*A voluntary paper submitted for publication in May, 1987.
- Introduction
- Protective Film Formation
- Effects of Velocity
- Cavitation
- Corrosion Fatigue
- Ship Propeller Alloys
- Pump, Piping, and Heat Exchanger Alloys
- Galvanic Behavior of Copper
- References
- Page 2
Users and designers have found the charts and data summaries in an earlier work, "Guidelines for Selection of Marine Materials," helpful in selecting materials for marine service. This review updates and extends those summaries for copper-base alloys, many of which were not included in the earlier work.
Introduction
The engineer usually begins with a good idea of alloys that will meet the stresses and mechanical requirements of the assembly under consideration. The author's purpose is to provide guidelines that will allow the engineer to make a reasonable estimate of the effect of the environment on the performance of copper alloys. The charts and summaries provide useful guideposts, but they can never replace the experience, specific data, or properly conducted evaluations so necessary to the successful use of materials. Temperature and pH values that are normal for the waters and usage under consideration are assumed.
The principal constituents of water that affect the performance of copper alloys are dissolved oxygen, nutrients, bacteria, biofouling, organisms, sediment, trash, debris, and residual chlorine from the chlorination practice. Dissolved oxygen is usually reported in standard water analyses. Although the nature of sediments, bacteria, nutrients, biofouling organisms, debris, or chlorine present are often critical to performance, information on these important constituents is seldom included in water analyses and must be sought elsewhere.
Back to TopProtective Film Formation
The corrosion resistance of copper and copper-base alloys in seawater is determined by the nature of the naturally occurring and protective corrosion product film. North and Pryor found the film to be largely cuprous oxide (Cu2O), with cuprous hydroxychloride [Cu2(OH)3CI] and cupric oxide (CuO) being present in significant amounts on occasion.1 These studies indicated corrosion product film thicknesses to range from 2800 A for copper to 4400 A for Alloy C70600 (90:10 copper-nickel). The film is adherent, protective, and generally brown or greenish-brown in color.
The corrosion product film forms very quickly when clean; unfilmed copper or copper alloys are first wetted by seawater. The rate of film formation is indicated as the rate of copper reduction in the effluent (Figure 1). Total copper decreases tenfold within 10 min and 100-fold in the first hour. In three months, copper in the effluent is seen to be virtually at the level of the copper in the intake water.
Weight loss corrosion studies show that the protective film continues to improve, with the corrosion rate dropping to 0.5 mpy (0.012 mm/y) in ~1 y, and a long-term, steady-state rate of ~0.0S mpy (0.001 mm/y) in 3 to 7 y in quiet, tidal, and flowing seawater (Figure 2)2 Alloy C71500 (70:30 copper-nickel) exhibits the same pattern of decreasing corrosion rate with time.
Reinhart found that copper and its alloys of aluminum, silicon, tin, beryllium, and nickel had significantly lower long-term corrosion rates after 18 months compared to those specimens measured after only 6 months of exposure to seawater (Figure 3).3 The only exception was Alloy C28000, Muntz metal, which exhibited a slightly higher corrosion rate after 18 months as compared to 6 months. Alloy C44300, Admiralty, was in the group characterized by a decreasing corrosion rate with time. The long-term, steady-state corrosion rate for copper and copper alloys, except for Muntz metal, is on the order of 1 mpy (0.025 mm/y) or less, and for the copper-nickel alloys on the order of 0.05 mpy (0.001 mm/y), within those velocities that each alloy can tolerate without damage to the protective corrosion product film.
Data from short-term (less than 1 y) corrosion tests on copper alloys in seawater, while useful for certain alloy-to-alloy comparisons in research investigations, can be very misleading if they are used to estimate service life. Short-term data tend to underestimate long-term durability. Only the long-term, steady-state corrosion rate can be used to provide reasonable service life projections for copper alloys. Table 1 lists the copper-base alloys commonly used in marine service.
