CA2816320C - Low lead ingot - Google Patents

Abstract

A composition for a low lead ingot comprising primarily copper and including tin, zinc, sulfur, phosphorus, nickel. The composition may contain manganese. The low lead ingot, when solidified, includes sulfur or sulfur containing compounds such as sulfides distributed through the ingot. The presence and a substantially uniform distribution of these sulfur compounds imparts improved machinability and better mechanical properties.

Description

. , Low Lead Ingot BACKGROUND OF THE INVENTION
100021 Current plumbing materials are typically made from lead containing copper alloys. One standard brass alloy formulation is referred to in the art as C84400 or the "81,3,7.9" alloy (consisting of 81% copper, 3% tin, 7% lead, and 9% zinc) (herein in after the "81 alloy"). While there has been a need, due to health and environmental issues (as dictated, in part, by the U.S.
Environmental Protection Agency on maximum lead content in copper alloys for drinking water applications) and also for cost reasons, to reduce lead contained in plumbing fitting, the presence of lead has continued to be necessary to achieve the desired properties of the alloy. For example.
the presence of lead in a brass alloy provides for desirable mechanical characteristics and to assist in machining and finishing the casting. Simple removal of lead or reduction below certain levels substantially degrades the machinability as well as the structural integrity of the casting and is not practicable.
100031 Removal or rcduction of lead from brass alloys has been attempted previously. Such previous attempts in the art of substituting other elements in place of lead has resulted in major machining and finishing issues in the manufacturing process, which includes primary casting, primary machining, secondary machining, polishing, plating, and mechanical assembly.
100041 Several low or no lead formulations have previously been described.
See, for example, products sold under the trade names SeBiLOY* or EnviroBrasse:, Federalle, and EcoBrase as well as U.S. patents 7,056,396 and 6,413,330. Figure 1 is a table that includes the formulation of several known alloys based upon their registration with the Copper Development Association.

The existing art for low lead or no lead copper based castings consists of two major categories:
silicon based materials and bismuth/selenium materials.
100051 However, there is a need for a low-lead casting solution providing a low-cost alloy with similar properties to current copper/lead alloys without degradation of mechanical properties or chemical properties, as well as significant disruption to the manufacturing process because of lead substitution in the material causing cutting tool and finishing problems.
SUMMARY OF THE INVENTION
f00061 One embodiment of the invention relates to a semi-red brass having a composition of about 83% to about 91% copper, about 0.1% to about 0.8% sulfur, about 2.0% to about 4.0% tin, less than about 0.09% lead, about 4.0% to about 14.0% zinc, and about 1.0% to about 2.0%
nickel.
100071 One embodiment of the invention relates to a tin bronze having a composition of about Rh% in about R9% copper, about 0.1% to about 0.8% sulfur, about 7.5% to about 8.3% tin, less than 0.09%, lead, about 1.0% to about 5.0%, zinc, and about 1.0% nickel.
(0008jAdditional features, advantages, and embodiments of the present disclosure may be set forth from consideration of the following detailed description, drawings, and claims. Moreover, it is to be understood that both the foregoing summary of the present disclosure and the following detailed description are exemplary and intended to provide further explanation without further limiting the scope of the present disclosure claimed.

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[0008A] In a broad aspect, the invention provides a cast alloy composition consisting essentially of a copper content from 83 wt% to 91 wt%, a sulfur content from 0.1 wt% to 0.8 wt%, a tin content from 2.0 wt% to 4.0 wt%, a lead content of less than 0.09 wt%, a zinc content from 4.0 wt% to 14.0 wt%, and a nickel content from 1.0 wt% to 2.0 wt%. The alloy also comprises an iron content of less than 0.1 wt%, an antimony content of less than 0.02 wt%, a phosphorous content from greater than 0 wt% and less than 0.05 wt%, an aluminum content of 0.005 wt%, a manganese content from 0.01 wt% to 0.7 wt%, a carbon content of from greater than 0 wt%
to 0.5 wt%, and a titanium content of from greater than 0 wt% to 0.5 wt%.
10008B1 In another aspect, the invention further provides a cast alloy composition consisting essentially of a copper content of from 83 wt% to 89 wt %, a sulfur content of from 0.1 wt%
to 0.8 wt%, a tin content of from 2.0 wt% to 4.0 wt%, a lead content of less than 0.09 wt%, a zinc content of from 4.0 wt% to 14.0 wt%, an iron content of less than 0.01 wt%, an antimony content of less than 0.02 wt%, a nickel content of from 1.0 wt% to 2.0 wt%, a phosphorus content of less than 0.05 wt%, an aluminum content less than 0.005 wt%, a silicon content less than 0.005 wt%, and a manganese content of 0.02 wt%.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] The foregoing and other aspects, features, and advantages of the disclosure will become more apparent and better understood by referring to the following description taken in conjunction with the accompanying drawings, in which:
[00101 Figure 1 provides Table 1 listing formulations for several known commercial copper alloys.
-2a-PCT/US2011/058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:13PM FOLEY & LARDNER NO. 7886 P. 19/78 Attny Docket No 055665-5144Pa 100111 Figure 2 provides Table 2 listing formulations for Alloy Groups in accordance with embodiments of the present invention.
(00121 Figure 3A provides Table 3 listing alloy formulations for Group 1-A
mechanical property examples by their respective casting heat. Figure 3B provides Table 4 listing the results of the average mechanical property testing of Group I-A by their respective casting heat.
(0013) Figure 4A provides Table 5 listing alloy formulations for Group mechanical property examples by their respective casting heat. Figure 4B provides Table 6 listing the results of the average mechanical property testing of Group 1-B.
100141 Figure 5A provides Table 7 listing alloy formulations for Group II-A
mechanical property examples by their respective casting heat. Figure 5B provides Table 8 listing the results of the average mechanical property testing of Group II-A.
100151 Figure 6 provides Table 9 listing the typical and minimum properties observed for embodiments of certain Alloy Groups of the present invention and those properties reported for commercially available alloys such as those in Table 1 (Figure 1).
[0016] Figure 7 provides Table 10 listing the alloy compositions utilized for the SEM/EDS
testing.
100171 Figures 8A and 8B illustrate element mapping of (0.16% S) sulfur in Alloy 1-A-1 0a.
[00181 Figure 9A is an SEM of Alloy I-A-10a; Figures 9B-H illustrate element mapping; Figure 98 is an EDS for Sn; Figure 9C is an EDS for Zn; Figure 9D is an EDS for Cu;
Figure 9E is an EDS for Fe; Figure 9F is an EDS for Ni; Figure 9G is an EDS for P; Figure 9H
is an EDS for S.
(0019) Figure 10A is a micrograph of Alloy I-A-10a, with regions 1, 2, and 3 marked; Figures 10B-D show the presence of Cu2S, ZnS and Cu-Zn intermetallic phases: Figure 1013 is an EDS
spectra from region 1; Figure 10C is an EDS spectra from region 2; Figure 10D
is an EDS
spectra from region 3.
(00201 Figures 11A-B are optical images of Alloy I-A-10a at low (Figure 11A) and high magnifications (Figure 11B).

