DOCSLIB.ORG

Turning & Boring Tools

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Turning & Boring Tools Turning & Boring Tools Section B of 2017 Indexable Cutting Tools Turning and Boring Cutting Tools B-2 Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] Turning and Boring Operations Turning Operation O.D. Profile A machining process A machining process used to generate where a tool follows external, cylindrical an external contour Part Rotation forms by removing Part Rotation instead of following material, usually a straight path. with a single-point cutting tool. End Feed Cutting Cutting Direction End Feed Cutting Cutting Direction Facing Operation I.D. Profile The process of making A machining process a flat surface at the where a tool follows an end of a part. Part Rotation internal contour instead of following a straight path. Part Rotation Cutting Direction Cutting Direction End Feed Cutting End Feed Cutting Boring Operation Between Centers Work Part Rotation A machining process A machining process used to enlarge a where a work piece cylindrical hole, is held by using centers usually with a single-point Part Rotation on each end. It allows cutting tool (boring bar). the entire length of the outside diameter of the part to be machined in one continuous operation. Cutting Direction Cutting Direction End Feed Chamfering Operation Chuck Work Metal turning operation A machining process used to remove sharp where any type of edges from workpiece workpiece has to diameter. be held by a chuck. Part Rotation Part Rotation Cutting Direction End Feed Cutting End FeedCutting Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] B-3 Turning System "M" - Multi-Lock Toolholder System "T″ Cam-Lock Toolholder • Maximum rigidity • One locking action to secure the insert • Utilizes lock pin and clamp • Two second change over • Holds insert and seat secure for less vibration • Triangular negative turning insert Page B-8 - B-26 Page B-27 "W" - Wedge Lock Toolholder System "P" - Profile Toolholder System • Excellent locking ability • Easy to index insert • Easier to index or change insert without the lock pin • Uses special clamp for a • Allows for an optional chip breaker secure positive lock with more force to be placed on the insert Page B-28 Page B-28 "C" - Clamp-Lock Toolholder System "S" - Screw-Lock Toolholder System • Excellent locking ability • Easy to index insert • Easier to index or change insert without the lock pin • Uses Torx screw for a secure lock with more force • Allows for an optional chip breaker to be placed on the insert Page B-34 - B-55 Page B-29 - B-33 "D" - Dor Lock Toolholder System • Excellent locking ability Page B-56 - B-60 B-4 Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] Turning System "M" - Multi-Lock Toolholder System Spare Parts "T″ Cam-Lock Toolholder System Spare Parts Supplied Standard Optional "W" - Wedge Lock Toolholder System Spare Parts "P" - Profile Toolholder System Spare Parts "C" - Clamp-Lock Toolholder System Spare Parts "S" - ISO Screw-Lock Toolholder System Spare Parts "D" - Dor Lock Toolholder System Spare Parts Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] B-5 Toolholder Identification System C - 80° Diamond 3° A - Positive C - Clamp Lock B - Positive D - 55° Diamond 5° D - Dor-Lock 7° C - Positive R - Round N - Neutral 15° D - Positive M - Multi-Lock S - Square 20° E - Positive T - Triangle