Copper, Aluminum, Titanium & Alloys – Contents
| 1.0 | Copper and Copper Alloy | 1 – 70
 |
|
1.1 |
Copper | 2 – 3 |
| 1.1.1 | Copper in General | 2 |
| 1.1.2 | Origin | 3 |
| 1.1.3 | Production Quantity | 3 |
| 1.2 | Refinery of Copper | 3 |
| 1.3 | Copper and Copper Alloy Flow Chart | 4 |
| 1.4 | Copper Based Alloy Constituents Chart | 5 |
| 1.5 | Copper | 6 – 8 |
| 1.5.1 | Oxygen free high conductivity Copper – OFHC | 6 |
| 1.5.2 | Tough Pitch Copper | 6 |
| Copper Oxide | 6 | |
| Globules Formation | 6 | |
| Disadvantages of Globules in Copper | 6 | |
| Advantages of Globules in Copper | 6 | |
| 1.5.3 | Electrical Conductivity of Copper | 7 |
| 100%Conductivity | ||
| Over 100% Conductivity | ||
| Oxygen free high conductivity copper | ||
| 1.5.4 | End Usages of Copper | 8 |
| 1.6 | Water Tube | 9 – 13 |
| Advantage of Water Tube | 9 | |
| Rules | 9 | |
| Conduit size | 9 | |
| 1.6.1 | Simple Principal of Calculating pipe size | 10 |
| 1.6.2 | Minimum Copper Tube Sizes for Short Branch Connections to Fixture | 10 |
| 1.6.3 | Packing Method | 10 |
| 1.6.4 | Ordering | 11 |
| 1.6.5 | Chemical Composition of seamless copper water tube (to ASTM B88) | 12 |
| 1.6.6 | Mechanical Properties of seamless copper water tube to ASTM B88 | 12 |
| 1.6.7 | Joining of Copper Tube for water and non-corrosive gases | 12 |
| 1.6.8 | Copper Seamless tube – Standard Size, Working Pressure and Weight | 13 |
| 1.7 | Turner Grooved Copper Tube | 14 |
| Groove Shape | ||
| Standard Sizes | ||
| 1.8 | Copper, Arc Tube | 15 – 16 |
| Chemical Composition and Hardness | 15 | |
| Mechanical Properties | 15 | |
| Standard Sizes, Weights and Tolerances | 16 | |
| Packing Method | 16 | |
| Ordering | 16 | |
| 1.9.1 | Floor Heating Copper Tube | 16 |
| 1.9.2 | Plastic-sheathed Copper tube | 17 |
| 1.10 | Finned Tube | 17 |
| 1.11 | Pure Copper Casting for General Use to JIS H5100 | 17 |
| Copper Alloy | 19 – 68 | |
| 1.12 | Brass – Type , Zinc Properties, Working Method, Colour, Hardness & Tensile Strength and Ductility Chart | 20 |
| Brass | 21 – 24 | |
| 1.13 | Brass | 21 |
| Solidus Temperature and Zinc Dissolution Ratio | 21 | |
| 1.13.1 | Free Cutting Brass | 21 |
| 1.13.2 | High Tensile Brass | 21 |
| 1.13.3 | Commercial Brass | 22 |
| 1.13.4 | Naval Brass or Admiralty Brass | 23 |
| 1.13.5 | Brass Ingot for Castings (to JIS H5101) | |
| 1.13.6 | High Strength Brass Ingots for Castings to JIS H2205 | 23 |
| Bronze | 24 – 25 | |
| 1.14.1 | Bronze, metal ingredients | 24 |
| 1.14.2 | Phosphor Bronze | 24 |
| 1.14.3 | Zinc Bronze | 24 |
| 1. 14.4 | Leaded Bronze | 25 |
| 1.14.5 | Phosphor-bronzes, Tin Bronzes and Red Brass -Chemical composition, mechanical properties, end usage & characteristic | 26 |
| 1.15 | Aluminum Bronze | 27 – 28 |
| 1. 15.1 | Features | 27 |
| 1.15.2 | Casting Problem | 27 |
| 1.15.3 | Type and End Usage | 27 – 28 |
| (a-Phase, Cold-working alloy) (a+ y2 (gamma) phase Hot-working and casting alloy) |
||
| 1.15.4 | Aluminum Bronze Ingots for Castings to JIS H2206 | 28 |
| Nickel Copper | 29 – 30 | |
| 1.16.1 | Nickel Sliver | 29 |
| 1.16.2 | Nickel Copper Alloys for Marine Purpose | 29 |
