Fundamental Concepts of Metal Forming Technology
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Magazine Lip Forming Tools
MAGAZINE LIP FORMING TOOLS Brownells Lip Forming Anvil and Yoke help the gunsmith alter original equipment-style, .45 caliber, 1911 Auto magazines to properly feed ammuni- tion with semi-wadcutter bullets. Issue-style feed lips are designed for round nose, 230 grain, jacketed bul- lets which have a long ogive and ride up the barrel’s feed ramp easily. Rounds loaded with shorter, lighter, blunt nosed or semi-wadcutter bullets can ei- ther run into the feed ramp as the slide carries them forward or “stand up” too soon and cause a smokestack jam. Changing the lip contour with these tools causes the magazine to release the rear of the cartridge sooner so the extractor can pick it up and help direct it up the ramp and into the chamber. Most aftermarket magazines like those made by Metalform, Wilson, Mc- Cormick, Pachmayr and others, already have a similar feed lip shape. The Lip Forming Anvil and Yoke can often be used to restore the lips on these magazines if they get damaged. READ & FOLLOW THESE m WARNING m Never attempt to disassemble or reassemble a firearm unless you are INSTRUCTIONS absolutely certain that it is empty and unloaded. Visually inspect the chamber, the magazine and firing mechanism to be absolutely certain that no ammunition remains in the firearm. Disassembly and reas- BROWNELLS GUNSMITHS DATA RING BINDER GUNSMITHS BROWNELLS DATA sembly should follow the manufacturer’s instructions. If such instruc- tions are not immediately available, contact the manufacturer to see if they are available. If they are not available at all, then you should 200 S. -
126 Metal Products
Lake Tuggeranong College LEARN – THRIVE - CONNECT Metal Products A/M Working with metal has fascinated people for centuries. Metal forming processes have advanced significantly in recent times and have enabled the creation of objects which have changed the world forever. These processes are now able to be experienced by students through the development of metal fabrication projects which provide an understanding of metal properties and construction techniques. The considerable time devoted to the practical skills in this course makes it an ideal choice for students who are looking for a unique practical learning environment. Rationale Why would you do this course? Working with metal is an enjoyable activity which more students need to experience! Being able to apply metal fabricating processes to create projects with a student design input is a major emphasis in the course. The range of fundamental skills employed in the metal fabrication industry readily engage students in their course work. There is a current skills shortage in the metal trade areas as evidenced by the inclusion of Metal Fabricator and Welder in the National Skills Needs list. There is a federal government push for apprenticeships using the skills learnt during this course. Beyond the classroom, this subject offers you: • Pathways to metal trades: boiler maker/metal fabricator • Skills that are interlinked between other trades: construction, plumber, electrician • Basic handyman skills Learner dispositions What type of person usually studies this course? Learners who would study this course typically achieve a satisfaction from being able to create practical objects using techniques such as welding, machining, plasma cutting, sheet metal forming and more. -
Improved Coining Force Calculations Through Incorporation of Key Process Parameters Dominique Cotton, André Maillard, Joël Kaufmann
Improved coining force calculations through incorporation of key process parameters Dominique Cotton, André Maillard, Joël Kaufmann To cite this version: Dominique Cotton, André Maillard, Joël Kaufmann. Improved coining force calculations through incorporation of key process parameters. IDDRG, Oct 2020, BUSAN, South Korea. pp.012003, 10.1088/1757-899X/967/1/012003/meta. hal-03117270 HAL Id: hal-03117270 https://hal.archives-ouvertes.fr/hal-03117270 Submitted on 21 Jan 2021 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. IOP Conference Series: Materials Science and Engineering PAPER • OPEN ACCESS Improved coining force calculations through incorporation of key process parameters To cite this article: D Cotton et al 2020 IOP Conf. Ser.: Mater. Sci. Eng. 967 012003 View the article online for updates and enhancements. This content was downloaded from IP address 195.221.202.65 on 15/01/2021 at 13:35 International Deep-Drawing Research Group (IDDRG 2020) IOP Publishing IOP Conf. Series: Materials Science and Engineering 967 (2020) 012003 doi:10.1088/1757-899X/967/1/012003 Improved coining force calculations through incorporation of key process parameters D Cotton1,3, A Maillard2, and J Kaufmann2 1 Arts et Métiers Institute of Technology, LABOMAP, HESAM University, 71250 Cluny, France 2 CETIM – Technical Centre for Mechanical Industries – France 3 Author to whom any correspondence should be addressed E-mail address: [email protected] Abstract. -
Fire Protection of Steel Structures: Examples of Applications
