Final report
Aluminum Alloy 5052-H32
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- 3.11.4 Grade 430 Stainless Steel
- 3.12 5-CENT COIN 3.12.1
- Weight (g) Metal + Fabrication + USM Production – Scrap USM O/H + GA +
- 3.13 DIME AND QUARTER DOLLAR COINS 3.13.1
3.11.3 Aluminum Alloy 5052-H32 Aluminum alloy 5052 is strengthened by the addition of 2.5% Mg and 0.25% Cr. Hardening of this alloy is through solid solution strengthening and is enhanced by cold working. For the cupronickel-based alloys of the higher denomination coins, strip is typically delivered in a hard condition for optimum blanking, and then annealed soft for subsequent upsetting and striking. It is not clear if an aluminum alloy would require these same processing steps or if blanking and striking could both be managed under the same temper condition, thus eliminating an annealing step. While this cost savings is not yet factored into the calculations, it will be an important consideration when considering alloy options as will the possibility of cost savings from lower die fatigue (i.e., longer die life) due to lower required striking loads. Alloy 5052-H32 (i.e., alloy 5052 with an H32 heat treatment) is much harder than pure aluminum and is thought to provide a good balance between coinability and coin durability in circulation. Calculations are based upon quotations from multiple aluminum alloy suppliers. Aluminum also has a well-established recycling market for scrap. While 5052-H32 aluminum provides a significant cost savings over the incumbent one-cent coin materials, there is some uncertainty about United States Mint production costs. While the calculations represent the cost of production based upon the contributions from each process step, the United States Mint has not blanked nor upset one-cent coins in 30 years. Since the one-cent coin represents approximately half of the circulating coin production, adjustments to production and capital expenditures may be needed to allow for blanking and upsetting of an additional four- plus billion units per year. Aluminum alloys have been used for low-denomination coins in some countries including Japan, Korea, China and in some earlier European countries. There have been some reports of poor wear resistance, galling and jamming in coin-processing equipment; cold welding of aluminum coins during processing have been known to cause permanent damage to high-speed coin sorters/counters. The coin-processing equipment manufacturers and their clients are strenuously opposed to aluminum coinage for these reasons. Because of aluminum’s low density, more one- cent coins could be minted per pound than the incumbent material; approximately five aluminum one-cent coins would weigh the same as two incumbent one-cent coins. This weight difference would necessitate adjustments for weight-based coin counting and may be a challenge for coin acceptors that utilize a coin’s weight to trip a mechanical sorting device. Aluminum alloy 5052-H32 is very corrosion resistant and does not require a coating like steel and zinc; however, it is silver-white in color and could be confused with the dime coin. Coatings such as anodizing to provide a darker or more copper-like color to mimic the incumbent one-cent coin have been investigated. These coatings have not yet been found to be cost effective and some concepts are still in the research and development (R&D) stage. Previous studies for the Department of the Treasury performed in 1973 and 1980 [11, 12] have concluded that aluminum is an acceptable material for one-cent coins although various reasons such as reduced press speeds to prevent jamming during coin striking, corrosion issues, and light weight causing either 1) jamming in coin-acceptors or 2) galling or jamming in high-speed coin sorting/counting equipment prevented the production of aluminum one-cent coins. In addition, decreasing copper prices during the time of these reports reduced the interest in making a material change to aluminum one-cent coins. 161 3.11.4 Grade 430 Stainless Steel Although stainless steels are priced at a premium over carbon steels, no surface treatment is necessary for corrosion protection. Stainless steels are defined as containing greater than 12% chromium although they also contain other elements, importantly nickel. Ferritic stainless steels (4xx series) have relatively low nickel content and are a lower-cost option than the austenitic grades. Ferritic stainless steel coins are currently in use within other countries including India and Mexico. Grade 430 stainless steel is a commodity alloy that is available from multiple suppliers and has an established recycling market. Stainless steels are typically hard and require higher striking loads than incumbent coin materials. In addition, to facilitate quality striking of stainless steel, the design of the coin may have to be adjusted to a lower relief. The United States Mint direct production cost has been adjusted by a difficulty factor in that shorter die life is anticipated if one-cent coins were fabricated from 430 stainless steel. There are not significant cost savings if one-cent coins were to be minted from 430 stainless steel. Since the one-cent coin is not used by vending and most other coin-acceptance equipment, the ferromagnetic character of the coin is not a major concern and in fact may be a benefit to coin sorters, as a simple magnet may be used for sorting. However, the significantly shorter die life and restrictions on coin design are obstacles that may be best overcome with future research and alloy development instead of using the currently available 430 stainless steel. 