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[0021] Figure 12A is a SEM of alloy I-B-10a and 12B illustrate element mapping of sulfur in Alloy I-8-10a (0.31% S).
[0022) Figure 13A is an SEM of Alloy I-B-10a; Figures 13B-H illustrate element mapping at 1000x magnification; Figure 1313 is an EDS for Sn; Figure 13C is an EDS for Zn; Figure 13D is an EDS for Cu; Figure 13E is an EDS for Fe; Figure 13F is an EDS for Ni;
Figure 13G is an EDS for P; Figure 13H is an EDS for S.
[0023) Figure 14A is an SEM of Alloy I-B-10b (0.13% 5); Figures 14B-H
illustrate element mapping at 5000x magnification; Figure 148 is an EDS for Si; Figure 14C is an EDS for S;
Figure 14D is an EDS for Fe; Figure 14E is an EDS for Cu; Figure 14F is an EDS
for Zn; Figure 140 is an EDS for Sn; Figure 14H is an EDS for Pb; Figure 141 is an EDS for Ni.
[0024] Figures 15A-B are optical images of Alloy I-B-10a (0.31% S) at low (Figure 15A) and high magnifications (Figure 15B).
100251 Figures 16A and 168 illustrate element mapping of sulfur in Alloy II-A-1 0a (0.30% S).
[0026) Figure 17A is an SEM of Alloy Figures 17B-H illustrate element mapping;
Figure 17B is an EDS for Sn; Figure 17C is an EDS for Zn; Figure 17D is an EDS
for Cu; Figure 17E is an EDS for Fe; Figure 17F is an EDS for Ni; Figure 17G is an EDS for P;
Figure 17H is an EDS for S.
[0027) Figure 18A is an SEM of Alloy II-A-10b (0.19% S); Figures 18B-I
illustrate element mapping at 1000x magnification; Figure 1813 is an EDS for Si; Figure 18C is an EDS for S;
Figure 18D is an EDS for Fe; Figure 18E is an EDS for Cu; Figure 18F is an EDS
for Zn; Figure 180 is an EDS for Sn; Figure 1811 is an EDS for Pb; Figure 181 is an EDS for Ni.
[0028] Figures 19A-B are optical images of Alloy 11-A at low (Figure 19B) and high magnifications (Figure 19A).
[0029] Figures 20A and 208 illustrate element mapping of sulfur in Alloy III-A
(0.011% S).
[0030) Figure 21A is an SEM of Alloy III-A; Figures 218-H illustrate element mapping; Figure 21B is an EDS for So; Figure 21C is an EDS for Zn; Figure 21D is an EDS for Cu; Figure 21E is

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an EDS for Pe; Figure 21F is an EDS for Ni; Figure 21G is an EDS for P; Figure 21H is an EDS
for S.
[00311 Figures 22A-B are optical images of Alloy III-A at low (Figure 22A) and high magnifications (Figure 22B).
[00321 Figure 23 is a sulfur free-energy diagram of primary sulfides formed in Group I-A, I-B &
11-A alloys.
[0033] Figure 24 is a vertical section of different alloys in the Cu-Sn-Zn-S
alloys [0034] Figure 25A is a phase distribution diagram of alloy I-A-11 a using Sch.eil cooling, Figure 258 is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
[0035] Figure 26A is a phase distribution diagram of alloy I-A-11b using Schell cooling, Figure 26B is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
[0036] Figure 27A is a phase distribution diagram of alloy I-A-11c using Schell cooling, Figure 27B is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
[0037] Figure 28A is a phase distribution diagram of alloy I-A-I I d using Schell cooling, Figure 28B is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
[0038] Figure 29A is a phase distribution diagram of alloy I-A-I le using Schell cooling, Figure 29/3 is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
[0039] Figure 30A is a phase distribution diagram of C83470 commercial alloy (Table 1, Figure 1) using Scheil cooling, Figure 30B is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
[0040] Figure 31 is phase diagram of Vertical Section of Group 1-A.

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PCT/US2011/058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:15PM FOLEY & LARDNER NO. 7886 P. 22//8 Attny pocket No 055665-5144PC1 10041] Figure 52A is a Schell Phase assemblage diagram of Group 1-A, Figure 32B is a magnified Scheil Phase assemblage diagram of Group 1-A.
100421 Figure 33 is a vertical Section of Group I-B.
[0043] Figure 34A is a Scheil Phase assemblage diagram of Group I-B Fig, 34B
is a magnified Scheil Phase assemblage diagram of Group I-B.
[0044] Figure 35 is a vertical Section of Group II-A.
[0045] Figure 36A is a Scheil Phase assemblage diagram of Group II-A, Figure 36B is a magnified Schell Phase assemblage diagram of Group II-A.
[0046] Figure 37 is a graph of ultimate tensile strength CUTS) showing various heats of Alloy Group 1-A compared to several known alloys, indicated by their CDA number.
[0047] Figure 38 is a graph of yield strength showing various heats of Alloy Group 1-A
compared to several known alloys, indicated by their CDA number.
[0048] Figure 39 is a graph of elongation showing various heats of Alloy Group 1-A compared to several known alloys, indicated by their CDA number.
[0049] Figure 40 is a graph of ultimate tensile strength (UTS) showing various heats of Alloy Group 1-B compared to several known alloys, indicated by their CDA number.
[0050] Figure 41 is a graph of yield strength showing various heats of Alloy Group 1-B
compared to several known alloys, indicated by their CDA number.
[0051] Figure 42 is a graph of elongation showing various heats of Alloy Group 1-B compared to several known alloys, indicated by their CDA number.
[0052] Figure 43 is a graph of ultimate tensile strength (UTS) showing various heats of Alloy Group II-A compared to several known alloys, indicated by their CDA number.
(0053) Figure 44 is a graph of yield strength showing various heats of Alloy Group II-A
compared to several known alloys, indicated by their CDA number.

