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Journal articles on the topic 'Nickel-aluminum bronze'

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Published: 4 June 2021
Last updated: 6 February 2022

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1

Leong, Keng H., Peter A. Kirkham, and Kenneth C. Meinert. "Deep penetration welding of nickel–aluminum–bronze." Journal of Laser Applications 12, no. 5 (2000): 181. http://dx.doi.org/10.2351/1.1309550.

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2

Olszewski, Albert M. "Dealloying of a Nickel–Aluminum Bronze Impeller." Journal of Failure Analysis and Prevention 8, no. 6 (October 1, 2008): 505–8. http://dx.doi.org/10.1007/s11668-008-9181-2.

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3

Ding, Yang, Rong Zhao, Zhenbo Qin, Zhong Wu, Liqiang Wang, Lei Liu, and Weijie Lu. "Evolution of the Corrosion Product Film on Nickel-Aluminum Bronze and Its Corrosion Behavior in 3.5 wt % NaCl Solution." Materials 12, no. 2 (January 9, 2019): 209. http://dx.doi.org/10.3390/ma12020209.

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The in-situ studies of the corrosion product film on nickel-aluminum bronze are significant for explaining the mechanism of its corrosion resistance. In this paper, the corrosion behavior of nickel-aluminum bronze and the formation process of the protective film in 3.5 wt % NaCl solution are systematically investigated. The results of scanning electron microscope analysis and electrochemical tests indicate that the corrosion resistance of nickel-aluminum bronze is improved due to the formation of the corrosion product film. The change of local electrochemical property on the corrosion product film during the immersion time is evaluated via in-situ scanning vibrating electrode technique, and it reveals the evolution rules of ionic flux in real time. The formation process of the protective film on different phases in nickel-aluminum bronze is observed directly by in-situ atomic force microscopy as height change measurements. The α phases at different locations present different corrosion behaviors, and the lamellar α phase within the α + κIII eutectoid structure gets more serious corrosion attack. The κ phases establish a stable and dense protective film in short time, preventing the corrosion attack effectively. The β′ phase, however, suffers the most serious corrosion damage until a protective film is formed after 150 min of immersion.
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4

Nascimento, Maurício Silva, Givanildo Alves dos Santos, Rogério Teram, Vinícius Torres dos Santos, Márcio Rodrigues da Silva, and Antonio Augusto Couto. "Effects of Thermal Variables of Solidification on the Microstructure, Hardness, and Microhardness of Cu-Al-Ni-Fe Alloys." Materials 12, no. 8 (April 18, 2019): 1267. http://dx.doi.org/10.3390/ma12081267.

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Aluminum bronze is a complex group of copper-based alloys that may include up to 14% aluminum, but lower amounts of nickel and iron are also added, as they differently affect alloy characteristics such as strength, ductility, and corrosion resistance. The phase transformations of nickel aluminum–bronze alloys have been the subject of many studies due to the formations of intermetallics promoted by slow cooling. In the present investigation, quaternary systems of aluminum bronze alloys, specifically Cu–10wt%Al–5wt%Ni–5wt%Fe (hypoeutectoid bronze) and Cu–14wt%Al–5wt%Ni–5wi%Fe (hypereutectoid bronze), were directionally solidified upward under transient heat flow conditions. The experimental parameters measured included solidification thermal parameters such as the tip growth rate (VL) and cooling rate (TR), optical microscopy, scanning electron microscopy (SEM) analysis, hardness, and microhardness. We observed that the hardness and microhardness values vary according to the thermal parameters and solidification. We also observed that the Cu–14wt%Al–5wt%Ni–5wi%Fe alloy presented higher hardness values and a more refined structure than the Cu–10wt%Al–5wt%Ni–5wt%Fe alloy. SEM analysis proved the presence of specific intermetallics for each alloy.
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5

Bennett, J. C., and C. V. Hyatt. "Microstructure of Laser Surface Melted Nickel Aluminum Bronze." Microscopy and Microanalysis 5, S2 (August 1999): 868–69. http://dx.doi.org/10.1017/s1431927600017669.