3.11.5 Aluminized Steel One of the most economical means to provide corrosion protection for steel substrates is via hot dip coating. While zinc-coated steel (also known as galvanized steel) was considered in this study, it was not pursued due to the poor appearance such coins would have after only a short time in circulation. Galvanizing protects steel by acting as a sacrificial anode that corrodes preferentially to the steel. This results in a flaky gray corrosion product on galvanized steel. Aluminized steel is an alternative to galvanized steel and is used for industrial components such as mufflers, heat exchangers, ovens, common bake ware, as well as roofing and siding. Aluminized steel coins would be grey-white in color. Aluminized steel can be recycled as steel scrap; it is not practical or cost effective to separate the very thin aluminum surface layers. Aluminized steel is currently available only as coiled strip. During the blanking operation, unprotected blank edges would be exposed and thereby edges of the coin would be susceptible to corrosion. Issues such as higher striking loads (of steel-based materials), as discussed earlier, would also apply. In addition, annealing of the steel could not be achieved since the usual steel annealing temperature is above the melting point of aluminum. The aluminum surface would be susceptible to galling and cold welding, cited by the coin-processing equipment manufacturers as potentially damaging to their equipment. Aluminized steel strip is a commodity product that is available from a number of suppliers. 3.12 5-CENT COIN 3.12.1 Cupr onickel The starting stock material for the incumbent 5-cent coin is monolithic cupronickel coiled strip from either Olin Brass (Olin) or PMX Industries, Inc. (PMX); the same material is used as the clad layer on the dime, quarter dollar and half dollar coins. Coiled materials go through blanking, annealing, upsetting and striking at the United States Mint. The current cost of the 5-cent coin 162 has decreased relative to the FY2011 average cost due to decreasing commodity prices of copper and nickel. The fixed cost components of United States Mint plant overhead, G&A and distribution total $0.0322 for the 5-cent coin for FY2011. As shown in Figure 3-7, the metal cost of the 5-cent coin was 60% of the total cost in FY2011. This is the highest percentage of all US circulating coins; the primary reasons are the coin’s monolithic (i.e., not clad) construction, low fabrication costs and of all the US circulating coins the composition of the 5-cent coin has the highest percentage (25%) of costly nickel. Cost details for cupronickel and other alternative material candidates for the 5-cent coin are shown in Table 3 4. 60% 6% 5% 13% 0% 16% Figure 3-7. Cost components of the 5-cent coin (FY2011). Table 3-4. 5-Cent Coin Alternative Material Candidates Unit Costs Weight (g) Metal + Fabrication + USM Production – Scrap USM O/H + G&A + Distribution Total Unit Cost Savings vs. March 2012 Cost for 914M Coins Savings vs. USM FY2011 914M Coins 2011 5-Cent Coin (S) 5.00 $0.0796 $0.0322 $0.1118 - - 5-Cent March 2012 Costs (S) 5.00 $0.0674 $0.0322 $0.0995 - $11,206,159 G6 Mod (S) 4.72 $0.0499 $0.0322 $0.0821 $15,942,757 $27,184,957 669z (S) 4.79 $0.0491 $0.0322 $0.0813 $16,668,857 $27,911,057 Unplated 31157 (S) 4.58 $0.0401 $0.0322 $0.0723 $24,898,153 $36,140,353 Nickel-Plated 31157 (P) 4.26 $0.0673 $0.0322 $0.0995 $36,560 $11,278,760 Dura-White™-Plated Zn (P) 4.10 $0.0226 $0.0322 $0.0547 $40,910,640 $52,152,840 Multi-Ply-Plated Steel (P) 4.37 $0.0312 $0.0322 $0.0634 $32,995,400 $44,237,600 Nickel-Plated Steel (P) 4.40 $0.0448 $0.0322 $0.0770 $20,556,171 $31,798,371 CPZ (P) 4.06 $0.0199 $0.0322 $0.0520 $43,378,440 $54,620,640 302 Stainless Steel (S) 4.40 $0.0355 $0.0322 $0.0677 $29,041,632 $40,283,832 430 Stainless Steel (S) 4.40 $0.0163 $0.0322 $0.0485 $46,590,679 $57,832,879 G&A Dist. To FRB O/H Production Fabrication Metal 3.12.2 Alter native Copper Alloys A modified-copper alloy option for the 5-cent coin can retain the same EMS with a modest cost reduction, primarily by reducing the total nickel content in the alloy. Three alternative copper 163 alloys were identified: G6 modified (mod) (from Olin Brass), 76 669z 77 and 31157 (nickel plated and unplated). 78 Each of these alloys is proprietary to the respective producer. The cost of the metal in these alloys was calculated using the commodity costs of the component metals as of March 1, 2012. The supplier fabrication cost for these candidates are all assumed to be equivalent to that of the cupronickel 5-cent coin in 2011. The alternative copper alloys provide an 18–28% total unit cost reduction (as compared to March 2012 metal costs) for the incumbent 5-cent coin, and up to a 49% reduction in metals cost. However, if each of these materials ultimately result in about the same striking efficiency and EMS properties, then it may be possible to write the specification for a future alternative copper alloy for the 5-cent coin broadly so that all would be suitable. The specification could designate a fixed EMS, hardness, density and other properties so