Wrought | ||
---|---|---|
Copper alloy | Number | Principal uses |
DHP copper | C1220 | Hull sheathing, piping |
PDO copper | C14200 | Hull sheathing, piping |
Beryllium copper | C17000 | Undersea telephone cable repeater housings |
Cartridge or 70:30 brass | C26000 | Hardware components |
Muntz metal | C28000 | Tubesheets |
Admiralty, arsenical | C44300 | Heat exchanger tubing |
Naval brass, arsenical | C46500 | Tubesheets |
Phosphor bronze | C51000 | Bolting, boat shafting, marine wire rope, naval ordnance |
Phosphor bronze | C52400 | Naval ordnance |
Aluminum bronze | C61400 C61300 |
Power plant and offshore oil piping and waterboxes |
NiAI bronze | C63000 C63200 |
Pump shafts, valve stems (Navy) |
Silicon bronze | C65500 | Bolting |
Aluminum brass | C68700 | Condenser and heat exchanger tubing |
Copper-nickel | C70600 | Condenser and heat exchanger tubing, piping and waterboxes-shipboard power, industrial and desalination plants, waterflood and offshore oil |
Copper-nickel | C71500 | Condenser and heat exchanger tubing, piping and waterboxes-shipboard. power, industrial and desalination plants, waterflood and offshore oil |
Copper-nickel | C72200 | Condenser and heat exchanger tubing |
Cast alloys | ||
Ounze metal | C83600 | Plumbing fittings |
Manganese bronze | C86500 | Ship propellers |
G Bronze | C90300 | Pumps, valves, naval ordnance, Tailshaft sleeves |
M bronze | C92200 | Pumps, valves |
Al bronze | C95200 | Waterflood and seawater pumps |
NiAI bronze | C95500 | Propellers |
NiAlMn bronze | C95700 | Propellers |
NiAl bronze | C95800 | Pump, valves and fittings. ship propellers |
Copper-nickel (80:20) | C96300 | Tailshaft sleeves for ships |
Copper-nickel (70:30) | C96400 | Pumps, valves, fittings |
Effects of Velocity
Seawater moving over a surface creates a shear stress between that surface and the layer of seawater closest to the metal surface. As velocity increases, the shear stress increases until it strips away the protective film on copper and copper alloys.
Alloy | Critical Shear Stress N/m2 (lbf/ft2) |
---|---|
CA 122 | 9.6 (0.2) |
CA 687 | 19.2 (0.4) |
CA 706 | 43.1 (0.9) |
CA 715 | 47.9 (1.0) |
CA 722 | 296.9 (6.2) |
Efird studied and estimated the critical shear stress for C12200, C68700, C70600, C71500, and C72200 (Table 2).4 Figure 4 shows how the critical shear stress varies with velocity and pipe (or tube) diameter. The shear stress in 1-in. (25-mm) diameter pipe at 10 fps (3 m/s) is no greater than that in 12-in. (305-mm) diameter pipe at 12 fps (3.7 m/s) or that in 10-ft (3-m) diameter pipe at 16 fps (4.9 m/s). As the diameter increases, copper-base alloys will tolerate higher nominal velocities in the piping system.
Sato and Nagata showed that the shear stress at the inlet end condenser tube is about double that further down the tube (Figure 5).5 These data explain why inlet-end erosion/corrosion is such a common occurrence and also explain the preference for the copper-nickel that have been developed because of their greater velocity tolerance. Sato and Nagata also showed that water velocity passing a partial obstruction in the bore of a condenser tube can reach 26 fps (8 m/s), even though the overall velocity remains in the normal 6.6 fps (2 m/s) range. This explains the occurrence of tube failures downstream of lodgements in condenser tubes when using debris-laden water.
Ferrara and Gudas studied the effect of velocity by mounting flat bars on a rotating disc.6 When tested in this manner, C70600 exhibited a significantly lower corrosion rate than C71 500 at peripheral velocities of 26 to 29 fps (7.9 to 8.8 m/s). Ferrara and Gudas found similar relationships in other tests in which high-velocity seawater was allowed to flow over the top and bottom surfaces of flat specimens, a parallel flow test. Although the 70:30 copper-nickel alloy has somewhat greater resistance to inlet-end erosion/corrosion in condensers and heat exchangers, 90:10 copper-nickel is more resistant at the higher velocities encountered by ship hulls.