Fire protection of steel structures: examples of applications Autor(en): Brozzetti, Jacques / Pettersson, Ove / Law, Margaret Objekttyp: Article Zeitschrift: IABSE proceedings = Mémoires AIPC = IVBH Abhandlungen Band (Jahr): 7 (1983) Heft P-61: Fire protection of steel structures: examples of applications PDF erstellt am: 06.10.2021 Persistenter Link: http://doi.org/10.5169/seals-37489 Nutzungsbedingungen Die ETH-Bibliothek ist Anbieterin der digitalisierten Zeitschriften. Sie besitzt keine Urheberrechte an den Inhalten der Zeitschriften. Die Rechte liegen in der Regel bei den Herausgebern. Die auf der Plattform e-periodica veröffentlichten Dokumente stehen für nicht-kommerzielle Zwecke in Lehre und Forschung sowie für die private Nutzung frei zur Verfügung. Einzelne Dateien oder Ausdrucke aus diesem Angebot können zusammen mit diesen Nutzungsbedingungen und den korrekten Herkunftsbezeichnungen weitergegeben werden. Das Veröffentlichen von Bildern in Print- und Online-Publikationen ist nur mit vorheriger Genehmigung der Rechteinhaber erlaubt. Die systematische Speicherung von Teilen des elektronischen Angebots auf anderen Servern bedarf ebenfalls des schriftlichen Einverständnisses der Rechteinhaber. Haftungsausschluss Alle Angaben erfolgen ohne Gewähr für Vollständigkeit oder Richtigkeit. Es wird keine Haftung übernommen für Schäden durch die Verwendung von Informationen aus diesem Online-Angebot oder durch das Fehlen von Informationen. Dies gilt auch für Inhalte Dritter, die über dieses Angebot zugänglich sind. Ein Dienst der ETH-Bibliothek ETH Zürich, Rämistrasse 101, 8092 Zürich, Schweiz, www.library.ethz.ch http://www.e-periodica.ch J% IABSE periodica 2/1983 IABSE PROCEEDINGS P-61/83 69 Fire Protection of Steel Structures — Examples of Applications Protection contre le feu des structures acier — Quelques exemples d'applications Brandschutz der Stahlkonstruktionen — Einige Anwendungsbeispiele Jacques BROZZETTI Margaret LAW Dir., Dep. -
A Comparison of Thixocasting and Rheocasting
A Comparison of Thixocasting and Rheocasting Stephen P. Midson The Midson Group, Inc. Denver, Colorado USA Andrew Jackson Arthur Jackson & Co., Ltd. Brighouse UK Abstract The first semi-solid casting process to be commercialized was thixocasting, where a pre-cast billet is re-heated to the semi-solid solid casting temperature. Advantages of thixocasting include the production of high quality components, while the main disadvantage is the higher cost associated with the production of the pre-cast billets. Commercial pressures have driven casters to examine a different approach to semi-solid casting, where the semi-solid slurry is generated directly from the liquid adjacent to a die casting machine. These processes are collectively referred to as rheocasting, and there are currently at least 15 rheocasting processes either in commercial production or under development around the world. This paper will describe technical aspects of both thixocasting and rheocasting, comparing the procedures used to generate the globular, semi-solid slurry. Two rheocasting processes will be examined in detail, one involved in the production of high integrity properties, while the other is focusing on reducing the porosity content of conventional die castings. Key Words Semi-solid casting, thixocasting, rheocasting, aluminum alloys 22 / 1 Introduction Semi-solid casting is a modified die casting process that reduces or eliminates the porosity present in most die castings [1] . Rather than using liquid metal as the feed material, semi-solid processing uses a higher viscosity feed material that is partially solid and partially liquid. The high viscosity of the semi-solid metal, along with the use of controlled die filling conditions, ensures that the semi-solid metal fills the die in a non-turbulent manner so that harmful gas porosity can be essentially eliminated. -
Coining's Micro Stamping Capabilities
ELECTRONIC COMPONENTS AND PACKAGING Coining Inc. Micro-Stampings Overview www.ametek.com © 2015 by AMETEK, Inc. All rights reserved. ELECTRONIC COMPONENTS AND PACKAGING Micro-Stampings and Solder Preforms More Than 100 Presses 3 ton to 85 ton High speed (>2000 strokes/min) High precision, 4 post presses Hot presses for stamping Mo, W, etc. www.ametek.com © 2015 by AMETEK, Inc. All rights reserved. ELECTRONIC COMPONENTS AND PACKAGING Coining Differentiators Material Processing Capability In-house advanced casting, rolling and cladding Plating to customer specifications Custom alloys available Tool & Die Capability More than 15,000 dies on-hand Customized designs available Tooling designed to match material characteristics Progressive stamping up to 16 stations Deep draw designs available In-house EDM based tool manufacturing Parts Delivered Clean Room Ready Industry Leading Applications Support Team www.ametek.com © 2015 by AMETEK, Inc. All rights reserved. ELECTRONIC COMPONENTS AND PACKAGING Applications Support Experienced Engineering Team Our material scientists and manufacturing engineers have more than 100 years experience Analytical Capabilities ICP (Inductively Coupled Plasma) for elemental analysis of melts ICP DSC (Differential Scanning Calorimetry) to evaluate proper melting point and characteristics XRF (X-Ray Fluorescence) to verify thickness of plated coatings Wetting Tests to ensure optimal wetting and spread of solder alloys SEM with EDS capability for detailed metallurgical analysis and FA SEM LECO O2, N2, C and S analyzers www.ametek.com © 2015 by AMETEK, Inc. All rights reserved. ELECTRONIC COMPONENTS AND PACKAGING Stampings Capabilities Capabilities Include Stamping Coining Drawing Punching A Wide Varity Of High Precision Parts Available From simple to complex shapes Thicknesses less than 1 mil All Tooling Designed, Manufactured & Maintained In-House Enables rapid prototyping Ensures prime condition of tooling www.ametek.com © 2015 by AMETEK, Inc. -