-6-[AMENDED SHEET(ART 34) 100541 Figure 45 is a graph of elongation showing various heats of Alloy Group II-A compared to several blown alloys, indicated by their CDA number.
100551 Figure 46A illustrates the sulfide particle sizes for a commercial sulfur brass, Bi Waken.' (C83470) and Figure 46B is photomicrograph showing particle size of Group I-A
alloy (.13 S ¨
4.45 Zn ¨3.63 Sn).
100561 The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of necessary fee.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
(0057) In the following detailed description, reference is made to the accompanying drawings, which form a part hereof. In the drawings, similar symbols typically identify similar components, unless context dictates otherwise. The illustrative embodiments described in the detailed description, drawings, and claims are not meant to be limiting. Other embodiments may be utilized, and other changes may be made, without departing from the scope of the subject matter presented here. It will be readily understood that the aspects of the present disclosure, as generally described herein, and illustrated in the figures, can be arranged.
substituted, combined, and designed in a wide variety of different configurations, all of which are explicitly contemplated and made part of this disclosure.
100581 In one embodiment, the invention relates to a composition of matter and methods for making same. The composition of matter is a copper-based alloy having a "low"
level of lead as would be understood by one of ordinary skill in the art of cavity devices that make contact with potable water, including, for example, plumbing fixtures. The level of lead is below that which are normally used to impart the beneficial properties to the alloy necessary for usefulness in most applications, such as tensile strength, elongation, machinability, and pressure tightness. Prior art no-lead alternatives to leaded brass typically require changes to the metal feeding for sand castings in order to produce sufficient pressure tightness (such as having no material porosity).
The alloys of the present invention include particular amounts of sulfur, and in certain

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embodiments, the sulfur is added through a preferred method, to impart the beneficial properties lost by the reduction in lead.
100591 The alloys of the present invention relate generally to formulations of suitable semi-red brass, tin-bronze, and yellow brass, Certain embodiments are formulated for use primarily in sand cast applications, permanent mold cast applications, or wrought applications.
100601 Table 2 (Figure 2) illustrates a group of alloys in accordance with the present invention.
Each of the alloys is characterized, at least in pat, by the relative low level of lead (about 0.09%
or less) and the presence of sulfur (about 0.1% to 0.8%).Three groups of semi-red brass, labeled Alloy Group I-A, Alloy Group I-B, and Alloy Group IC are provided. In one embodiment, these semi-red brass alloys are suitable for sand casting. Three groups of tin bronze, labeled Alloy Group II-A, Alloy Group 11-B, and Alloy Group II-C are provided. In one embodiment, these tin bronze alloys are suitable for sand casting. Six groups of yellow brass, labeled Alloy Group Alloy Group III-B, Alloy Group Alloy Group N-A, Alloy Grow N-B, and Alloy Group N-C are provided. In one embodiment the Alloy Group III alloys are suitable for permanent mold casting. In one embodiment, the Alloy Group IV alloys are suitable for wrought applications.
Alloy components [00611 The alloys of the present invention comprise copper, zinc, tin, sulfur, nickel, and phosphorus. In certain embodiments, one or more of manganese, zirconium, boron, titanium and/or carbon are included. Embodiments, other than Group IV wrought yellow brass, also include one or more of antimony, tin, nickel, phosphorus, aluminum, and silicon.
(0062] The alloys, comprise as a principal component, copper. Copper provides basic properties to the alloy, including antimicrobial properties and corrosion resistance.
Pure copper has a relatively low yield strength, and tensile strength, and is not very hard relative to its common alloy classes of bronze and brass. Therefore, it is desirable to improve the properties of copper for use in many applications through alloying. The copper will typically be added as a base ingot. The base ingot's composition purity will vary depending on the source mine and post-

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mining processing. Therefore, it should be appreciated that ingot chemistry can vary, so, in one embodiment, the chemistry of the base ingot is taken into account For example, the amount of zinc in the base ingot is taken into account when determining how much additional zinc to add to arrive at the desired final composition for the alloy. The base ingot should be selected to provide the required copper for the alloy while considering the secondary elements in the base ingot and their intended presence in the final alloy since small amounts of various impurities, such as iron, are common and have no material effect on the desired properties.
100631 Lead has typically been included as a component in copper alloys, particularly for applications such as plumbing where machinability is an important factor. Lead has a low melting point relative to many other elements common to copper alloys. As such, lead, in a copper alloy, tends to migrate to the interdendritic or grain boundary areas as the melt cools.
The presence of lead at interdendritic or grain boundary areas can greatly improve niachi ability and pressure tightness. However, in recent decades the serious detrimental impacts of lead have made use of lead in many applications of copper alloys undesirable. In particular, the presence of the lead at the interdendritic or grain boundary areas, the feature that is generally accepted to improve machinability, is, in part, responsible for the unwanted ease with which lead can leach from a copper alloy.
[00641 Sulfur is added to the alloys of the present invention to overcome certain disadvantages of using leaded copper alloys. Sulfur present in the melt will typically react with transition metals also present in the melt to form transition metal sulfides. For example, copper sulfide and zinc sulfide may be formed, or, for embodiments where manganese is present it can form manganese sulfide. Figure 23 illustrates a free-energy diagram for several transition metal sulfides that may form in embodiments of the present invention. The melting point for copper sulfide is 1130 Celsius, 1185 Celsius for zinc sulfide, 1610 Celsius for manganese sulfide, and 832 Celsius for tin sulfide. Thus, without limiting the scope of the invention, in light of the free energy of formation, it is believed that a significant amount of the sulfide formation will be zinc sulfide for those embodiments having no manganese. It is believed that sulfides that solidify

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after the copper has become to solidify, thus forming dendrites in the melt, aggregate at the interdendtic areas or grain boundaries.
10065] Sulfur provides similar properties as lead would impart to a copper alloy, without the health concerns associated with lead. Sulfur forms sulfides which it is believed tend to aggregate at the interdendritic or grain boundary areas. The presence of the sulfides provides a break in the metallic structure and a point for the formation of a chip in the grain botmdary region and improve machining lubricity, allowing for improved overall machinabffity. The sulfides predominate in the alloys of the present invention provide lubricity. Good distribution of sulphides improves pressure tightness, as well as, machinability.
10066] It is believed that the presence of tin in some embodiments increases the strength and hardness but reduces ductility by solid solution strengthening and by forming Cu-Sn intermetallic phase such as Cu3Sn. It also increases the solidification range.
Casting fluidity increases with tin content Tin also increases corrosion resistance. However, currently Sn is very expensive relative to other components.
10067] With respect to zinc, it is believed that the presence of Zn is simiLsr to that of Six, but to a lesser degree, in certain embodiments approximately 2% Zn is roughly equivalent to 1 % Sn with respect to the above mentioned improvements to characteristics noted above. Zn increases strength and hardness by solid solution hardening_ However, Cu-Zn alloys have a short freezing range. Zn is much less expensive than Sn.
10068] With respect to certain embodiments, iron can be considered an impurity picked up from stirring rods, skimmers, etc during melting and pouring operations, or as an impurity in the base ingot Such categories of impurity have no material effect on alloy properties.
100691 For red brass and tin bronzes, antimony may be considered an impurity in the described alloys. Typically, antimony is picked up from inferior brands of tin, scrap and poor quality of ingots and scrap. However, antimony is deliberately added to yellow brasses in a permanent mold to increase the dezincification resistance.