| Advantage | ||
| End Useage | ||
| 1.16.3 | Cupro Nickel | 29 |
| 1.16.4 | Copper Nickel Alloys to BS2870/5, 3072/6 & NES824,condition, chemical properties feature & end usages | 30 |
| 1.17 | Chromium Copper | 31 |
| 1.18 | Zirconium Copper | 31 |
| 1.19 | Silicon Copper | 31 |
| 1.20 | Hot-dip tinned copper or alloy strip | 31 |
| 1.21 | Contour – miller copper alloy strip | 32 |
| 1.22 | Heat-Treatable Copper Alloy | 33 |
| (a) | Beryllium Copper | 33 |
| (b) | Titanium Copper | 33 |
| (c) | Shape Memory Copper Alloy | 33 |
| 1.23 | Copper Alloy – Sheet and Strip, Alloy Name, Physical Properties, Tensile Strength and Elongation | 34 – 35 |
| 1.24 | Copper and Copper Alloy – Strip and Sheet Classification, Industrial Standards, Class , Chemical Composition, Application and Characteristics | 37 – 39 |
| 1.25 | Copper and Copper Alloy – Strip and Sheet, Thickness and Width Tolerance | 40 |
| 1.26 | Copper and copper Alloy Strip, Sheet and Plate Standard Measurement | 41 |
| Sheets and Plates | 41 | |
| Strips | 41 | |
| 1.27 | Semi-finished Product of Copper and Copper Alloy | 41 |
| 1.28 | Copper and Copper Alloy, Mechanical Properties | 42 – 43 |
| 1.29 | Copper and Copper Alloy – Rod and Bar Classification, Industrial Standards, Class, Chemical Composition, Application and Characteristics | 44 – 46 |
| 1.30 | Free Cutting Brass Rod and Bar – Mechanical Properties | 47 – 49 |
| 1.31 | Copper and Copper Alloy Strip, Sheet and Plate Standard Measurement | 50 |
| Rods and Bars | 50 | |
| Wires | 50 | |
| 1.32 | Semi-finished Product of Copper and Copper Alloys | 51 |
| Semi-finished | 51 | |
| Advantages | 51 | |
| 1.33 | Copper and Copper Alloy – Wire Classification, Industrial Standards, Class, Chemical Composition, Application and Characteristics |
52 – 54 |
| 1.33.1 | The dimensional tolerances of diameter and length of Round, Hexagonal, Rectangular and Square Rods and Bars. | 54 |
| 1. 34 | Copper and Copper Alloy Wire Diameter Tolerance | 55 |
| Round Wire | 55 | |
| Square Wire | 55 | |
| Hexagonal Wire | 55 | |
| 1.35 | Copper and Copper Alloy, Grain Size | 56 |
| 1.36 | Copper and Copper Alloy, Mechanical Properties | 56 |
| 1.37 | Deep Drawing Purpose (non-earing) strip & sheet, Non-directional | 57 |
| Earing | 57 | |
| Calculation of earing percentage | 57 | |
| 1.38 | Deep Drawing Material | 57 – 58 |
| Deep Drawing Quality (DDQ) Strip / Sheet | 57 | |
| Limits of deep drawing in Practice of Various Metal | ||
| Reduction Limit Ration | 58 | |
| 1.39 | Material with Speical Feature | 58 – 59 |
| Stress | 58 | |
| Freedom from Flow Line | 58 | |
| Soft temper | 58 | |
| Etching | 59 | |
| 1.40 | Copper Alloy Strip & Sheet End Usage (classified by trade) |
59 – 60 |
| 1.41 | Direct and Indirect Extrusion | 61 |
| 1.42 | Cladded and Plated Metal Alloy | 62 – 68 |
| The Method of Cladding | 62 | |
| Cladding included Base & Cladding Metal | 62 | |
| 1.42.1 | Types of Cladding | 62 |
| Over lay | 62 | |
| In lay | 62 | |
| Corner lay | 62 | |
| Edge lay | 62 | |
| Top lay | 62 | |
| Multi-layer inlay | 62 | |