F - Positive P - Lever Lock 25° - Left Hand 30° G - Positive L W - 80° Trigon S - Screw Lock 0° N - Negative V - 35° Diamond 11° P - Positive W - Wedge Lock K - 55° Parallelogram T - Positive 10° R - Right Hand 1. Holding Method 2. Insert Geometry 4. Insert Clearance Angle 5. Hand of Tool 1 2 4 M C L N R 5 3 3. Tool Style A B C D E F G J K L M Side Cutting Side Cutting End Cutting Side Cutting Side Cutting End Cutting Side Cutting Side Cutting End Cutting Edge Angle Side Cutting Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Offset Edge Angle Straight Straight Straight Straight Straight Offset Offset Offset Offset Straight N O P Q R S T U V W Y Side Cutting Round Cutting Side Cutting Convex Radius Side Cutting Side Cutting Side Cutting End Cutting Side Cutting Side Cutting Side Cutting Edge Angle Edge Angle Edge Angle Cutting Edge Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Edge Angle Straight Straight Straight Offset Offset Offset Offset Offset Straight Offset Straight B-6 Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] Toolholder Identification System Expressed in 1/16" Increments A” ” expressed in 1/8" Increments Insert I.C. B” ” expressed in 1/4" Increments (Inscribed Circle): EX: 16 units (16 x 1/16") = 1" square Measures surface in 1/8" or 1/32" EX: 64 (6 x 1/8") & (4 x 1/4") = increments, 1 unit = 1/8" J 3 - 1/2" 1/2" square and below 3/4" x 1" EX: 4 units (4 x 1/8") = 1/2" A 4.0" will start with a 0. EX: 1/2” = 08 B 4 - 1/2" C 5.0" D 6.0" E 7.0" F 8.0" D A B A B Note: Old A.N.S.I. standards may apply for I.C.s under 1/4" (if > 1/4" I.C., 1 unit = 1/32") 6. Square Size 7. Rectangle Size 8. Insert Size I.C. 9. Length 7 7 8 9 6 1 6 4 D Inch 6 25 25 M 16 Metric 7 7 8 9 6. Square Size 7. Rectangle Size 9. Length 9. Insert Size B A B A M Cutting Edge Length shown in 1mm increments 16 D 60mm E 70mm F 80mm H 100mm Expressed in 1mm Increments Expressed in 1mm Increments K 125mm M 150mm EX: 2525 = EX: 3225 = P 170mm 25mm square 32mm height x 25mm width Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] B-7 Multi-Lock Toolholders MC - Style Toolholders Turning Application ( ) ARROWS SPECIFY CUTTING DIRECTION MCFN R/L Toolholder Style F - 0° End Cutting Edge Angle for negative 80° diamond CNM_ inserts For Dual Insert Styles * * ** * * **Optional *Supplied Standard Right Hand Shown, Left Hand Opposite. Inch UPC No. 733101- CNM_ Lock Clamp Optional Seat Description R.H. L.H. A B C E F Gage Insert Seat Pin Clamp Screw Screw MCFNR/L12-4B - 50011 0.75 0.75 4.50 1.250 1.000 MCFNR/L16-4C 50014 50015 1.00 1.00 5.00 1.250 1.250 432 ICSN-433 NL-46 CL-20 XNS-48 S-46 MCFNR/L16-4D 50018 50019 1.00 1.00 6.00 1.250 1.250 MCFNR/L16-5D 50022 50023 1.00 1.00 6.00 1.375 1.250 543 ICSN-533 NL-58 CL-12 XNS-510 S-58 MCFNR/L16-6D 50026 50027 1.00 1.00 6.00 1.500 1.250 643 ICSN-633 NL68 CL-9 XNS-510 S-68 For Turning inserts see pages A-62 - A-91. For spare parts see pages B-91-B-92. MCGN R/L Toolholder Style G- 0° Side Cutting Edge Angle for negative 80° diamond CNM_ inserts For Dual Insert Styles * * ** * * **Optional *Supplied Standard Right Hand Shown, Left Hand Opposite. Inch UPC No. 733101- CNM_ Lock Clamp Optional Seat Description R.H. L.H. A B C E F Gage Insert Seat Pin Clamp Screw Screw MCGNR/L12-4B 50036 50037 0.75 0.75 4.50 1.250 1.000 MCGNR/L16-4C - 50041 1.00 1.00 5.00 1.250 1.250 432 ICSN-433 NL-46 CL-20 XNS-48 S-46 MCGNR/L16-4D 50044 50045 