that the suppliers can compete on cost with their own version of an alloy that fits the specification. The United States Mint production of these candidates is expected be identical to that of cupronickel, although these candidates utilize a reduced annealing temperature over that for cupronickel. The incumbent 5-cent coin requires a higher annealing temperature than the dime, quarter dollar and half dollar coins and therefore dedicated furnaces, requiring additional maintenance and energy are needed. These candidate 5-cent coin alloys can be annealed at the same temperature as the dime, quarter dollar and half dollar coins resulting in associated cost savings. These associated cost savings are not reflected in Table 3-4. With a reduction in nickel content, the alternative copper alloys do not appear as white as the incumbent cupronickel coins. Alloys G6 mod and 669z have a yellowish cast, or a hint of yellow, while unplated 31157 has a more golden hue color. To ensure a white coin, JZP provided quotations on a nickel-plated (4 micron) 31157 alloy. However, this option does not provide for any significant cost savings because of the cost of plating and the limitations of cost reduction possible for RTS planchets versus coiled strip. If color is a lower order property than EMS, a slightly golden hue coin could be a seamless option with regard to the coin-processing equipment community. 3.12.3 Dur a-White™ 79 -Plated Zinc Dura-White is a proprietary patent-pending process developed by JZP to coat a zinc planchet with a copper and tin plating. The product can be thought of as a large tin-coated version of the incumbent one-cent coin. Tin is not an inexpensive alloying element, but the plating layer is thin and so the cost impact is limited. As a white metal, tin is a better choice than nickel for coating onto a zinc substrate. Electroplated nickel typically requires a stress relief annealing treatment after plating at a temperature higher than the melting point of zinc. The zinc alloy core of a Dura White-plated 5-cent coin does not contain tin and thus direct recycling back into coins is not possible. However, Dura-White-plated zinc coins could be recycled at a number of foundries that cast copper-tin-zinc alloys. As with all of the 5-cent alternative metal candidates, weights are reduced compared to the incumbent cupronickel alloy; this reduced weight may be cause for 76 Olin Brass researched and developed this material prior to the start of this project. Information about the alloy was provided pursuant to a Confidentiality Agreement between GBC Metals and CTC. 77 PMX has a patent pending for this alloy. 78 JZP has a patent pending for this alloy. 79 Dura-White™ is a trademark of Jarden Zinc Products, Greeneville, Tennessee. 164 concern for the bulk-coin-handling stakeholders as described in the Outreach Chapter. This copper/tin-plated zinc coin has a unique EMS, although different from the incumbent 5-cent coin. The costs of the coin were calculated from a JZP quote for Dura-White-plated zinc RTS planchets; United States Mint direct production costs were modified to reflect striking only. A Dura-White 5-cent coin was found to be approximately 36% lower in cost than the incumbent cupronickel 5-cent coin. 3.12.4 Multi-Ply-Plated Steel Multi-Ply-plated steel is a patented process developed by the RCM in which a flash nickel layer is plated onto low-carbon steel, followed by a (non-cyanide) plated-copper layer and a second nickel layer. The copper layer allows for EMS control (via its thickness) and the nickel outer surface provides a white coin with good wear resistance. The plating is applied to an upset steel blank and delivered as a RTS planchet. If a cyanide plating process is used, the copper layer can be deposited on the steel without the initial flash nickel coating; thus the process may provide equivalent EMS control utilizing a two-layer (Cu-Ni) plating as a Multi-Ply (Ni-Cu-Ni) plating. Multi-Ply-plated steel construction is used for circulating coins in Canada; in addition, the RCM is minting Multi-Ply-plated steel coins for several other countries. JZP manufactures Multi-Ply plated steel coins under license from the RCM, and there is a memorandum of understanding between the RCM and Sunshine Minting, Incorporated, Coeur d’Alene, Idaho, to license future production. Two domestic US sources could therefore provide Multi-Ply-plated steel planchets to the United States Mint. Although the RCM has provided pricing guidance, JZP has provided a quotation for the price calculations. A Multi-Ply-plated steel 5-cent coin would have a unique EMS; however, it would be different than that of cupronickel. More information is provided in the Outreach Chapter concerning the EMS of Multi-Ply-plated steel coins. It is important that the EMS, coupled with the coin’s dimensions (diameter and thickness), are used to provide for a truly unique coin, distinguishable from other Multi-Ply-plated steel coins in use around the world. The nickel- and copper-plated layers of Multi-Ply coins could not be economically separated and reclaimed for their recycling value and essentially worn coins would be classified as steel scrap. As seen in Table 3-4, the cost reduction projected with Multi-Ply-plated steel 5-cent coins is slightly more than that for the seamless alternative copper alloy candidates. 