!AMENDED SHEET(ART 34)1 PCT/US2011 /058448 1PEA/KR (27-08-2012) AU(. 2/. 2012 3 1 8 PM FOLEY & LARDNER O. 7886 P. 27/78 Attny Docket No 055665-5144PC1 (00701 In some embodiments, nickel is included to increase strength and hardness. Further, nickel aids in distribution of the sulfide particles in the alloy. In one embodiment, adding nickel helps the sulfide precipitate during the cooling process of the casting. The precipitation of the sulfide is desirable as the suspended sulfides act as a substitute to the lead for chip bruiting and machining lubricity during the post casting machining operations. With the lower lead content, it is believed that the sulfide precipitate will minimize the effects of Lowered machiztability.
[0071) Phosphorus may be added to provide deoxidation. The addition of phosphorus reduces the gas content in the liquid alloy, Removal of gas generally provides higher quality castings by reducing gas content in the melt and reducing porosity in the finished alloy.
However, excess phosphorus can contribute to metal-mold reaction giving rise to low mechanical properties and porous castings.
[0072) Aluminum is, in some embodiments, such as semi-red brasses and tin bronzes, treated as an impurity. In such embodiments, aluminum has harmful effects on pressure tightness and mechanical properties. However, aluminum in yellow brass castings can selectively improve casting fluidity. It is believed that aluminum encourages a fine feathery dendritic structure in such embodiments.
[00731 Silicon is also considered an impurity. In foundries with multiple alloys, silicon based materials can lead to silicon contamination in non silicon contaking alloys. A
small amount of residual silicon can contaminate semi red brass alloys, making production of multiple alloys near impossible. In addition, the presence of silicon can reduce the mechanical properties of semi-red brass alloys.
[00741 Manganese may be added in certain embodiments. The manganese is believed to aid in the distribution of sulfides. In particular, the presence of manganese is believed to aid in the formation of and retention of zinc sulfide in the melt. In one embodiment, a small amount of ingnganese is added to improve pressure tightness. In one embodiment, manganese is added as MnS.
[0075) Either zirconium or boron may be added individually (not in combination) to produce a fine grained structure which improves surface finish of castings during polishing.

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[0076] Carbon may be added in certain embodiments to improve pressure tightness, reduce porosity, and improve machinability.
100171 Titanium may be added in combination with carbon, such as in graphite form. Without limiting the scope of the invention, it is believed that the titanium aides in bonding the carbon particles with the copper matrix, particularly for raw graphite. For embodiments utilizing copper coated with carbon, titanium may not be useful to distribute the carbon.
Alloy Characteristics [0078] In one embodiment, an alloy of the present invention solidifies in a manner such that a multitude of discrete particles of sulfur/sulfide are distributed throughout in a generally tmiform manner throughout the casting. These nonmetallic sulfur particles serve to improve lubricity and break chips developed during the machining of parts cast in this new alloy, thereby improving machinability with a significant or complete reduction in the amount of lead.
Without limiting the scope of the invention, the sulfides are believed to improved lubricity.
[0079] The preferred embodiments of the described alloy retain machinability advantages of the current alloys such as the "81" alloy or a similar leaded alloy. Further, it is believe that due to the relative scarcity of certain materials involved, the preferred embodiments of the ingot alloy will cost considerately less than that of the bismuth and/or selenium alloyed brasses that are currently advocated for replacement of leaded brass alloys such as "81". The sulfur is present in certain embodiments described herein as a sulfide which is soluble in the melt, but is precipitated as a sulfide during solidification and subsequent cooling of the alloy in a piece part. This precipitated sulfur enables improved machinability by serving as a chip breaker similar to the function of lead in alloys such as the "81" and in bismuth and selenium alloys. In the case of bismuth and/or selenium alloys the formation of bismuthides or selenides, along with some metallic bismuth, accomplishes a similar objective as this new sulfur containing alloy. The improvement in machinability may show up as increased tool life, improved machining surfaces, reduced tool forces, etc. This new idea also supplies the industry with a low lead brass/bronze AMENDED SHEENRT 34) PCT/US2011 /058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:19PM FOLEY & LARDNER NO. 7886 P. 29/78 Attny Docket No 055665-5144PCT
which in today's environment is seeing any number of regulatory authorities limit by law the amount of lead that can be contained in plumbing fittings.
[0080] Further, alloys to which lead has been added result in an increase in the temperature range over which solidification occurs, normally making it more difficult to produce a leak tight casting, critical in plumbing fittings. However, lead segregates to the last regions to solidify and thereby seals the interdendritic and grain boundary shrinkage which occurs.
This sealing of interdendritic or grain boundary porosity is not accomplished in the sulfur/sulfide containing alloys. Neither is it accomplished in the bismuth and/or selenium alloys.
While bismuth is similar to lead in the periodic table of the elements, and expands during solidification, the amount of bismuth used is small compared to the amount of lead in conventional alloys such as the "81". Bi is typically present in commercial alloys in the elemental form.
[0081] One of ordinary skill will appreciate the additional benefits beyond the performance properties of the present alloys. Compared to bismuth and selenium the alloys of.the present Invention utilize abundantly found elements, whereas both bismuth and selenium are in relatively limited supply; and the conversion of brass castings to these materials will significantly increase the demand for these limited supply materials. In addition, bismuth has some health concerns associated with its use in plumbing fixtures, in part due to its proximity to lead as a heavy metal on the periodic table. Further, in certain embodiments, the alloys of the present invention utilizes a lower percent of copper than prior art bismuth and selenium compositions.
Yield Benefits 100821 It has been observed that the use of sulfur as a substitute for lead rather than silicon -provides superior "yield per melt". With sulfur, the yield per melt ranges from 70 to 80% as compared to silicon which can yield 40 to 60% per melt. Normal leaded brass alloys yield 70 to 80% depending upon process efficiency. As can be appreciated by one of ordinary skill, such an increase in yield reflects a substantial cost of goods differential, Therefore, the capacity of the metal casting facility is significantly reduced utilizing the silicon based materials, Also, certain embodiments of the present invention have a lower zinc content than the silicon based prior art 4822.6303.2592 CA 02816320 2013-04-26 IVENDED $HEET(ART.34)1 PCT/US2011/058448 IPEA/KR (27-08-2012) AUG, 27.2012 3:19PM FOLEY & LARDNER NO. 7886 P. 30/78 Attny Docket No 055665-5144PCT
alloys which normally contain upwards of 30% of zinc which can lead to leaks due to the interaction of the zinc and water resulting in corrosion. The lower, relative to those silicon based alloys, zinc of the present invention reduces the tendency for de-zincification. Further, if typically the product is to be finished with a chrome plated surface, the silicon based materials require a copper or tin strike prior to plating which increases the cost of the plating. The alloys of the present invention do not require the additional step (and its associated costs) to allow for chrome plating.
Melt Process (0083] In one embodiment, graphite is placed on the bottom of the crucible prior to heating. In one embodiment, silicon carbide or clay graphite crucibles may be used in the melts. It is believed that the use of graphite reduces the loss of zinc during the heat without substantially becoming incorporated into the final alloy_ In one embodiment, approximately two cups of graphite are used for a 90 to 95 lbs capacity crucible. For the examples used herein, a B-30 crucible was used for the melts) which has a capacity of 90 to 95 lbs of alloy.
(00841 Based upon the desired end alloy's formulation, the required base ingot is placed in the crucible and the furnace started. The base ingot, is brought to a temperature of about 2,100 degtees Fahrenheit to form a melt. In one embodiment a conventional gas-fired furnace is used, and in another an induction furnace is used. The furnace is then turned off, i.e. the melt is no longer heated. Then the additives, except, in one embodiment, for sulfur and phosphorus, arc then plunged into the melt between 15 to 20 seconds to achieve desired levels of Za, Ni and Sir.
The additives comprise the materials needed to achieve the final desired alloy composition for a given base ingot. In one embodiment, the additives comprise elemental forms of the elements to be present in the final alloy. Then a partial amount of slag is skimmed from the top of the melt (00851 The furnace is then brought to a temperature of about 2,140 Fahrenheit The furnace is then shut off and the sulfur additive is plunged in. For certain embodiments having phosphorus added, such as for degassing of the melt, the furnace is then reheated to a temperature of about 2,150 degrees Fahrenheit and phosphorous is plunged into the melt as a Cu-P
master alloy.