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The copper alloys commonly referred to as nickel aluminum bronzes (NAB) are widely used in marine applications due to their excellent seawater corrosion resistance and good mechanical properties. Unfortunately, these alloys are susceptible to a variety of surface sensitive degradation processes such as cavitation and wear which significantly reduce service life. Laser surface melting and cladding techniques have recently demonstrated a potential to substantially enhance the performance of NAB components. This is associated with the occurrence of a martensitic or Widmanstätten transformation from the high temperature bcc β phase accompanied by precipitation of ordered intermetallic particles collectively referred to as κ. Optimization of these techniques requires an improved understanding of the evolution of microstructure in the NAB system under conditions of rapid solidification, however little data is currently available. In this paper, transmission electron microscopy is used to examine the microstructures of a series of laser surface melted NAB alloys containing from 8 to 12 wt. % Al, 3.8 to 6.5 wt. % Ni, 3.8 to 6.5 wt. % Fe, ∽1 wt. % Mn and, in some cases, lesser amounts of Ti or Zr.
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6

Goldman, R. W., A. E. Segall, and J. C. Conway. "The Dry Sliding Behavior of Aluminum Alloys Against Steel in Sheave Wheel Applications." Journal of Tribology 123, no. 4 (October 20, 2000): 676–81. http://dx.doi.org/10.1115/1.1339981.

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The dry sliding behavior of various 2xxx and 7xxx aluminum alloys with and without nickel-aluminum bronze-coatings were evaluated for industrial sheave wheel applications involving steel cables. In order to simulate the wear caused by a cable within the sheave groove, wear tests were conducted using a pin-on-ring wear test configuration. For these tests, the various aluminum alloys were worn against a 387 steel using an interfacial pressure of 13.9 MPa and a sliding velocity of 9.42 m/s. Results indicated that for the conditions studied, the 7xxx aluminum alloys exhibited a superior wear resistance relative to the 2xxx aluminum alloys with and without nickel-aluminum bronze coatings. A wear mode analysis based upon optical and electron microscopy revealed material removal mechanisms dominated by adhesive and abrasive wear. Moreover, a statistical analysis indicated a potential relationship between wear rate and a combination of yield strength, solidus temperature and post-wear inverse hardness.
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7

Jin, Kongjie, Zhuhui Qiao, Shuai Wang, Shengyu Zhu, Jun Cheng, Jun Yang, and Weimin Liu. "The effects of the main components of seawater on the tribological properties of Cu–9Al–5Ni–4Fe–Mn alloy sliding against AISI 52100 steel." RSC Advances 6, no. 8 (2016): 6384–94. http://dx.doi.org/10.1039/c5ra19719h.

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8

Mota, N. M., S. S. M. Tavares, A. M. do Nascimento, G. Zeeman, and M. V. Biezma-Moraleda. "Failure analysis of a butterfly valve made with nickel aluminum Bronze (NAB) and manganese aluminum Bronze (MAB)." Engineering Failure Analysis 129 (November 2021): 105732. http://dx.doi.org/10.1016/j.engfailanal.2021.105732.

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9

Kuppahalli, Prabhakar, R. Keshavamurthy, P. Sriram, and J. T. Kavya. "Microstructural and Mechanical behaviour of Nickel Aluminum Bronze alloys." IOP Conference Series: Materials Science and Engineering 577 (December 7, 2019): 012044. http://dx.doi.org/10.1088/1757-899x/577/1/012044.

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10

Siemek, K., M. K. Eseev, P. Horodek, A. G. Kobets, and I. V. Kuziv. "Defects studies of nickel aluminum bronze subjected to cavitation." Applied Surface Science 546 (April 2021): 149107. http://dx.doi.org/10.1016/j.apsusc.2021.149107.

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11

Zhao, Xu, Yuhong Qi, Jintao Wang, Tianxiang Peng, Zhanping Zhang, and Kejiao Li. "Effect of Weld and Surface Defects on the Corrosion Behavior of Nickel Aluminum Bronze in 3.5% NaCl Solution." Metals 10, no. 9 (September 11, 2020): 1227. http://dx.doi.org/10.3390/met10091227.