The British Nonferrous Metals Research Association impingement test uses a jet of highly aerated seawater directed normal to the specimen surface and has been widely used to study velocity effects and to rank the velocity resistance of materials. The results are expressed in terms of weight loss and as maximum depth of impingement attack. The results of a 60-day test at a jet velocity of 25 fps (7.6 m/s) are shown in Figure 6.6 In this test, 90:10 copper-nickel had a lower weight loss and less depth of penetration than 70:30 copper-nickel.
The results of these different testing methods, while useful for ranking alloys, are difficult to apply directly to pumps, propellers, and piping. Table 3 has been prepared to assist designers in selecting copper alloys for condensers, heat exchangers, and piping applications. Table 4 can be used in selecting pump and propeller materials based on alloy resistance to flow as indicated by velocity test data and service experience.
Condensers and heat exchangers Minimum velocity-any tube, any alloy, 3 fps (0.9 m/s) | ||||
---|---|---|---|---|
Note: It is necessary to keep the minimum velocity in any tube above 3 fps (0.9 m/s) at the lowest heat transfer demand anticipated so that sediment and particulate matter will be swept through and not deposited in the tube. Unremoved sediment reduces heat transfer and in time can lead to under sediment corrosion. | ||||
Maximum velocity-fps (m/s), average | ||||
CA68700 | CA70600 | CA71500 | CA72200 | |
Once through | 6.5 (2.0) | 7.5 (2.3) | 9.5 (2.9) | 10 (3.1) |
Two pass | 5.5 (1.7) | 6.5 (2.0) | 8 (2.4) | 10 (3.1) |
Note: Once the corrosion product film is fully formed (2 to 4 weeks), somewhat higher velocities can be tolerated for short periods not exceeding 15% of total operating time. The water box and the return head of two pass units must be designed so that the flow in any tube is within 25% of the average flow for the unit. In smaller heat exchangers, the waterbox and return head may require extra volume to provide good flow distribution to all tubes. |
||||
Piping Nominal velocity-fps (m/s) | ||||
CA70600 | CA71500 | |||
3-in. (76-mm) diameter and smaller | 5 (1.5) | 6 (1.8) | ||
4- to 8-in. (101- to 203-mm) diameter with short radius bends | 6.5 (2.0) | 7.5 (2.3) | ||
4-in. (101 mm) and larger with long radius bends and 8 in. (203 mm) | 11 (3.35) | 12 (3.7) | ||
Note: Higher velocities can be tolerated in fresh waters, but the minimum remains the same. | ||||
Stagnant water | ||||
Avoid stagnant conditions. Flush, drain, and blow dry for extended standby. Circulate frequently if full. |
Peripheral Velocity-fps (m/s) | Copper Alloys |
---|---|
30 (9.1 ) | C83600 C87600 |
35 (10.7) | C90300 C92200 |
50 (15.2) | C95200 C86500 |
775 (22.9) | C95500 C95700 C95800 |
Cavitation
With the high flow velocities found in some high-speed pumps and at the periphery of large ship propellers, pressure differentials sufficient to create momentary cavities in the seawater between leading and trailing surfaces are sometimes encountered. These cavities collapse, setting up a hammering action and fatigue stresses in the surface of the metal on the trailing or low-pressure side. The occurrence of cavitation is strongly influenced by the manner in which the flow is directed over the leading and trailing surfaces, by slight changes in the contour of the surfaces, and by the direction of water flow and velocity.
Cavitation tests are valuable for the specific condition under investigation, but are difficult to apply to other applications. Table 5 from Tuthill and Schillmoller groups a number of alloys in terms of their relative resistance to cavitation damage in seawater.7 The more resistant copper alloys are in Group 2 and the less resistant in Group 3.
Aluminum bronze and nickel-aluminum bronze alloys display outstanding resistance to cavitation, especially Alloy C95500 (Mil B 21230 Alloy 1) (Military specification), the principal, high-performance, propeller alloy for naval and merchant ships. Although the aluminum bronzes fall into Group 2 in Table 5, they closely approach the cavitation resistance of the alloys in Group 1. The Group 3 alloys, while still useful in applications in which cavitation may be encountered, do suffer substantial damage if cavitation prevails.