1.00 1.00 6.00 1.250 1.250 MCGNR/L16-5D 50048 50049 1.00 1.00 6.00 1.375 1.250 543 ICSN-533 NL-58 CL-12 XNS-510 S-58 MCGNR/L16-6D - 50053 1.00 1.00 6.00 1.625 1.250 643 ICSN-633 NL-68 CL-12 XNS-510 S-68 MCGNR/L85-6D 50056 50057 1.00 1.25 6.00 1.625 1.250 For Turning inserts see pages A-62 - A-91. For spare parts see pages B-91-B-92. B-8 Call: 979-282-2861 Fax: 888-508-7055 Visit:www.doriantool.com E-mail:[email protected] Multi-Lock Toolholders MCKN R/L Toolholder Style K- 15° End Cutting Edge Angle for negative 80° diamond CNM_ inserts For Dual Insert Styles * * c ** * * **Optional *Supplied Standard Right Hand Shown, Left Hand Opposite. Inch UPC No. 733101- CNM_ Lock Clamp Optional Seat Description R.H. L.H. A B C E F U Gage Insert Seat Pin Clamp Screw Screw MCKNR/L12-4B 50066 50067 0.75 0.75 4.50 1.250 1.000 .123 MCKNR/L16-4C 50070 50071 1.00 1.00 5.00 1.250 1.250 .123 432 ICSN-433 NL-46 CL-20 XNS-48 S-46 MCKNR/L16-4D 50074 50075 1.00 1.00 6.00 1.250 1.250 .123 MCKNR/L20-4D 50078 50079 1.25 1.25 6.00 1.250 1.500 .123 MCKNR/L16-5D 50082 50083 1.00 1.00 6.00 1.375 1.250 .151 MCKNR/L20-5D 50086 50087 1.25 1.25 6.00 1.375 1.500 .151 543 ICSN-533 NL-58 CL-9 XNS-59 S-58 MCKNR/L85-5D 50090 50091 1.00 1.25 6.00 1.375 1.250 .151 MCKNR/L16-6D - 50095 1.00 1.00 6.00 1.500 1.250 .184 MCKNR/L20-6D 50098 50099 1.25 1.25 6.00 1.500 1.500 .184 643 ICSN-633 NL-68 CL-12 XNS-510 S-68 MCKNR/L24-6E 50102 50103 1.50 1.50 7.00 1.500 2.000 .184 MCKNR/L86-6E 50106 50107 1.00 1.50 7.00 1.500 1.250 .184 For Turning inserts see pages A-62 - A-91.
Load more

Recommended publications
  • Manufacturing Processes
    Module 1 Classification of Metal Removal Processes and Machine tools Version 2 ME IIT, Kharagpur Lesson 2 Basic working principle, configuration, specification and classification of machine tools Version 2 ME IIT, Kharagpur Instructional Objectives At the end of this lesson, the students should be able to : (a) Describe the basic functional principles of machine tools (i) Illustrate the concept of Generatrix and Directrix (ii) Demonstrate Tool – work motions (iii) Give idea about machine tool drives (b) Show configuration of basic machine tools and state their uses (c) Give examples of machine tools - specification (d) Classify machine tools broadly. Basic functional principles of machine tool operations Machine Tools produce desired geometrical surfaces on solid bodies (preformed blanks) and for that they are basically comprised of; • Devices for firmly holding the tool and work • Drives for providing power and motions to the tool and work • Kinematic system to transmit motion and power from the sources to the tool-work • Automation and control systems • Structural body to support and accommodate those systems with sufficient strength and rigidity. For material removal by machining, the work and the tool need relative movements and those motions and required power are derived from the power source(s) and transmitted through the kinematic system(s) comprised of a number and type of mechanisms. (i) Concept of Generatrix and Directrix • Generation of flat surface The principle is shown in Fig. 2.1 where on a flat plain a straight line called Generatrix (G) is traversed in a perpendicular direction called Directrix (D) resulting a flat surface. • Generation of cylindrical surfaces The principles of production of various cylindrical surfaces (of revolution) are shown in Fig.