iptiENDEO SHENAR, PCT/US2011/058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:20PM FOLEY & LARDNER NO. 7886 P. 31/78 Attny Docket No 055665-5144PCT
Next, preferably all of the slag is skimmed from the top of the crucible. Tail castings for pressure testing and evaluation of machinability and plating, buttons, wedges and mini ingots for chemical analysis, and web bars for tensile testing are poured at about 2100, kora 2040, and about 2000 F respectively. In one embodiment, the furnace is fired to about 2,140 Fahrenheit for Alloy Groups I-A and 1-B. In another embodiment, the furnace is fired to about 2,050 Fahrenheit for Alloy Group II-A.
Testing/Examples [0086] Machinability testing described in the present application was performed using the following method. The piece parts were machined by a coolant fed, 2 axis, CNC
Turning Center. The cutting tool was a carbide insert. The machinability is based on a ratio of energy that was used during the turning on the above mentioned CNC Turning Center.
The calculation formula can be written as follows:
CF=(EI/B2)x 100 CF = Cutting Force E1 Energy used during the turning of the New Alloy.
Energy used during the turning of a "known" alloy C 36000 (CDA).
Feed rate = .005 IPR
Spindle Speed 1,500 RPM
Depth of Cut '= Radial Depth of Cut= 0.038 inches 100871 An electrical meter was used to measure the electrical pull while the cutting tool was under load. This pull was captured via milliamp measurement Mechanical Properties [0088] Mechanical properties of various embodiments of the present alloys were tested. Figures 3A-6 correspond to the specific tested formulations and the corresponding results for the Alloy Group I-A, Alloy Group I-B, and Alloy Group 11-A.
100891 Figures 3A and 3B correspond to the specific tested formulations and the corresponding results for the Alloy Group I-A. Eight sample heats, prepared in accordance with the process above to achieve a Group I-A alloy, were tested for ultimate tensile strength ("UTS"), yield siisE Tit AR T.34) PCT/US2011/058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:21PM FOLEY & LARDNER NO. 7886 P. 32/78 Attny uocKet No 055665-5144PCT
strength ("YS"), percent elongation ("E%"), Brinnell beakless ("WIN"), and Modulus of Elasticity ("MoE"). The average for the eight Alloy Group I-A alloys was 40.25 ksi for ultimate tensile strength, 17.1 ksi for yield strength, 47 for percent elongation, 63 for Brinnell hardness, and 13.5 Mpsi for Modulus of Elasticity.
[0090)Figures 4A and 4B correspond to the specific tested formulations and the corresponding results for the Alloy Group I-B. Seven sample heats, prepared in accordance with the process above to achieve a Group I-B alloy, were tested for ultimate tensile strength, yield strength, percent elongation, Brinnell hardness, and Modulus of Elasticity. The average for the seven Alloy Group I-B alloys was 38.1 ksi for ultimate tensile strength, 17.5 ksi for yield strength, 32 for percent elongation, 64 for Brinnell hardness, and 13.8 Mpsi for Modulus of Elasticity.
100911 Figures 5A and 5B correspond to the specific tested formulations and the corresponding results for the Alloy Group 11-A. Eight sample heats, prepared in accordance with the process above to achieve a Group II-A alloy, were tested for ultimate tensile strength, yield strength, percent elongation, Brinnell hardness, and Modulus of Elasticity. The average for the eight Alloy Group 11-A alloys was 43.8 ksi for ultimate tensile strength, 23 ksi fox yield strength, 27 for percent elongation, 80 for Brinnell hardness, and 15.0 Mpsi for Modulus of Elasticity.
100921 Table 9 (Figure 6) illustrates the range of mechanical properties determined experimentally for alloys of the present invention, as well as for several known commercial alloys.
100931 These results indicate that the minimum and typical UTS values for alloy I-A are higher by 50%, 18%, and 34% for minimum and 30%, 9%, and 12% for typical with respect to alloys C89520, C89836, and C83470 respectively. Similarly, the E% is higher by 550%
95%, and 129% for minimum and 370%, 57%, and 88% for typical with respect to C89520, C89836, and C83470 respectively. The YS of I-A is higher by 8% over the Biwalitem(C83470).
100941 With respect to I-B, these values are 40%, 11%, and 26% for minimum UTS, 24%, 4%, and 7% for typical UTS; 350%, 35%, and 59% for minimum E%, and 220%, rh, and 28% for typical E% with respect to alloys C89520, C89836, and Biwa1itend(C83470) respectively.