Updated Course Guide Jan 2017.Pdf
1 Wilmot Union High School Mission Statement As a professional learning community, Wilmot Union High School's core purpose is to ensure our students are college, career, and civic ready by fostering a culture of life-long learning. District Vision As a learning community and through community involvement, Wilmot Union High School has developed a clear sense of who we want to become through a process where district stakeholders: students, staff, parents, community members, business partners and Board of Education members came together and identified the key characteristics and values we want to exemplify. These characteristics and values were aligned under five pillars to further define the key areas of focus for our learning community. I. Safe and Supportive Learning Environment II. Equity and Access for All Students III. Community Partnerships IV. Collaborative Culture for Learning V. Curriculum, Instruction and Assessment It is through these five pillars and their guiding statements that WUHS and our stakeholders will empower one another to create and fulfill the goals and commitments that will bring our vision to fruition. We invite every stakeholder of the WUHS learning community to enter in to this process of adopting the defined values to fulfill our vision of an exemplary school. 2 Wilmot Union High School P.O. Box 8 11112 – 308th Avenue Wilmot, WI 53192 High School Administration (262) 862-2351 John LaFleur, Ph.D., Principal [email protected] Tom Blair, Associate Principal [email protected] Luke Braden, Associate -
Forming Methods
theartofpressbrake.com http://www.theartofpressbrake.com/wordpress/?page_id=1023 Forming Methods Bend Allowance, Outside Setback, Bend Deduction If you calculate these with precision, you have a better chance of bending a good part on the first try. But, to make this happen, you need to make sure every factor in the equation is what it should be, and this includes the inside bend radius . How exactly is this inside bend radius achieved? To uncover this, we must first look at the different methods of bending on a press brake: air forming, bottom bending, and coining. The Methods of bending There are three different types of bending methods used in the forming of sheet metal: “ air forming“, “Bottom Bending and “Coining. Each of these methods has a specific purpose and application. In this chapter the benefits and the inefficiencies of each will be discussed. Coining Note that there are three bending methods, not two. Bottom bending and coining often are confused for the same process, but they are not. Unlike bottoming, coining actually penetrates and thins the material. Coining is the oldest method and for the most part, no longer practiced. Why? Because of the extreme tonnages this method requires. An amount of tonnage so great that the material “flows” on a molecular level while under this extreme pressure. Coining forces the punch nose into the material, penetrating the neutral axis, figure 1. Technically, any radius may be coined, but traditionally, coining has been used to establish a dead-sharp bend. This method not only requires excessive tonnages, it also destroys the material’s integrity. -
S2P Conference
The 9th International Conference on Semi-Solid Processing of Alloys and Composites —S2P Busan, Korea, Conference September 11-13, 2006 Qingyue Pan, Research Associate Professor Metal Processing Institute, WPI Worcester, Massachusetts Busan, a bustling city of approximately 3.7 million resi- Pusan National University, in conjunction with the Korea dents, is located on the Southeastern tip of the Korean Institute of Industrial Technology, and the Korea Society peninsula. It is the second largest city in Korea. Th e natu- for Technology of Plasticity hosted the 9th S2P confer- ral environment of Busan is a perfect example of harmony ence. About 180 scientists and engineers coming from 23 between mountains, rivers and sea. Its geography includes countries attended the conference to present and discuss all a coastline with superb beaches and scenic cliff s, moun- aspects on semi-solid processing of alloys and composites. tains which provide excellent hiking and extraordinary Eight distinct sessions contained 113 oral presentations views, and hot springs scattered throughout the city. and 61 posters. Th e eight sessions included: 1) alloy design, Th e 9th International Conference on Semi-Solid Pro- 2) industrial applications, 3) microstructure & properties, cessing of Alloys and Composites was held Sept. 11-13, 4) novel processes, 5) rheocasting, 6) rheological behavior, 2006 at Paradise Hotel, Busan. Th e fi ve-star hotel off ered a modeling and simulation, 7) semi-solid processing of high spectacular view of Haeundae Beach – Korea’s most popular melting point materials, and 8) semi-solid processing of resort, which was the setting for the 9th S2P conference. -