| 1.42.2 | Plating | 63 |
| 1.42.3 | Flow Chart of Claded & Plated Metal | 63 |
| 1.42.4 | Various Base Metals’ Other Claded Metal | 64 – 65 |
| 1.42.5 | Plating Position & Example | 66 |
| 1.42.6 | Coiling Direction | 66 |
| 1.42.7 | End Usages | 67 |
| 1.42.8 | Claded, Inlet or Plated Stainless Steel Strip | 68 |
| 1.43 | Indentification of Copper and head Alloy by Physical and Chemical Test | 69 |
| 1.44 | Electroplating Purpose Copper Materials Alloy | 70 |
| 2.0 | Aluminum and Aluminum Alloy | 71 – 121 |
| 2.1 | Aluminum in General | 73 |
| 2.2 | Origin | 73 |
| 2.3 | Refinery | 73 |
| 2.4 | IOutstanding Characteristics of Aluminum | 73 – 74 |
| 2.5 | Production Method & Production Flow Chart | 75 – 77 |
| 2.5.1 | Production of Ingot | 75 |
| 2.5.2 | Production of Aluminum and Alloy Material | 76 |
| 2.5.3 | Aluminum Surface Treatment | 77 |
| 2.6 | Corrosion Resistance Properties | 78 |
| 2.7 | Corrosion Resistance of Aluminum Against Chemical | 79 – 82 |
| 2.8 | Classification of Aluminum & Aluminum Alloys | 83 – 84 |
| 2.8.1 | Comparison of Heat-treatable and Non-treatable Alloy | 83 |
| Tensile Strength | ||
| Alloy | ||
| Corrosion Resistant | ||
| Jointing | ||
| Machining | ||
| 2.8.2 | Not-heat-treatable Wrought Aluminum Alloy | 84 |
| 2.8.3 | Not-heat-treatable Cast Aluminum Alloy | 84 |
| 2.8.4 | Heat-treatable Wrought Aluminum Alloy | 84 |
| 2.8.5 | Heat-treatable Wrought Aluminum Alloy | 84 |
| Industrial Standards of Aluminum & Alloys | 85 – 113 | |
| 2.9 | American Standards | 85 – 99 |
| 2.9.1 | Typical mechanical properties of Aluminum & Aluminum alloy (Alloy Designation) | 85 |
| 2.9.2 | (Temper Designation) | 86 – 88 |
| 2.9.3 | Visual Inspection | 88 – 89 |
| 2.10 | Japan Industrial Standard (JIS) | 90 |
| 2.11 | British Standard (BS) | 91 |
| 2.11.1 | Heat-Treatable & Non Hea-Treatable Alloy | 91 |
| 2.11.2 | Materials Shape | 91 |
| 2.11.3 | Purity | 91 – 92 |
| 2.11.4 | Condition | 92 – 93 |
| 2.12 | Engineering Aluminum Under British Standard | 94 – 95 |
| 2.13 | Other Standards | 96 |
| 2.14 | Aluminum – Type, Industrial Standard, Chemical Composition, Characteristic & end usage of the most commonly used Stainless Steel | 97 – 108 |
| 2.15 | U.S. Aluminum Plate Standard | 109 |
| 2.16 | Weight of Aluminum Plate (For 2024 and 7075 alloy) | 109 |
| 2.17 | Comparison of Aluminum Bars Standard | 110 |
| 2.18 | Aluminum Rounds (2024 and 7075 alloy) | 111 – 113 |
| 2.19 | Aluminum Square (2024 and 7075 alloy) | 114 |
| 2.20 | Aluminum Rectangle (2024 and 7075 alloy) | 115 – 119 |
| 2.21 | Aluminum Hex (2024 and 7075 alloy) | 120 – 121 |
| 3.0 | Titanium and Titanium Alloy | 125 – 173 |
| 3.1 | Titanium in general | 125 – 127 |
| 3.1.1 | Application | 125 |
| 3.1.2 | Example of Application | 126 |
| 3.1.3 | Supply of Titanium | 127 |
| 3.1.4 | Origin of Titanium | 127 |
| 3.2 | Refinery | 128 – 129 |
| 3.2.1 | Titanium Spongy Manufacturing Flow Chart | 128 |
| 3.2.2 | Flow Chart of Titanium Finishing Material | 129 |
| 3.3 | The Outstanding Characteristic of Titanium | 130 |
| 3.4 | Grain Structure of Titanium Alloy | 130 |