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[0095] Figures 37 to 45 illustrate the variation between various heats within each of Group I-A
(Figures 37 to 39), Group I-B (Figures 40 to 42), and Group 11-A (Figures 43 to 45). Mechanical data is also provided for three commercially available alloys, C84400 (depicted as ¨), C89836 (depicted as and C89520 (depicted as - - -)for comparison purposes. The data for the respective Alloy Groups of the present invention are shown as points connected by a solid line.
[0096] Regarding Group I-A, Figure 37 shows the observed UTS was consistently higher than the commercial alloys. Figure 38 shows the observed YS was consistently higher than all of the commercial alloys except C89520, an alloy containing the expensive rare element bismuth.
Figure 39 shows the observed elongation was consistently much higher than all of the commercial alloys. Elongation did exhibit variability from heat to heat for Group I-A.
10097] Regarding Group I-B, Figure 40 shows the observed UTS was consistently higher than the commercial alloys. Figure 41 shows the observed YS was consistently higher than all of the commercial alloys, again, except C89520, an alloy containing the expensive rare element bismuth. Figure 42 shows the observed elongation was consistently higher than all of the commercial alloys. Elongation did exhibit significant variability from heat to heat for Group 1-B.
100981 Group II-A alloys were also compared with leaded alloy C90300 (depicted as in addition to the commercial alloys used in as previously discussed Regarding Group II-A, Figure 43 shows the observed UTS was consistently higher than the commercial alloys, including slightly higher than C90300. Figure 44 shows the observed YS was consistently higher than all of the conunercial alloys including C89520. Figure 45 shows the observed elongation was consistently higher than all of the commercial alloys. Elongation did exhibit significant variability from heat to heat for Group II-A.
Scanning Electron Microscope Analysis [0099] Table 10 (Figure 7) lists the compositions of five alloys of the present invention, Alloy I-A-10, Alloy I-8-10, Alloy II-A-10, Alloy 11-3-10, and Alloy III-A-10, that were analyzed using a scanning electron microscope equipped with energy dispersive spectroscopy (SEM/EDS). A
sample of each alloy in Table 10 was mounted, metallographically prepared according to known 4622-6303.2592 i AMENDED Slic"( 413T 14' PCT/US2011/058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:22PM FOLEY & LARDNER NO. 7886 P. 34/78 Attny Docket No 055665-5144PCT
methods and then examined both optically and using SEM/EDS. For comparison, the Biwa1iterm(C83470) alloy was melted and cast under conditions similar to alloy I-A and used for evaluation and comparison of microstructure.
10100) Figures SA and 8B illustrate element mapping of sulfur in Alloy I-A-10 (0_16% S).
Figure 9A is an SEM of Alloy I-A-10; Figures 9B-H illustrate element mapping;
Figure 9B is an EDS for Sn; Figure 9C is an EDS for Zn; Figure 9D is an EDS for Cu; Figure 9E
is an EDS for Fe; Figure 9F is an EDS for Ni; Figure 9G is an EDS for P; Figure 9H is an EDS
for S. Figure 10A is a micrograph of Alloy I-A-10a, with regions 1,2, and 3 marked; Figures 10B-D show the presence of Cu2S, ZnS and Cu-Zn intermetallic phases: Figure 10B is an EDS
spectra from region 1; Figure 10C is an EDS spectra from region 2; Figure 10D is an EDS
spectra from region 3. Figures 11A-B are optical images of Alloy I-A-10a at low (Figure 11A) and high magnifications (Figure 11B). The elements are seen widely distributed except for sulfur, which appears collected at what is believe to be interdentic areas or grain boundaries.
[0101]Figures 12A and 12B illustrate element mapping of sulfur in Alloy I-B-10a (0.31% S).
Figure 13A is an SEM of Alloy i-B-10; Figures 13B-H illustrate element mapping; Figure 13B is an EDS for Sn; Figure 13C is an EDS for Zn; Figure 13D is an EDS for Cu;
Figure 13E is an EDS for Fe; Figure 13F is an EDS for Ni; Figure 12G is an EDS for P; Figure 1311 is an EDS for S. Figure 14A is an SEM of Alloy I-B-10b (0.13%S); Figures 14B-H illustrate element mapping at 5000x magnification; Figure 14B is an EDS for Si; Figure 14C is an EDS for S; Figure 14D is an EDS for Fe; Figure 14E is an EDS for Cu; Figure 14F is an EDS for Zn;
Figure 140 is an EDS for Sn; Figure 14H is an EDS for Pb; Figure 14 I is an EDS for Ni. Figures 15A-B are optical images of Alloy I-B-10a at low (Figure 15A) and high magnifications (Figure 15B). The elements are seen widely distributed except for sulfur, which appears collected at what is believe to be interdentric areas or grain boundaries. The higher volume fraction of the sulfides is evident due to the high sulfur content. Some of these sulfides are ZnS as evident from the EDS data.
These sulfides are finer than those Observed in Biwalitelw(C83470), see Figure 46A. Presence of the Cu-Zn intennetallic phases are evident as well.

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[0102] Figures 16A and 1613 illustrate element mapping of sulfur in Alloy H-A
(0.30% S).
Figure 17A is an SEM of Alloy II-A; Figures 178-H illustrate element mapping;
Figure 15B is an EDS for Sn; Figure 17C is an EDS for Zn; Figure 1713 is an EDS for Cu;
Figure 17E is an EDS for Fe; Figure 17F is an EDS for Ni; Figure 170 is an EDS for?; Figure 17H
is an EDS for S. Figure 18A is an SEM of Alloy II-A-10b (0.19% S); Figures 183-H illustrate element mapping at 1000x magnification; Figure 183 is an EDS for Si; Figure I8C is an EDS for S;
Figure 18D is an EDS for Fe; Figure 18E is an EDS for Cu; Figure 18F is an EDS
for Zn; Figure 180 is an EDS for Sn; Figure 18H is an EDS for Pb; Figure 18 ha an EDS for Ni.
Figures 19A-B are optical images of Alloy 1I-A at low (Figure 19B) and high magnifications (Figure 19A).
The elements are seen widely distributed except for sulfur, which appears collected at what is believe to be interdentic areas or grain boundaries. These figures show the presence of Cu2S, ZnS, and intermetallic phases of Cu-Sn and Cu-Zn.
[01031 Figures 20A and 20B illustrate element mapping of sulfur in Alloy M-A
(0.011% 5).
Figure 21A is an SEM of Alloy III-A; Figures 121B-11 illustrate element mapping; Figure 21B is an EDS for Sn; Figure 21C is an EDS for Zn; Figure 211) is an EDS for Cu;
Figure 21E is an EDS for Fe; Figure 21F is an EDS for Ni; Figure 210 is an EDS for?; Figure 21H
is an EDS for S. Figures 22A-B are optical images of Alloy M-A at low (Figure 22A) and high magnifications (Figure 22B), The elements are seen widely distributed except for sulfur, which appears collected at what is believe to be interdentric areas or grain boundaries.
Phase Analysis [01041 Phase information was gathered for the alloys in Table 11. Alloys I-A-1 through 1-A-5 and Alloys I-B-1 and 11-A-1 were formulated and made in accordance with the present invention.
Alloy C83470 is a known alloy whose full composition is listed in Table 1 (Figure 1). Alloys 1-B-11a and H-A-11a are nominal compositions for Alloy Groups I-B and I1-A
respectively. For comparison, nominal composition of commercially available alloy- C83470 (BiwaliteTM) is also included in Table 11.