    [Show full text]
  • Vibrations in Metal Cutting Measurement, Analysis and Reduction
    Vibrations in Metal Cutting Measurement, Analysis and Reduction Linus Pettersson Ronneby, March 2002 Department of Telecommunications and Signal Processing Blekinge Institute of Technology 372 25 Ronneby, Sweden c Linus Pettersson Licentiate Dissertation Series No. 01/02 ISSN 1650-2140 ISBN 91-7295-008-0 Published 2002 Printed by Kaserntryckeriet AB Karlskrona 2002 Sweden v Abstract Vibration and noise in metal cutting are ubiquitous problems in the workshop. The turning operation is one kind of metal cutting that exhibits vibration related problems. Today the industry aims at smaller tolerances in surface finish. Harder regulations in terms of the noise levels in the operator environment are also central. One step towards a solution to the noise and vibration problems is to investigate what kind of vibrations that are present in a turning operation. The vibrations in a boring operation have been put under scrutiny in the first part of this thesis. Analytical models have been compared with experimental results and the vibration pattern has been determined. The second part of the thesis deals with active vibration control in external turning operations. By embedding a piezo-ceramic actuator and an accelerometer into a tool holder it was possible to obtain a solution that can be fitted in a standard lathe. The control system consists of the active tool holder, a control system based on the filtered-X LMS algorithm and an amplifier designed for capacitive loads. The vibration level using this technique can be reduced by as much as 40 dB during an external turning operation. vii Preface The work presented in this licentiate thesis has been performed at the department of Telecommunications and Signal Processing at Blekinge Institute of Technology.
    [Show full text]
  • Boilermaker Health & Safety Manual
    Boilermakers Health & Safety Manual ihsa.ca Boilermakers Health & Safety Manual Infrastructure Health & Safety Association 5110 Creekbank Road, Suite 400 Mississauga, Ontario L4W 0A1 Canada 1-800-263-5024 ihsa.ca 1 Boilermakers Health & Safety Manual IHSA has additional information on this and other topics. Visit ihsa.ca or call Customer Service at 1-800-263-5024. The contents of this publication are for general information only. This publication should not be regarded or relied upon as a definitive guide to government regulations or to safety practices and procedures. The contents of this publication were, to the best of our knowledge, current at the time of printing. However, no representations of any kind are made with regard to the accuracy, completeness, or sufficiency of the contents. The appropriate regulations and statutes should be consulted. Readers should not act on the information contained herein without seeking specific independent legal advice on their specific circumstance. The Infrastructure Health & Safety Association is pleased to answer individual requests for counselling and advice. This manual was developed, reviewed, and endorsed by the Boilermakers Labour-Management Health and Safety Committee in association with IHSA. Manual IHSA editor: Lori-Lynn Bonnell, design and illustrations: Philippa Giancontieri; project manager: Mike Russo. The Infrastructure Health & Safety Association would like to thank the members of the working group for contributing their knowledge, experience, and time to produce a health and safety manual that will benefit both labour and management in the boilermaker sector. The working group included representatives from the Boilermaker Contractors’ Association (BCA) as well as: · Marty Albright – Alstom Power Canada Inc.
    [Show full text]
  • Mechanical Metalworking: from Manual to Computer-Based Processes
    August 04, 2021 Mechanical metalworking: from manual to computer-based processes Just like in an ordinary kitchen, there is more to the steelmaker’s kitchen than just the processes where high temperature plays a crucial role, such as boiling, roasting or baking. Before a dish can be served, it needs additional work to make it more appealing. The same is true of metals. Prior to their use, plates, tubes, rods and complex steel castings are subject to cold forming by special metalworking machines and lathes, which become more and more sophisticated each year. History of mechanical metalworking Let’s look first into the history of mechanical metalworking and its origins. Unlike many other processes that are unique to steelmaking, some ideas related to the mechanical working of metal surfaces came from related areas. The ancient Egyptians had devices for drilling holes in stones. Wood machining equipment that later evolved into turning lathes existed in the sixth and seventh centuries BC. Yet these types of processes were not applied to metals for hundreds of years. For a long time, metal surface treatment had several restricting factors. First, it required harder tools. Second, small-batch production did not need high-precision metalworking. Third, the industrial revolution and mass production of uniform products only became a reality in the 18th-19th centuries. The third reason was a key prerequisite for the appearance of mechanical metalworking. Smiths that made goods for individual orders gave way to large industrial manufacturers and factories that had the capacity to produce large quantities of uniform metal goods. Gunsmiths were among the first to appreciate the importance of standardised metalworking.