Resistance to cavitation damage rating | Metals |
---|---|
Group 1-Most resistant. Little or no damage. Useful under supercavitating conditions. | Cobalt-base hard facing alloy Titanium alloys Austenitic (AISI series 300) and precipitation-hardened SSs Nickel-chromium alloys such as Alloys 625 and 718 Nickel-molybdenum-chromium Alloy C |
Group 2-These metals are commonly used where a high order of resistance to cavitation damage is required but are subject to some metal loss under the most severe conditions of cavitation | Nickel-copper-aluminum alloy K-500 Nickel-copper Alloy 400 Nickel-aluminum bronze Nickel-aluminum-manganese bronze |
Group 3-These metals have some degree of cavitation resistance but are generally limited to low speed, low performance type applications. | 70:30 copper-nickel alloy Manganese bronze G Bronze and M Bronze Austenitic nickel cast irons |
Group 4-These metals are normally not used in applications where cavitation damage may occur unless heavily protected | Carbon and low-alloy steels Cast irons Aluminum and aluminum alloys |
(1) At normal cavitation erosion intensities where inherent corrosion resistance influences resistance to cavitation. |
Corrosion Fatigue
Corrosion fatigue strength (CFS) is commonly defined as the fatigue strength at 108 cycles at zero mean stress. CFS should not be regarded as a true endurance limit, since failure may occur at lower stresses at greater than 108 cycles. Ship propellers, deep diving submersibles, undersea equipment, and certain pumps are subject to corrosion fatigue.
Back to TopShip Propeller Alloys
The thickness of large ship propeller blades at one-fourth to one-third the distance to the tip is 10 to 16 in. (254 to 406 mm) and is where fatigue loadings are greatest. Castings of this thickness generally cool very slowly, resulting in larger grain sizes and lower tensile properties than the smaller separately cast test keel blocks used for mechanical property determinations. Thus, the properties determined on keel blocks cannot be used directly for design purposes.
The outer surface layers of the propeller blade, which cool faster and have somewhat better properties than the interior, are removed in the grinding and polishing operations essential to obtaining requisite propeller surface finish. Porosity and other casting defects uncovered in the grinding and polishing operation must be held to a minimum, but they still contribute to some of the variations in measurement of the CFSs and in propeller performance. The CFSs of large, slowly cooled propeller alloy castings were determined in a Metals Properties Council program and are given in Table 6.8 Since these CFSs were measured at zero mean stress, they must be adjusted downward when the mean tensile stresses are substantial.
Corrosion Fatigue Strength(1) | ||
---|---|---|
Cast Alloy | (psi) | (MPa) |
C86500 ABS Type 2 | 9000 + 20% | 62 + 20% |
C95500 ABS Type 4 | 14,000 + 20% | 96 + 20% |
C95700 ABS Type 5 | 12,000 + 20% | 83 + 20% |
1) These corrosion fatigue strengths were measured at 108 cycles and zero mean stress and must be reduced when mean tensile stresses are substantial. |
Pump, Piping, and Heat Exchanger Alloys
CFS is an important characteristic of both cast and wrought alloys used in pumps, piping, and heat exchangers in deep diving submersibles, undersea equipment, and certain oil production activities. Much of this equipment is subject to low-cycle fatigue that can occur with repeated deep dives or repeated lowering of instruments to great depths, as well as to high-cycle fatigue associated with rotating machinery. Unlike propellers, this equipment is fabricated from wrought alloys as well as cast materials. Low-cycle fatigue strengths for copper alloys from the work of Czyryca and Gross are plotted in Figure 7.9 Unlike high-cycle fatigue, in which seawater reduces the fatigue strength as measured in air, no significant difference in low-cycle fatigue behavior between air or seawater was found.
Back to TopGalvanic Behavior of Copper and Copper-Base Alloys
Copper and copper-base alloys occupy a useful mid-position in the galvanic seriesmore noble than steel, cast iron, NiResist, aluminum, and zinc; and less noble than stainless steel (SS), titanium, and nickel-base alloys. The corrosion potential of copper in flowing seawater is ~-0.33 V; nickel-aluminum bronze (the most noble) is -0.18 V; and aluminum bronze (the least noble) is -0.36 V SCE (saturated calomel electrode).