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_ Table 11 Alloy Compositions for Phase Analysis Alloy Type Cu S _Su Zn Ni Mn Alloy I-A-112 88.9 0.6 3 7.5 , 1 - _ Alloy I-A-11b 88.1 0.6 2.9 , 8.5 1 , Alloy I-A-Ile 91.2 0,6 3,2 5 _1 -.
, Alloy I-A-11d 85.4 0.6 3 , 11 , 1 _ _ Alloy I-A-Ile 81.4 0.6 3 14 1 -_ _ Alloy 1-A Nominal 86 0.4 3 9 ' 1 --Biwalite Tm(C83470) 93.96 , 0.6 2.5 3 1 _ Alloy i-B-ha 86 0.5 3 8 1 0.5 Allox 11-A-11a 87 0,4 8 T3.5 1 (0105i In order to understand the strengthening mechanisms in these alloys, phase diagrams of the Cu-Zn-Sn-S systems with and without Mn were determined using both equilibrium and non-equilibrium cooling (Scheil cooling) conditions. It should be noted that sand casting generally corresponds to non-equilibrium cooling. The phases present in these alloys have been studied using the vertical sections of the multicomponent systems.
[0106] Analysis done using conventional techniques was performed to determine the relative amount of the phases present at mom temperature in the alloys of Table 11. In a first phase study, the five specific formulations of Alloy Group I-A were tested to observe the variance in phases within an Alloy Group. A known commercial alloy, C83470, was also studied as a . reference. Table 12 lists as a percentage, the phases for each alloy.
The C83470 exhibits less of the Beta phase than the alloys of Group I-A or 11-A.

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Table 12 Relative amount of the phases present at room temperature E5uftibrium Schen Cooling Alloy FCC Cu3Sn '7AIS FCC
Cu3Sn MnS CuiS MnS y (BCC11, (BCC2) Alloy I-A-12a) , 90.8 73 1.8 87.5 1.1 0 2.8 5.4 2.5 0 0.6 Alloy I-A-12b 91.3 7.1 1.6 87.8 1.3 0 23 - 7.8 0.2 0 0.5 Alloy I-A-12e 90.9 7.3 1.9 87.5 0.7 0 2.8 4.3 3.9 0 0.8 Alloy I-A-12d 90.6 7.6 1.9 86.0 r- 1.9 0 2.6 7.7 - 1.5 0 0.15 Alloy I-A-12e 90.5 7.5 2 85 2.3 0 2.6 9 1.1 -C83470 93.5 4.7 1.9 91.5 0.4 - 0 2.9 -3.4 1.1 0 0.8 Bivvalitemi Alloy I-A 12f 90.6 6.8 0.9 85.5 1.6 0 1.8 8.4 0.5 0 0.50 Alloy I-B-12a - 90.8 6.7 0.5 86.6 1.7 0.6 1.0 7.5 13 0.5 0.4 Alloy 11-A-124 79.7 17.4 1.2 74.2 1.6 0 , 1.9 16.1 -0.1 r 0 - 3.6 , [0107] Figure 24 plots the position of the alloys in table 12 on a copper/zinc/tin phase diagram.
The alloys proceed from the highest percentage of copper and zinc on the left to the lowest copper and zinc on the right. A phase distribution diagram of I-A-11a (Figures 25A and 25B), I-A-11b (Figures 26A and 26B), I-A-11c (Figures 27A and 27B), I-A-11d (Figures 28A and 28B), I-A-I le (Figures 29A and 29B), using Scheil cooling is shown. Figures 31, 32A, and 32B
correspond to Alloy I-A-12f. Figures 33, 34A, and 34E correspond to Alloy I-B-12a. Figures 35, 36A, and 36B correspond to Alloy II-A-12a. The relative amounts of the melt having FCC, Liquid, BCCI, BCC2, Cu2S, and Cu3Sn in relation to temperature is shown in Figures 26A, 26B, 27A, and 27B (magnified in 26B and 27B to show the distribution of the secondary phases).
(01081 Figures 30A-30B illustrates a similar series of phase distributions as Figures 25A-29, but for an existing commercial alloy, C83470. Figure 30A is a phase distribution diagram of C83470 alloy using Schell cooling. Figure 30B is a magnified part of the phase distribution diagram showing the relative amounts of secondary phases.
101091 The phase distribution diagrams show the phase that can be expected and the temperature at which they start wearing. The relative amount of each phase can also be estimated from these diagrams. Table 12 is based on these diagrams which shows that for non-equilibrium cooling, it is the p (BCC1) phase (which is an intermeta/lic compound of Cu and Zn) that 4 .
itlitMED APT 34) PCT/US2011 /058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:24PM FOLEY & LARDNER NO. 7886 P. 38/78 ikttny Uocket No 055665-5144PC1 contributes to the strength of the alloys. However, strength increases at the expense of ductility.
Sloan Green alloys show high strength and ductility. Their high ductility may be due to the good melt quality, low gas content and good homogeneity. The finer distribution of sulfides also contribute to high strength and high ductility in addition to contributing to pressure tightness and machinability.
Table 13: Liquidus Study Alloy Type Liquidus Temperature Solidus Temperature Freezing Range C ( F) C ( F) C
Alloy I-A-11e 1043 (1910) 936(1717) 107(193) Alloy I-A-11a 1041(1904) 942(1728) 991178) , Alloy I-A-11b 1036(1897) 947 (1737) 89(160) Alloy I-A-11d 1029 (1884) 948 (1738) 81 (14.6) Alloy I-B-11a , 1035 (1895) 939 (1722) 96 (173) C84400, Leaded Alloy, 1004(1840) 843 (1549) 161 (291) Biwiditem, C83470 1013 (1855) 951(1744) 62(111) BiwallteTM, C83470 1027, (1881) 982(1800) 45(81) (Roported;
C90400 987 (1810) 852(1566) 135(244) C90300, Leaded ABoy, 1000 (1832) 854 (1570) " 146(262) Procedure:
[0110] Thermal investigation of the systems was performed using a DSC-2400 Setaram Setsys Differential Scanning Calorimetry. Tempera= calibration of the DSC was done using 7 pure metals: In, Sn, Pb, Zn, Al, Ag, and Au spanning the temperatute range from 156 to 1065 C.
The samples were cut and mechanically polished to remove any possible contaminated surface layers. Afterwards, they were cleaned with ethanol and placed in a graphite crucible with a lid cover to limit possible evaporation and protect the apparatus. To avoid oxidation, the analysis chamber was evacuated to 1172 nabs/ and then flooded with argon. The DSC
measurements were carried out under flowing argon atmosphere. Three replicas of each sample were tested. The weight of the sample was 62-78 mg.
10111] The sample was heated from room temperature to 1080 C. Then it was cooled to 800 C
and kept at that temperature for 10 minutes, 600 5. This is termed "first heating and cooling 1VNED SHEEMOT,34) PCT/US2011 /058448 IPEA/KR (27-08-2012) AUG. 27. 2012 3:25PM FOLEY & LARDNER NO.
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cycle." In the second and third cycles the sample was heated to 1080 C and then cooled to 800 C twice. Finally the sample was cooled down to room temperature. A constant rate of 5 C /min was used for all heating and cooling. A baseline experiment, with two empty graphite crucibles was run using the same experimental program. The baseline was subtracted for all NILS. The analysis for temperatures and enthalpies was carried on these baseline adjusted thermogrEmrs.
[01121 The results from the second and third cycles were used to determine the relevant thermal parameters, namely the Tswit of melting , the To.t of solidification, and Tpuk of melting and solidification, as well as, the enthalpy, E, of melting and of solidification.
Usually, T., (heating) and Tpeak (cooling) were taken as the Ts (solidus) and TL (liquidus).
[0113] The results of the liquidus study (Table 13) indicate that the introduction of sulphides appear to reduce the liquidus temperatures and the freezing ranges hi comparison with the leaded alloys. In the A-I group of alloys, as the Zn content increases, liquidus temperature and the freezing range decrease.
[01141 With respect to freezing ranges, BiwaliteTu(C83470), has a medium freezing range. The alloys of Table 13 have a broad freezing range. In contrast, with BiwaliteTm(C83470), one can expect a deep pipe in the riser which can extend to the casting to produce shrinkage porosity.
With broad freezing range alloys, porosity can be distributed well in the casting. In addition, it can be minimized / eliminated by using proper risering design and/or by using metal chills. In a way, the alloys I-A, I-B, and II-A of Table 13 can be less susceptible to shrinkage porosity. This would lead to better strength and elongation values as observed.
Sulfide Particle Size Table 14 Alloys for Particle Size Study Biwalitem Element Alloy I-A-14a Alloy I-A-14b Alloy II-A-14a C90300 Cu 88.26 90.46 ¨ 87.46 91.82 87.58 , Ag <0.01 <0.01 0.03 <0.01 0.02 Bi 0.01 0.01 0.07 0.01 0.02 Fe 0.16 0.05 0.16 r 0.26 0.09 AILLE:FED SHEET( ART 24)]