    [Show full text]
  • Vehicle Maintenance
    VEHICLE MAINTENANCE Introduction 1.0 Introduction The servicing of the automobile has also changed greatly to keep in step with the engineering advances of the industry. The tools and equipments which the early mechanic used were poor compared to today’s standard, and in many cases were made by the mechanic. Today’s automotive mechanic is well trained and works in a clean, bright, well- ventilated, specially designed automotive service centre. A thorough knowledge of the parts an understanding of the mechanisms are essential in order that faculty conditions in any part of automotive mechanism may be detected and corrected. As a result, the mechanic must possess the knowledge, skill, and experience in this field to be successful . Service Station A service station is a place where in addition to care of the motor vehicle like mechanical service and minor repairs, petrol is supplied, cars are lubricated, and cleaned, washed and other types of simpler services that are required daily are performed. In general it includes a number of sections like garage general it includes a number of sections like garage general service, mechanical service, major repair shop, tire shop, paint shop, body shop. A service station is addition to the equipment available is garage is usually run in conjunction with a sales agency for a particular type of motor vehicle to provide comprehensive repair service for that particular vehicle. The equipment available, in a general garage will be added with specialized equipment like lifting tackle, and different types of jigs, fixtures and tools specially designed for checking, adjusting and repair of particular type and make of the vehicle.
    [Show full text]
  • Introduction to Turning Tools and Their Application Identification and Application of Cutting Tools for Turning
    Introduction to Turning Tools and their Application Identification and application of cutting tools for turning The variety of cutting tools available for modern CNC turning centers makes it imperative for machine operators to be familiar with different tool geometries and how they are applied to common turning processes. This course curriculum contains 16-hours of material for instructors to get their students ready to identify different types of turning tools and their uses. ©2016 MachiningCloud, Inc. All rights reserved. Table of Contents Introduction .................................................................................................................................... 2 Audience ..................................................................................................................................... 2 Purpose ....................................................................................................................................... 2 Lesson Objectives ........................................................................................................................ 2 Anatomy of a turning tool............................................................................................................... 3 Standard Inserts .............................................................................................................................. 3 ANSI Insert Designations ............................................................................................................. 3 Insert Materials
    [Show full text]
  • Implementation of Metal Casting Best Practices
    Implementation of Metal Casting Best Practices January 2007 Prepared for ITP Metal Casting Authors: Robert Eppich, Eppich Technologies Robert D. Naranjo, BCS, Incorporated Acknowledgement This project was a collaborative effort by Robert Eppich (Eppich Technologies) and Robert Naranjo (BCS, Incorporated). Mr. Eppich coordinated this project and was the technical lead for this effort. He guided the data collection and analysis. Mr. Naranjo assisted in the data collection and analysis of the results and led the development of the final report. The final report was prepared by Robert Naranjo, Lee Schultz, Rajita Majumdar, Bill Choate, Ellen Glover, and Krista Jones of BCS, Incorporated. The cover was designed by Borys Mararytsya of BCS, Incorporated. We also gratefully acknowledge the support of the U.S. Department of Energy, the Advanced Technology Institute, and the Cast Metals Coalition in conducting this project. Disclaimer This report was prepared as an account of work sponsored by an Agency of the United States Government. Neither the United States Government nor any Agency thereof, nor any of their employees, makes any warranty, expressed or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any Agency thereof. The views and opinions expressed by the authors herein do not necessarily state or reflect those of the United States Government or any Agency thereof.