In addition to the corrosion potential, the effective cathode-to-anode area ratio and the amount of oxygen available at the cathodic surface have a pronounced effect on galvanic corrosion. The larger the effective cathode-to-anode area ratio and the more oxygen available at the cathode, the greater the galvanic effect will be. To a lesser extent, temperature and other chemical species present also effect galvanic behavior.
Scholes and Rowland reported the acceleration in corrosion resulting from galvanic coupling of a variety of materials.10 The portion of their chart dealing with copper-base alloys is shown as Table 7. Most copper alloys can be coupled to each other without greatly accelerating the corrosion that would otherwise occur in the absence of coupling. Nevertheless, better performance and longer service life will be obtained if the copper alloy condenser tubing is more noble than the tubesheet and waterbox, if pump impellers are more noble than the case, and if valve seats are more noble than the body.
Coupled material (M) | Uncoupled corrosion rate-1y (mm/y) | Acceleration factors | |||||
---|---|---|---|---|---|---|---|
Copper (Cu) 10:1 M | Copper (Cu) 1:1 M | Copper (Cu) 1:10 M | Mild Steel 10:1 M | Mild Steel 1:1 M | Mild Steel 1:10 M | ||
Zinc | 0.05 | 20 | 10 | 3 | 20 | 10 | 3 |
N34 aluminum | 0.01 | l00 | 20 | 2 | 80 | 20 | 2 |
Mild steel | 0.13 | 7 | 3 | 1 | 1 | 1 | 1 |
HY80 | 0.10 | 7 | 3 | 1 | 1 MS | 2 MS | 3 MS |
Ni-Resist Type D2(1) | 0.15 | 7 | 3 | 1 | 1 MS | 2 MS | 3 MS |
Tin | 0.03 | 3 | 2 | 1 | 1 MS | 2 MS | 3 MS |
Lead | 0.01 | 2S | 8 | 1(2) | 1 MS | 2 MS | 3 MS |
Naval brass(3) C46500 | 0.04 | 2 | 2 | 1 | 1 MS | 3 MS | 7 MS |
Aluminum brass C61 400 | 0.01 | 2 | 2 | 1 | 1 MS | 3 MS | 7 MS |
Aluminum bronze(3) (10o/o Al) C61800 | 0.02 | 2 | 2 | 1 CU | 1 MS | 3 MS | 7 MS |
Silicon aluminum bronze(3) | 0.015 | 1 | 1 | 1 | 1 MS | 3 MS | 7 MS |
Nickel aluminum bronze(3)C95800 | 0.015 | 1 CU | 2 CU | 1 CU | 1 MS | 3 MS | 7 MS |
Silicon bronze C6S50 | 0.035 | 1 CU | 1 CU | 1 CU | 1 MS | 3 MS | 7 MS |
Copper C1100 | 1 | 1 | 1 | 1 MS | 3 MS | 7 MS | |
Phosphor bronze (3% Sn) CS1000 | 0.02 | 1 CU | 2 CU | 1 CU | 1 MS | 3 MS | 7 MS |
Phosphor bronze (10% Sn) CS2400 | 0.02 | 1 CU | 2 CU | 1 CU | 1 MS | 3 MS | 7 MS |
Gun Metal C90300 | 0.035 | 1 CU | 1 CU | 1 CU | 1 MS | 3 MS | 7 MS |
90:10 Cupro-nickel (1% Fe) C70600 | 0.02 | 2 | 2 | 2 | 1 MS | 3 MS | 7 MS |
70:30 Cupro-nickel (1% Fe) C71500 | 0.02 | 1 CU | 1 CU | 2 CU | 1 MS | 3 MS | 7 MS |
TN732 Cupro-nickel C71900 | 0.02 | 1 CU | 1 CU | 2 CU | 1 MS | 3 MS | 7 MS |
Iconel 625 | 0.005 | 1 CU | 1 CU | 10 CU | 1 MS | 3 MS | 7 MS |
Monel 400(4) | 0.003 | 1 CU | 1 CU | 10 CU | 1 MS | 3 MS | 7 MS |
AlSI 316 SS(4) | 0.005 | 1 CU | 2 CU | 10 CU | 1 MS | 3 MS | 7 MS |
Titanium | 0.001 | 1 CU | 5 CU | 10 CU | 1 MS | 2 MS | 5 MS |
Carbon | - | 1 CU | 8 CU | 40 CU | 2 MS | 4 MS | 10 MS |
(1) Materials in wrought form except cast form. (2) Results based on 100-h tests for materials that can undergo polarity reversals. (3) Acceleration factors subject to changes resulting from variable complex microstructure. CU and MS indicate that coupling with M accelerates corrosion of copper (CU) or mild steel (MS) rather than material (M). (4) These materials are subject to crevice corrosion. |
Some condensers have been retubed with highly alloyed SS or titanium tubing while still retaining the original copper alloy tubesheet. other new condensers have used aluminum bronze tubesheets with titanium tubes. The severe tubesheet corrosion that followed led to studies that showed that the effective cathodic area was many times larger than had been supposed, approaching a 1000:1 cathode-to-anode ratio.11 Copper alloy tubesheets require a carefully designed cathodic protection system when using titanium or SS tubes.