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Mn <0.01 0.01 0.01 <0.01 <0.01 Ni 0.88 , 1.13 0.89 0.69 0.07 P 0.012 0.006 0.015 0.012 0.023 Pb 0.02 0.12 0.01 0.02 0.11 0.11 0.13 0.19 .59 0.012 , Sb <0.01 <0.01 <0.01 <0.01 0.01 Sn 3.23 3.63 8.18 4.02 8.22 Zn 7.32 4.45 2.99 2.58 3.84 Table 15 Particle Sizes Alloy Minimum (pm) Mailman* (pm) Average (pm) -Alloy I-A-14a , 0.1 9 Alloy I-A-14b 0.1 7 2 AJloy II-A-14a 0.1 14 2 Bilwalitem C83470 0.1 14 3 C90300 0.2 5 2 Alloy I-B-10a 0.1 5 , 1 Alloy III-A 0,1 5 1 Alloy I-A-10a 0.2 18 5 Alloy 1.1-A-10a 0.1 53 6 (01151 A study was done of the sulfide particles sizes of the alloys in Table 14 as well as select alloys in Table 10. Table 15 lists the minimum, maximum and average particle sizes for the alloys. In addition, particle sizes were reviewed for two commercial alloys, C83470 and C90300. The alloys of the present invention provide, on average, a smaller particle size than C83470 and a small minimum particle size than the commercial alloy C90300.
Figure 46A-46B
illustrate photomicrographs of the commercial C83470 compared with a Group I-B
alloy (I-B-14a).
10116] The foregoing description of illustrative embodiments has been presented for purposes of illustration and of description. It is not intended to be exhaustive or limiting with respect to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of the disclosed embodiments. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

11t!f1 A!!2i

Claims (5)

WHAT IS CLAIMED IS:

1. A cast alloy composition consisting essentially of:
a copper content from 83 wt% to 91 wt%;
a sulfur content from 0.1 wt% to 0.8 wt%;
a tin content from 2.0 wt% to 4.0 wt%;
a lead content of less than 0.09 wt%;
a zinc content from 4.0 wt% to 14.0 wt%; and a nickel content from 1.0 wt% to 2.0 wt%;
an iron content of less than 0.1 wt%;
an antimony content of less than 0.02 wt%;
a phosphorous content from greater than 0 wt% and less than 0.05 wt%;
an aluminum content of 0.005 wt%;
a manganese content from 0.01 wt% to 0.7 wt%;
a carbon content of from greater than 0 wt% to 0.5 wt%; and a titanium content of from greater than 0 wt% to 0.5 wt%.

2. The alloy composition of claim 1, wherein the copper content is from 83.0% to 89.0%.

3. The alloy composition of claim 1, wherein the copper content is from 83.0% to 88.0%

4. A cast alloy composition consisting essentially of:
a copper content of from 83 wt% to 89 wt %;
a sulfur content of from 0.1 wt% to 0.8 wt%;
a tin content of from 2.0 wt% to 4.0 wt%;
a lead content of less than 0.09 wt%;

a zinc content of from 4.0 wt% to 14.0 wt%;
an iron content of less than 0.01 wt%;
an antimony content of less than 0.02 wt%;
a nickel content of from 1.0 wt% to 2.0 wt%;
a phosphorus content of less than 0.05 wt%;
an aluminum content less than 0.005 wt%;
a silicon content less than 0.005 wt%; and a manganese content of 0.02 wt%.

5. A cast alloy composition consisting essentially of:
a copper content of from 83 wt% to 88 wt%;
a sulfur content of from 0.1 wt% to 0.8 wt%;
a tin content of from 2.0 wt% to 4.0 wt%;
a lead content of less than 0.09 wt%;
a zinc content of from 4.0 wt% to 14.0 wt%;
an iron content of less than 0.01 wt%;
an antimony content of less than 0.02 wt%;
a nickel content of from 1.0 wt% to 2.0 wt%;
a phosphorous content of less than 0.05 wt%;
an aluminum content of less than 0.005 wt%;
a silicon content of less than 0.005 wt%;
a manganese content of from 0.01 wt% to 0.7 wt%;
a zirconium content of less than 0.2 wt%;
a boron content of less than 0.2 wt%;
a carbon content of less than 0.5 wt%;
a titanium content of 0.5 wt%.