| 3.5 | Comparison of Properties of Titanium Steel, Stainless Steel and Aluminum | 131 |
| Working Methods | 132 – 143 | |
| 3.6 | Working on Titanium Alloy | 132 – 135 |
| 3.6.7 | Comparison of Working Speed of Titanium, High Speed Steel and Carbide | 134 – 135 |
| 3.6.8 | Forming & Deep Drawing | 136 – 137 |
| Forming | 136 | |
| Forming Temperatures for Unalloyed Titanium and Titanium Alloys | 136 | |
| Deep Drawing | 136 | |
| (a) | Lubrication | 136 |
| (b) | Comparison of physical and mechanical properties of Titanium, Stainless Steel (304 & 403) and mild steel | 137 |
| (c) | Bending test | 137 |
| 3.6.9 | Drilling | 138 |
| 3.6.10 | Grinding | 139 |
| Coolant | 139 | |
| Suitable Wheel Speed | 139 | |
| Vitrified bond (Vitrified Bond) A60 wheel | 139 | |
| Wheel Designation , Speed and Feeding of Materialµ | 139 | |
| 3.6.11 | Milling | 140 |
| 3.6.12 | Turning | 141 |
| Tool Geometry for Turning Titanium | 141 | |
| 3.6.13 | Jointing | 142 |
| 3.6.14 | Welding & Soldering | 142 |
| Welding | 142 | |
| Bending | 142 | |
| TIG | 142 | |
| Soldering | 143 | |
| Typical Solders and Soldering Temperatures | 143 | |
| 3.6.15 | Bending | 143 |
| Titanium Bending | ||
| 3.7 | Treatment | 144 |
| 3.7.1 | Surface Treatment | 144 |
| (a) | Nitriding | 144 |
| (b) | Glow Discharge Nitriding | 144 |
| (c) | Chromium Plating | 144 |
| (d) | Hard-facing Welding | 144 |
| 3.8 | Increasing Corrosion Resistance | 144 – 145 |
| 3.8.1 | Electroplating | 144 |
| Platinum Plating | 144 | |
| Pd O/T.o Coating | 144 | |
| 3.8.2 | Decorative Colour | 144 |
| 3.8.3 | Interference of colour by Atmospheric Oxidation | 145 |
| 3.8.4 | Interference of colour by Anode Oxidation | 145 |
| 3.8.5 | Lubricily | 145 |
| 3.9 | Heat Treatment | 146 |
| Solution Treatment & Aging (STA) | ||
| Duplex Solution Treatment & Aging (STSTA) | ||
| 3.10 | Descaling | 146 |
| 3.11 | Titanium – Type, Industrial Standard, Chemical Composition, Characteristic & end usage of the most commonly used Titanium & Titanium Alloy | 147 – 150 |
| 3.12 | 6Al-4V ELI & 6Al-4V Alloy | 151 – 157 |
| 3.12.1 | End Usages, Available Forms and Chemical Composition | |
| 3.12.2 | Mechanical Properties | 152 – 153 |
| 3.12.3 | Physical Properties | 154 |
| 3.12.4 | Fabrication | 155 |
| 3.12.5 | Heat Treatment | 156 |
| 3.12.6 | Smallest Bending Radius (r) | 157 |
| 3.13 | CP GR4 & GR2 Alloy | 158 – 161 |
| 3.13.1 | Mechanical Properties | 158 |
| 3.13.2 | Physical Properties | 159 |
| 3.13.3 | Fabrication | 160 |
| 3.13.4 | Heat Treatment | 160 |
| 3.13.5 | Technical Data | 161 |
| 3.14 | Titanium & Titanium Alloy Specifications Available Forms | 162 – 163 |
| Available Forms | 162 | |
| General Specifications | 163 | |
| Grading | 163 | |
| 3.15 | Titanium Alloy Military Use | 164 |
| Bar and reforge Stock (MIL-T-9047G) | 164 | |
| Sheet-Strip-Plate (MIL-T-9046J) | 164 | |
| 3.16 | Surface finish | 165 |
| 3.17 | Titanium Wire and Shaped Wire | 165 – 169 |
| 3.17.1 | End Usages | 165 |
| 3.17.2 | Size Available | 165 |
| 3.17.3 | Chemical Comparison and Mechanical Property(Annealed Condition) | 166 |
| 3.17.4 | Tolerance of Round Wire Diameter | 166 |