It has been the practice in the US to use C83600, C90300, and C90500 pumps and valves in C70600 piping systems because of their wide availability. Although these materials are less noble than the C70600 piping, they perform reasonably well. SS or titanium pumps and valves may be used in copper alloy piping systems since the cathodic area is small in relation to the piping. Although metal loss will increase somewhat in the piping. this has generally been tolerable. Copper alloy pumps and valves in SS or titanium piping systems would have difficulty in forming a good protective film and are not suggested for such service.
Back to Top- R. F. North, M. J. Pryor, Corros. Sci., Vol. 10, p. 197, 1970.
- "Corrosion Resistance of Wrought 90-10 Copper-Nickel-Iron Alloy in Marine Environments," INCO TP A-1222, 1975.
- F. M. Reinhard, "Corrosion of Materials in Hydrospace Part IC Copper and Copy Alloys," Tech. Not N-961, NITS Document No. AD 835 104, April 1978.
- K. D. Efird, Corrosion, Vol. 33, No. 1, p. 3, 1977.
- S. Sato, K. Nagata, "Factors Affecting Corrosion and Fouling of Metal Condenser Tubes of Copper Alloys and Titanium," Sumitomo Light Metal Technical Reports, Vol. 19, Nos. 3 and 4, p.83, 1978.
- R. J. Ferrara, J. P. Gudas, "Corrosion Behavior of Copper-Base Alloys with Respect to Velocity," Proc. 3rd Int. Cong. Marine Corros. and Fouling, October 1972.
- A. H. Tuthill, C. M. Schillmoller, Ocean Sci. and Ocean Eng. Conf., INCO Tech. Pub. A404, Marine Technology Society, Washington, DC, 1965.
- M. Prager, "The Properties of Cast Alloys for Large Marine Propellers," ASME Pub. Cast Metals for Structural and Pressure Containment Applications, 1979 Metals Properties Council11, American Society of Mechanical Engineers, New York, NY.
- E. J. Czyryca, M. R. Gross, "Low-Cycle Fatigue of Non Ferrous Alloys for Heat Exchanger and Salt Water Piping," MEL R&D Report 26/66, NTIS Document AD 627 771, February 1966.
- I. R. Scholes, J. C. Rowlands, "Bimetallic Corrosion in Sea Water," Proc. 6th Eur. Cong. Met. Corros., London, England, September 1977.
- G. A. Gehring, Jr., J. R. Mauer, CORROSION/81, Paper No. 202, NACE, Houston, TX, 1981.
- B. C. Syrett, "Sulfide Attack in Steam Surface Condensers," Proc. 2nd Int. Conf. Environmental Degradation of Eng. Mater. in an Aggressive Environment, p. 3, 1981.
The material presented in this publication has been prepared for the general information of the reader and should not be used or relied on for specific applications without first securing competent advice. The Nickel Development Institute, and the Copper Development Association, Inc., their members, staff and consultants do not represent or warrant its suitability for any general or specific use and assume no liability of any kind in connection with the information herein.