recording of the exact profile of the workpiece is
obtained. Waviness also is superimposed on the profile of the workpiece.
59. Cylindricity
A cylinder is an envelope of a rectangle
rotated about an axis. It is bound between
two circular and parallel planes.
Runout
Runout is a measure of the trueness of the
running of a body about its own axis.