| 3.17.5 | Dimensional Profile of Flat and Half Round Wire | 167 |
| 3.17.6 | Chemical Composition of Titanium Wire and Rods for Welding | 167 |
| 3.17.7 | Comparison of Physical Properties of Titanium, Stainless Steel, Iron and Aluminum | 168 |
| 3.17.8 | Corrosion Resistance of Titanium | 168 |
| 3.17.9 | Weight in kg per one meter | 168 |
| 3.18 | Diameter of Mother Wire to Draw Hexagons or Square Wire | 169 – 170 |
| 3.19 | Weight Formula for Titanium | 171 – 172 |
| Rounds | 171 | |
| Squares | 171 | |
| Rectangles | 171 | |
| Hexagons | 171 | |
| Octagons | 171 | |
| Circles | 171 | |
| Sheet / Plate | 172 | |
| Round Seamless Tube | 172 | |
| Square Seamless | 172 | |
| Rectangular (Seamless Tubing) | 172 | |
| Ring | 172 | |
| 3.20 | Fire Preventive | 173 |
|
Supplement
|
||
| 4.0 | Nickel | 187 – 195 |
| 4.1 | Nickel in General | 187 |
| 4.2 | Origin | 188 |
| 4.3 | Refinery | 188 |
| 4.4 | Nickel Pellet | 188 |
| 4.5 | Monel | 189 |
| 4.6 | Constantan | 189 |
| 4.7 | Nichrome Wire | 189 |
| 4.8 | Permalloy | 189 |
| 4.9 | Nickel Silver | 190 |
| 4.10 | Nickalloy | 190 |
| 4.11 | Physical and Mechanical Properties of Nickel | 190 |
| 4.12 | High Nickel Alloys | 191 – 193 |
| 4.13 | Indentification of Copper and Lead Alloy by Physical Test | 194 |
| 4.14 | Electroplating Purpose Nickel | 195 |
| 5.0 | Zinc | 199 – 208 |
| 5.1 | Introduction | 199 |
| 5.2 | End Usages | 199 – 200 |
| (a) | Coating | 199 |
| (b) | Zinc Oxide | 199 |
| (c) | Die-casting | 199 |
| (d) | Alloying | 200 |
| (e) | Super Plastic Alloy | 200 |
| (f) | Roofing & Cladding | 200 |
| (g) | Nutrition | |
| 5.3 | Origin | 200 |
| 5.4 | Refinery | 201 |
| 5.5 | Production | 201 |
| 5.6 | Properties of zinc | 201 |
| 5.7 | Zinc Die-Casting Alloy | |
| 5.8 | Battery Grade Zinc Alloy (for making dry cell cans) | 202 |
| 5.9 | Special Zinc Anodes > 99.995% Zn | 203 |
| 5.10 | Special Highgrade Zinc > 99.995% Zn | 204 |
| 5.11 | Gravity Casting Alloy Zinc No.12 | 204 |
| 5.12 | Gravity Casting Alloy Zinc No.12 | |
| 5.13 | American Standard of Zinc | 206 |
| 5.14 | European standard (EN) of Zinc | 206 |
| 5.15 | Zinc Chemical composition to EN 11749(% ps mm2) | 206 |
| 5.16 | The Zinc trading in LME | 207 |
| 5.16.1 | Purity | 207 |
| 5.16.2 | Ingots – slabs & Jumbo | 207 |
| 5.17 | Nickel and other metal for Electroplating purpose | 207 – 208 |
| 6.0 | Cadmium | 209 |
| 6.1 | Cadmium(99.99% Cd minimum) | 209 |
| 7.0 | Lead | 210 – 212 |
| 7.1 | Lead in General | 210 |
| 7.2 | Corrosion | 210 |
| Alkali corrosion | 210 | |
| Condensation corrosion | 210 | |
| Lead Attack Aluminum | 210 | |
| 7.3 | Lead use in general | 211 |
| 7.4 | Battery use lead | 211 |
| 7.5 | Source and Production | 211 |
| 7.6 | Properties of Lead | 212 |
| 7.7 | Color Marking on Different Thickness of Lead | 212 |
| 7.8 | Melting Point of Lead and Other Materials | 212 |
| 8.0 | Tin | 213 – 214 |
| 8.1 | General | 213 |
| 8.2 | Chemical Composition of Tin Metal to JIS H2108 | 213 |
| 8.3 | Tin for Electroplating | 213 |
| 8.4 | Physical Properties of Pure Lead, Tin and Zinc | 214 |