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To study the effect of weld and defects on the corrosion behavior of nickel aluminum bronze (UNS C95810) in 3.5% NaCl solution, the weight loss, X-ray diffraction, optical microscope, scanning electron microscope and electrochemical test of the specimen with weld and defects were investigated. The results show that the presence of weld and defects increases the corrosion rate of bronze. Weld does not change the structure of the corrosion product film, but defects induce a lack of the protective outermost corrosion product in bronze. Weld makes the corrosion product film in the early stage more porous. Defects always produce an increase in the dissolution rate of the bronze.
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12

Qin, Zhenbo, Zhong Wu, Xiangsen Zen, Qin Luo, Lei Liu, Weijie Lu, and Wenbin Hu. "Improving Corrosion Resistance of a Nickel-Aluminum Bronze Alloy via Nickel Ion Implantation." CORROSION 72, no. 10 (October 2016): 1269–80. http://dx.doi.org/10.5006/2097.

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13

Xing, Qing, Lin Fan, Wei Min Guo, Xiang Xi Chen, Li Hua Gong, and Chao Yang. "Galvanic Corrosion of 70-30 Copper-Nickel Alloy in Contact with Nickel-Aluminum Bronze in Simulated Deep Sea Environment." Advanced Materials Research 1095 (March 2015): 124–29. http://dx.doi.org/10.4028/www.scientific.net/amr.1095.124.

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The galvanic corrosion behavior of 70-30 copper-nickel alloy as a brand new seawater pipe material and nickel-aluminum bronze as the commonly used pipe valve material in simulated low temperature conditions of deep sea was studied. The galvanic corrosion potential and galvanic current density of the pair were monitored, and the galvanic corrosion tendency and effect at different temperature were evaluated. Combined with the electrochemical measurements, the influence of seawater temperature on galvanic corrosion behavior was also discussed. The results showed that as the result of coupling, 70-30 copper-nickel alloy acting as the coupled cathode was prevented from corrosion, while nickel-aluminum bronze became the sacrificial anode. With the decrease of seawater temperature, the galvanic corrosion tendency and galvanic corrosion rate of the pair decreased. The change in galvanic corrosion tendency with seawater temperature was attributed to the different electrochemical properties induced by the inherent difference in chemical compositions of the alloys. The low galvanic corrosion rate and effect were related to the reduced mass transfer rates at low temperature. Moreover, the electrochemical behavior of the copper alloys was much sensitive to the change in the amount of dissolved oxygen at the lower seawater temperature, especially for the alloy with higher passivation ability, i.e., 70-30 copper-nickel alloy.
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14

Anantapong, Jutamas, Surasak Suranuntchai, Anchalee Manonukul, and Vitoon Uthaisangsuk. "Investigation of Nickel Aluminum Bronze Alloy under Hot Compression Test." Advanced Materials Research 931-932 (May 2014): 365–69. http://dx.doi.org/10.4028/www.scientific.net/amr.931-932.365.

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The characteristics of Nickel Aluminum Bronze alloy (NAB) after hot deformation were investigated. The NAB alloy have been studied by dilatometer according to study the influence of hot deformation on microstructure of NAB alloy by dilatometer in the temperature range 800 - 950 °C, strain rate 10s-1 and cooling rate 40 and 100 °C/s. The experimental results showed that peak stress in relation to the involved deformation temperature, peak stresses at a constant strain rate decreased with an increase of deformation temperature. It was found that volume fraction of the β phase significantly increased with increasing temperature and cooling rate. The variation of this phase affected macro hardness of the investigated alloy. By higher temperatures, amount of β phase increased as well as the macro hardness of the NAB alloy.
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15

Al-Hashem, A., P. G. Caceres, W. T. Riad, and H. M. Shalaby. "Cavitation Corrosion Behavior of Cast Nickel-Aluminum Bronze in Seawater." CORROSION 51, no. 5 (May 1995): 331–42. http://dx.doi.org/10.5006/1.3293598.