Monumental Iron Works®
Monumental Iron Works® 1 The Finest Ornamental Iron Crafted Elegance, Ornamental iron fences and gates have been Customized Construction the architectural choice for attractive security Monumental Iron Works is a modular system, worldwide for hundreds of years. Combining consisting of component parts designed to today’s technology with traditional elegance support each other. When completely assembled, and craftsmanship, Master Halco is able to offer these parts create one of the strongest ornamental a unique, ornamental solution with the look of fence systems on the market. Using industrial fencing forged by the hands of master blacksmiths. rivets, the constructed panels have the solid look and feel of authentic ornamental iron. Monumental Iron Works® fences and gates bring a combination of aesthetic elegance and With a riveted panel system, you can be sure security to residential, commercial, industrial, and the factory applied coating will offer years of institutional properties. Monumental Iron Works is maintenance and rust free elegance. Monumental sure to satisfy your architectural goals with a wide Iron Works utilizes a multiple layer coating process variety of options, designs, and styles crafted for that ensures corrosion protection, durability outstanding value. Quality materials manufactured and a great appearance for years to come. to our exacting specifications allows us to provide Monumental Iron Works system will complement a durable, cost-effective fence system that will last any architectural design while providing elegance, for many years. security, and long lasting value. Top 3 Reasons to Buy Monumental Iron Works® 1. Made In America • Monumental Iron Works is made in America and can be ordered through your local Master Halco distributor location. -
Magnesium Casting Technology for Structural Applications
Available online at www.sciencedirect.com Journal of Magnesium and Alloys 1 (2013) 2e22 www.elsevier.com/journals/journal-of-magnesium-and-alloys/2213-9567 Full length article Magnesium casting technology for structural applications Alan A. Luo a,b,* a Department of Materials Science and Engineering, The Ohio State University, Columbus, OH, USA b Department of Integrated Systems Engineering, The Ohio State University, Columbus, OH, USA Abstract This paper summarizes the melting and casting processes for magnesium alloys. It also reviews the historical development of magnesium castings and their structural uses in the western world since 1921 when Dow began producing magnesium pistons. Magnesium casting technology was well developed during and after World War II, both in gravity sand and permanent mold casting as well as high-pressure die casting, for aerospace, defense and automotive applications. In the last 20 years, most of the development has been focused on thin-wall die casting ap- plications in the automotive industry, taking advantages of the excellent castability of modern magnesium alloys. Recently, the continued expansion of magnesium casting applications into automotive, defense, aerospace, electronics and power tools has led to the diversification of casting processes into vacuum die casting, low-pressure die casting, squeeze casting, lost foam casting, ablation casting as well as semi-solid casting. This paper will also review the historical, current and potential structural use of magnesium with a focus on automotive applications. The technical challenges of magnesium structural applications are also discussed. Increasing worldwide energy demand, environment protection and government regulations will stimulate more applications of lightweight magnesium castings in the next few decades. -
Monte Carlo Stock
Gun Stocks STOCK DESIGN AND STOCK STYLE Types of Gun Stocks A gunsmith requires a basic understanding of stock function prior to becoming a stock maker. A rifle stock, in function, is nothing more than a segment of wood, fiberglass, plastic, or other material shaped to support the rifle’s barrel and action. It also functions to conform to the shooter’s body so the shooter can control the firearm. That’s the mechanical side of it. However, arms lovers the world over consider a stock much more than a mechanical device. They think of a gun stock as a work of art and function (Figure 1). As a prospec- tive gunsmith, we hope this is your position. FIGURE 1—Notice the attractive oak-leaf pattern on this Bishop-III stock. (Photo courtesy of Reinhart Fajen, Inc.) Stocks can be built in a multitude of styles with a stock shape to fit everyone. Even factory rifles come in a wide variety of stock styles. Factory stocks, incidentally, have come a long way and can be considered quite good today, although cer- tainly not in the realm of a custom-made stock. Figure 2 shows a gun stock labeled with its proper nomenclature. 1 FIGURE 2—Become familiar with the names of the parts of a gun stock. Early Stock Design Turning the pages of gun history to an earlier time reveals that the first stocks well known to American shooters had a great deal to do with contemporary stock designs. However, such muzzleloader stocks left a lot to be desired.