    [Show full text]
  • Metal Drill Bits Hammer Drill Stronger Than Steel Chisel Drill Bits Stone and Special Metal Drill Bits
    BITS METAL DRILL BITS HAMMER DRILL STRONGER THAN STEEL CHISEL DRILL BITS STONE AND SPECIAL METAL DRILL BITS 307 | HSS-E DIN 338 cobalt 76–79 WOOD DRILL BITS 311 | HSS TIN DIN 338 steel drill bit 80–81 302 | HSS DIN 338, ground, split point 82–85 300 | HSS DIN 338, standard 86–90 300 | HSS DIN 338, standard, shank reduced 91 340 | HSS DIN 340, ground, split point, long 92 342 | HSS DIN 1869, ground, extra long 93 SAWS 344 | HSS hollow section drill bit / Facade drill bit 94 345 | HSS DIN 345 morse taper 95–96 303 | HSS DIN 1897 pilot drill bit, ground, split point, extra short 97 310 | HSS DIN 8037 carbide tipped 98 312 | HSS-G Speeder DIN 338 RN metal drill bit 99 304 | HSS Double end drill bit, ground, split point 100 315 | HSS Drill bit KEILBIT, ground 101 317 | HSS combination tool KEILBIT 102 329 | HSS countersink KEILBIT 103 327 | HSS countersink 90° DIN 335 C 104 328 | HSS deburring countersink 105 ASSORTMENTS 326 | HSS tube and sheet drill bit 106 325 | HSS step drill 107 140 | Scriber 108 320 | HSS hole saw bi-metal 109–112 SHELVES | From Pros for Pros | www.keil.eu | 73 MODULES - BITS HAMMER DRILL METAL DRILL BITS Nothing stops the metal drill bits because we offer a drill bit for every application. CHISEL HSS-E TWIST DRILL BIT 135° The HSS-E drill bit is a cobalt alloyed high performance drill bit. Even with insufficient cooling it has reserve in heat resistance. Due to the alloying addition of 5 % Co in the cutting material these drill bits can be used for working with work pieces with a tensile strength of over 800N/m².
    [Show full text]
  • Cutoff Lathes and Endfinishers Brochure
    Rotating-Head Cutoff Lathes Tube Loading & Endfinishing Systems • Rugged high-speed cutting, grooving, turning and chamfering • More parts per hour, closer tolerances, reduced labor • Fastest changeover • OD/ID chamfers in a single chucking, both ends • Models for round tubing up to 9" diameter, barstock to 3" HAUT-025RCBrochure2RS.indd 2 1/27/10 1:29:15 PM Our History and Our Commitment to You … Hautau is our family name. It is on every machine we build. That’s why we’ll stand behind you on every one 24/7. Hautau makes world-class tube cutoff machines and systems. They are designed, engineered and built by American craftsmen in the fields of southeast Indiana. Charles F. Hautau Sr, company founder, was a gifted inventor who held over 60 patents including rotary-head cutoff and CNC tube bending. Charles Jr. and Fred have carried on the tradition, building a wide range of innovative machinery for over forty years. Among our early machines was one to trim the ends of mufflers. Because the muffler Charlie Hautau could not spin, our design featured a rotating head. After twenty years of building tube cutting and processing machines and other custom automation, we decided to apply the rotating head concept to cutting thick wall steel tubing. This would form the basis for our standard product line. Traditional tube cutoff lathes have a headstock with a through hole up to two feet deep, so tube feeding methods are limited. The tube can be machined on just one end. Short cuts can fly out and long cuts need outboard support rollers.
    [Show full text]
  • Holemaking Products & Accessories
    Holemaking Products Holemaking Products Holemaking Products & & Accessories Accessories Made of top-of-the-line materials for longer lasting performance, Klein's diverse line of drill bits and holemaking products and accessories provide accuracy and consistency to get the job done right. 225 All dimensions are in inches and (millimeters). www.kleintools.com NOTE: Read and follow safety instructions in power tool owner's manual. Flexible Drill Bits Flex Bit Augers 53719 • Used to drill holes through wood within a wall. Tapered back for easy bit retrieval. • 53720 • Spring steel shaft resists deformation. • Screw point tip pulls the bit through wood. • Hole in tip allows for use with wire or cable pulling grip. 53719 Cat. No. Length Weight (lbs.) 53716 3/8" x 54" (9.5 mm x 1372 mm) 1.00 53717 3/8" x 72" (9.5 mm x 1829 mm) 1.00 53718 9/16" x 54" (14 mm x 1372 mm) 1.00 53718 Holemaking Products & Holemaking Products & Accessories 53719 3/4" x 54" (19 mm x 1372 mm) 2.00 53751 3/4" x 72" (19 mm x 1829 mm) 2.00 53720 1" x 54" (25 mm x 1829 mm) 2.00 53716 Flex Bit Extensions 53722 • Connects to the end of a flex bit and extends the length. Cat. No. For Use with Flex Bits Length Connection Diameter Weight (lbs.) 53722 3/4" and larger 54" (1372 mm) 5/8" (14 mm) 1.00 53723 9/16" and smaller 54" (1372 mm) 7/16" (11 mm) 1.00 Flex Bit Placement Tool • For use with flexible drill bits.