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16

Amirkhiz, Babak Shalchi, Dharmendra Chalasani, and Mohsen Mohammadi. "TEM Study of Additively Manufactured Metallic Alloys: Nickel Aluminum Bronze." Microscopy and Microanalysis 25, S2 (August 2019): 2588–89. http://dx.doi.org/10.1017/s1431927619013679.

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17

Fang, Jie, Guo Lin Song, Wei Liu, and Qiu Lin Li. "Microstructure Evolution of As-Cast Nickel Aluminum Bronze under Electropulsing." Key Engineering Materials 861 (September 2020): 28–34. http://dx.doi.org/10.4028/www.scientific.net/kem.861.28.

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In this work, the microstructure evolution of as-cast NAB under different electropulsing parameters were studied. The microstructure of the electropulsing treatment (EPT) sample was characterized by mircohardness test and optical microscopy. The results show that compared with heat treatment, when the peak current density reaches 5.84×108A/m2 (no significant change in the structure when the peak current density is lower), the β' phase region undergo phase transition in a shorter time. When the peak current density reaches 7.25×108A/m2, the sample is significantly affected by the Joule heating effect, and the κⅢ and κⅣ phases are successively dissolved to form Widmanstätten α structure. As the β' phase increases and the Widmanstätten α structure forms, the hardness value of the microstructure increases by 80%.
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18

Palani, Sarangapani, Poovazhagan Lakshmanan, and Rajkumar Kaliyamurthy. "Experimental investigations of electrochemical micromachining of nickel aluminum bronze alloy." Materials and Manufacturing Processes 35, no. 16 (September 17, 2020): 1860–69. http://dx.doi.org/10.1080/10426914.2020.1813888.

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19

Wenschot, P. "A new nickel-aluminum bronze alloy with low magnetic permeability." Metallurgical and Materials Transactions A 28, no. 3 (March 1997): 689–97. http://dx.doi.org/10.1007/s11661-997-0055-0.

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20

Li, Yang, Ying Lian, and Yanjun Sun. "Cavitation erosion behavior of friction stir processed nickel aluminum bronze." Journal of Alloys and Compounds 795 (July 2019): 233–40. http://dx.doi.org/10.1016/j.jallcom.2019.04.302.

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21

Lin, Liangxu, Huaping Wu, Stephen J. Green, Joanna Crompton, Shaowei Zhang, and David W. Horsell. "Formation of tunable graphene oxide coating with high adhesion." Physical Chemistry Chemical Physics 18, no. 7 (2016): 5086–90. http://dx.doi.org/10.1039/c5cp06906h.

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Graphene oxide (GO) can form a highly adhered robust coating on nickel–aluminum–bronze (NAB) using a conceptual process (the formation and consolidation of a layer of GO), which allows further functionalisation of the coating for various potential applications.
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22

Eastham, D. R. "Electroplated Overlays for Crankshaft Bearings." Journal of Engineering for Gas Turbines and Power 115, no. 4 (October 1, 1993): 706–10. http://dx.doi.org/10.1115/1.2906763.

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Overlays of either lead-indium or lead-tin-copper are electroplated onto both lead-bronze and aluminum alloy crankshaft bearings to improve seizure resistance and conformability during the initial running-in period. In addition, both the corrosion resistance, particularly of lead-bronze, and the effective fatigue strength of the composite bearing are improved by this layer. The life of the overlay is largely dependent upon the diffusion rate of the low melting point species to the substrate. Thus, migration of either the indium or the tin will determine both the corrosion and wear rates of the overlay. Owing to the processing requirements, aluminum bearings require a nickel or copper interlayer prior to final overlaying with either of the lead alloys. For diffusion control reasons, when depositing lead-tin-copper onto lead-bronze it is usual to have a thin nickel dam to retard the formation of copper-tin intermetallics, which under given conditions may reduce the overall strength and adhesion; lead-indium does not require such a dam on lead-bronze. The principal differences between the two overlays lie in their respective fatigue and wear properties. Thus, lead-indium has a higher fatigue strength but lower wear resistance than lead-tin-copper. This paper compares these two major overlays and considers the selection criteria for the overlay employed.
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23

Cottam, R., T. Barry, D. McDonald, H. Li, D. Edwards, A. Majumdar, J. Dominguez, J. Wang, and M. Brandt. "Laser processing of nickel–aluminum bronze for improved surface corrosion properties." Journal of Laser Applications 25, no. 3 (May 2013): 032009. http://dx.doi.org/10.2351/1.4799555.