3.12.5 Nickel-Plated Steel (NPS) Estimated prices for NPS 5-cent RTS planchets were received from the Royal Mint and are included in Table 3-4. While the total cost of this candidate is reasonably low, it is higher than some of the alternative copper alloys. NPS also still has the concerns of higher striking loads and annealing temperature than cupronickel and it is not clear if the nickel layer, which is quite thick at 25 microns, could be recovered during recycling. NPS 5-cent coins have an EMS that is different than cupronickel and would need to be co-circulated as a non-seamless coin. In the UK, NPS 5- and 10-pence coins have recently been introduced as cupronickel-coin replacements. While the technology to electroplate nickel onto steel is mature, the ability of a domestic supplier to provide millions of planchets per week to the United States Mint needs to be developed to ensure a domestic source is available if this candidate material system is selected for construction of future 5-cent coins. 165 3.12.6 Stainless Steel Ferritic 430 stainless steel is a nickel-free alloy (Fe with 0.05% C and 17% Cr) while austenitic 302HQ stainless steel contains nickel (Fe with 18% Cr, 9% Ni and 3.5% Cu) and is higher in cost. Grade 302HQ stainless steel is a very low-carbon grade to reduce flow stress and increase ductility. The primary difference between these alloys, relative to use in circulating coins, is that 430 stainless steel is ferromagnetic and does not respond to annealing treatments; on the other hand, 302HQ stainless steel is non-ferromagnetic and can be softened by an annealing heat treatment. Of the commercially available grades of stainless steel, 302HQ was selected because it was developed to be a low-cost rivet alloy where extensive cold forming would be required. Grade 430 stainless steel was selected because of its proven use in some other country’s coinage (e.g., India and Mexico) as well as its low cost. An issue for either stainless steel grade is that the loads required to strike coins are higher than that required for the incumbent 5-cent coins; so a difficulty factor was calculated into the United States Mint direct production costs. For 302HQ stainless steel, the cost of a higher anneal temperature was also factored into this calculation. The material cost for 302HQ stainless steel was calculated using a quotation from Carpenter Technology, while material costs for 430 stainless steel were calculated from commodity metals prices. A web-scrap factor was also assigned to both materials, as these alloys would be supplied as coiled strip. The scrap credit was assumed to be 10% (approximately that of the 5-cent coin for 2011) of the total metal plus fabrication cost. Grade 302HQ stainless steel has an EMS that is different from cupronickel, although it is very similar to other austenitic stainless steel grades. Approximately 33% of fielded EMS sensors used to validate coins cannot recognize ferromagnetic 430 stainless steel since these sensors are not able to distinguish materials with an ability to be magnetized. 3.13 DIME AND QUARTER DOLLAR COINS 3.13.1 Cupr onickel-Clad Copper The starting stock for the dime and quarter dollar coins is cupronickel clad on a copper core; the material is produced by Olin and PMX as coiled strip. The description of the process and alloys are the same for both coins and are grouped together here for efficiency as any changes to the materials of construction would likely be implemented for both denominations simultaneously. The cost table for the dime (Table 3-5) only shows the costs/savings for the three alternative copper alloy candidates. Table 3-6 shows costs/savings for additional material candidates; quotations for these other alternative material candidates were only received for the quarter dollar coin. As with the 5-cent coin, the starting stock coils for the dime and quarter dollar coins are blanked, annealed and upset prior to striking; however some of the alternative material candidates shown in Table 3-6 are plated and supplied as RTS planchets. The quarter dollar coin is the most utilized coin for vending and other machines designed for unattended points of sale, followed by the dime coin. Due to their use rate in circulation and due to their higher value, EMS and security take on added importance for the quarter dollar coin than for the one-cent or 5-cent coins; therefore, monolithic candidates have not been selected for the quarter dollar coin in the present study. It is difficult for a counterfeiter to produce a one-cent or a 5-cent slug for much less than face value, but attempts at counterfeiting become more attractive as the coin face value increases. In 166 addition, the dime and quarter dollar coins are at a relatively high positive seigniorage and so the expense of higher security materials, such as clad sheet, can be tolerated. Furthermore, a clad construction using materials having the proper properties would minimize or eliminate the conversion cost to many stakeholders to upgrade their coin-processing equipment to recognize the alternative coins. 44% 12% 8% 21% 1% 15% 56% 15% 3% 9% 1% 16% Metal Fabrication Production O/H Dist. To FRB G&A Figure 3-8. Cost components of the dime (left) and quarter dollar (right) coins (FY2011). Table 3-5. Dime Coin Alternative Material Candidates Unit Costs Download 4.8 Kb. Do'stlaringiz bilan baham: |
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