| 9.0 | Magnesium | 215 – 217 |
| 9.1 | General | 215 |
| 9.2 | Physical properties of Magnesium | 215 |
| 9.3 | Mechanical Properties of Magnesium | 216 |
| 9.4 | Casting Magnesium Alloy and Forging Magnesium Alloy | 216 |
| 9.5 | Magnesium Casted Parts to JIS H5203 | 217 |
| 10.0 | Gold | 218 – 220 |
| 10.1 | General | 218 |
| 10.2 | Gold Alloy | 218 |
| 10.3 | Evaporation | 218 – 219 |
| 10.4 | Precious Metals & Alloy | 220 |
| 11.0 | Platinum | 221 |
| 12.0 | Heat Resistant Alloys and Stainless Steel | 223 – 224 |
| 12.1 | Heat – Resistance Stainless Steel | 223 |
| 12.2 | Chrome Heat Resistance Stainless Steel | 224 |
| 12.3 | Cr-Ni Heat Resistance Stainless Steel | 224 |
| 12.4 | Superior Heat Resistance Steel | 224 |
| 12.5 | Heat Resistance Super Alloy | 224 |
| 13.0 | Permalloy & Magnetic Alloy | 225 – 227 |
| 13.1 | Magnetic Materials – General | 225 |
| 13.1.1 | Soft Magnetic | 225 |
| 13.1.2 | Hard Magnetic | 225 |
| 13.1.3 | Magnetic Induction | 225 |
| 13.1.4 | Magnetic Permeability | 225 |
| 13.1.5 | magnetic force,magnetic field,electron | 226 |
| 13.2.1 | Soft Magnetic Alloys | 226 |
| 13.2.2 | Usages | 226 |
| 13.2.3 | Semi – Hard Magnetic Alloy | 226 |
| 13.2.4 | Usages | 226 |
| 13.3 | Hard Magnetic Alloys | 227 |
| 13.4 | End Usages of Hard Magnetic Alloys | 227 |
| 13.5 | Magnetostrictions Alloys | 227 |
| 13.6 | Alloys for Semi – Conductors & Electronic Tubes | |
| 13.7 | Alloys for Semi – Conductors & Electronic Tubes Use | 227 |
| 13.8 | Alloys for Semi – Conductors & Electronic Tubes – Chemical Composition & Characteristic | 228 |
| 13.9 | Anti – Corrosion and Heat – Resistant Spring Alloys | 228 |
| 13.10 | End Usages | 228 |
| 13.11 | Anti – Corrosion and Heat -Resistant Spring Alloys | 228 |
| 14.0 | Bi-Metal(Thermostat Metal) | 229 – 231 |
| Structure | 229 | |
| End Usages | 229 | |
| 14.1 | Bi-Metal, Chemical Composition and Expansion | 230 |
| 14.2 | Available sizes | 231 |
| 14.3 | Applications | 231 |
| 15.0 | Shape Memory Alloy & Super Elastic Alloy | 232 – 236 |
| 15.1 | Memory Alloy | 232 |
| 15.2 | Features | 232 |
| 15.3 | Memory Characteristics & Super Elastic Characteristics | 233 |
| 15.4 | Comparision of Memory Alloy & Steel | 233 |
| 15.5 | Chemical composition and shape-recovery temperature of shape memory alloy | 233 |
| 15.6 | Physical properties of shape memory alloys in comparison with titanium, copper and stainless steel | 234 |
| 15.7 | Mechanical properties | 235 |
| 15.8 | End usage examples | 235 |
| Control value of evaporated coffee maker | ||
| Joints of Micro-robot | ||
| Heat senser for power supply cable of mass transit system | 236 | |
| eye glasses | ||
| Garment Accessories | ||
| Temperature Control Device | 236 | |
| Greenhouse window switch | ||
| Medical appliance | ||
| Others | ||
| 16.0 | Tungsten | 237 |
| 16.1 | Tungsten Alloy | 237 |
| 17.0 | Manganese | 238 |
| 18.0 | Chromium | 239 |
| 19.0 | Molybdenum | 239 |
| 20.0 | Cobalt | 239 |
| 21.0 | Vanadium | 239 |
| 22.0 | Antimeny | 239 |
| 23.0 | Bismuth | 239 |
| 24.0 | Mercury | 240 |
| 25.0 | Metal Elements and their Properties | 241 |