    [Show full text]
  • BORING MACHINE • the Boring Machine Is One of the Vertalile Machine Tool Used to Enlarge Already Drilled Hole
    MANUFACTURING TECHNOLOGY UNIT – V Machine Tools Department of Automobile Engineering Manufacturing Technology Introduction • One of the most versatile machine tools; used to bore holes in large and heavy parts as engine frames, machine housings etc which are practically impossible to hold and rotate in an engine lathe or in a drilling machine. • Also drilling, milling and facing can be preformed with equal facility. • Along with attachments screw cutting, turning, grinding or gear cutting can also be performed. Department of Automobile Engineering Manufacturing Technology CLASSIFICATION OF BORING MACHINE • The boring machine is one of the vertalile machine tool used to enlarge already drilled hole. • Boring operation can be performed on lathe as that of turning where tool is stationary and work piece is rotating. • But in case of boring is rotating and work piece is stationary which is similar to • Drilling ,reaming , milling etc. • Boring machines can be classified based on position of boring tools, accuracy of work required etc. Department of Automobile Engineering Manufacturing Technology Boring machines 1. Horizontal 2. Vertical 3. Precision (Jig) Boring Boring Boring Machine Machine Machine (HBM) (VBM) (PBM) Department of Automobile Engineering Manufacturing Technology Types Horizontal boring machine: • The work is supported on a table which is stationary and tool revolves in a horizontal axis. • Can perform boring, reaming, turning, threading, facing, milling , grooving and many other operations with suitable tools. • Work piece
    [Show full text]
  • Boilermaking Manual. INSTITUTION British Columbia Dept
    DOCUMENT RESUME ED 246 301 CE 039 364 TITLE Boilermaking Manual. INSTITUTION British Columbia Dept. of Education, Victoria. REPORT NO ISBN-0-7718-8254-8. PUB DATE [82] NOTE 381p.; Developed in cooperation with the 1pprenticeship Training Programs Branch, Ministry of Labour. Photographs may not reproduce well. AVAILABLE FROMPublication Services Branch, Ministry of Education, 878 Viewfield Road, Victoria, BC V9A 4V1 ($10.00). PUB TYPE Guides Classroom Use - Materials (For Learner) (OW EARS PRICE MFOI Plus Postage. PC Not Available from EARS. DESCRIPTORS Apprenticeships; Blue Collar Occupations; Blueprints; *Construction (Process); Construction Materials; Drafting; Foreign Countries; Hand Tools; Industrial Personnel; *Industrial Training; Inplant Programs; Machine Tools; Mathematical Applications; *Mechanical Skills; Metal Industry; Metals; Metal Working; *On the Job Training; Postsecondary Education; Power Technology; Quality Control; Safety; *Sheet Metal Work; Skilled Occupations; Skilled Workers; Trade and Industrial Education; Trainees; Welding IDENTIFIERS *Boilermakers; *Boilers; British Columbia ABSTRACT This manual is intended (I) to provide an information resource to supplement the formal training program for boilermaker apprentices; (2) to assist the journeyworker to build on present knowledge to increase expertise and qualify for formal accreditation in the boilermaking trade; and (3) to serve as an on-the-job reference with sound, up-to-date guidelines for all aspects of the trade. The manual is organized into 13 chapters that cover the following topics: safety; boilermaker tools; mathematics; material, blueprint reading and sketching; layout; boilershop fabrication; rigging and erection; welding; quality control and inspection; boilers; dust collection systems; tanks and stacks; and hydro-electric power development. Each chapter contains an introduction and information about the topic, illustrated with charts, line drawings, and photographs.
    [Show full text]