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24

FU, Zhong-tao, Wen-yu YANG, Si-qi ZENG, Bu-peng GUO, and Shu-bing HU. "Identification of constitutive model parameters for nickel aluminum bronze in machining." Transactions of Nonferrous Metals Society of China 26, no. 4 (April 2016): 1105–11. http://dx.doi.org/10.1016/s1003-6326(16)64207-3.

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25

Wang, Chengxi, Chuanhai Jiang, Ze Chai, Ming Chen, Lianbo Wang, and Vincent Ji. "Estimation of microstructure and corrosion properties of peened nickel aluminum bronze." Surface and Coatings Technology 313 (March 2017): 136–42. http://dx.doi.org/10.1016/j.surfcoat.2017.01.073.

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26

Lee, Taeyong. "Improvement of viscoelastic damping in nickel aluminum bronze by indium-tin." Metals and Materials International 17, no. 3 (June 2011): 425–30. http://dx.doi.org/10.1007/s12540-011-0619-9.

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27

Luo, Qin, Qi Zhang, Zhenbo Qin, Zhong Wu, Bin Shen, Lei Liu, and Wenbin Hu. "The synergistic effect of cavitation erosion and corrosion of nickel-aluminum copper surface layer on nickel-aluminum bronze alloy." Journal of Alloys and Compounds 747 (May 2018): 861–68. http://dx.doi.org/10.1016/j.jallcom.2018.03.103.

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28

Gerashchenkova, E. Yu, D. A. Gerashchenkov, and A. N. Belyakov. "Investigation of nickel coatings obtained by laser processing on the surface of bronze." Voprosy Materialovedeniya, no. 2(106) (August 1, 2021): 105–12. http://dx.doi.org/10.22349/1994-6716-2021-106-2-105-112.

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The article presents the results of a comprehensive study of the modes of laser processing during the formation of a coating on nickel-aluminum bronze using nickel powders. The coating was obtained in two stages. At the first stage, a precursor coating of the powder material was applied by cold spraying, at the second stage, its surface treatment with a laser was performed. The change in the composition and properties of the coating is shown depending on the processing modes and the thickness of the precursor coating, as well as the modes of laser processing.
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29

Palaci, Yuksel, and Guven Gonca. "The effects of different engine material properties on the performance of a diesel engine at maximum combustion temperatures." Thermal Science 24, no. 1 Part A (2020): 183–91. http://dx.doi.org/10.2298/tsci180916164p.

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In this study, the influences of various engine materials such as palladium, titanium, thorium, zirconium, vanadium, alumina, aluminum bronze, copper, iron (gray cast), manganese, nickel, cobalt, and carbon steel on the effective efficiency and effective power with respect to the variation of equivalence ratio at the maximum combustion temperatures. In-cylinder gas temperatures have been determined with respect to the melting temperatures and the performance values have been calculated with respect to the variation of the gas temperatures. The results indicated that alumina provides the maximum performance values as aluminum bronze gives the minimum performance values due to the combustion temperatures. Further-more, the equivalence ratios which give the maximum performance characteristics have been parametrically described. The obtained results can be assessed by engine designers and manufacturers to choose suitable engine material.
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30

Munro, Cameron, Phuong Vo, and Bruno Guerreiro. "Preliminary Development of Cold Spray Procedures for Nickel Aluminum Bronze Casting Repair." Materials Science Forum 1016 (January 2021): 971–77. http://dx.doi.org/10.4028/www.scientific.net/msf.1016.971.

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Nickel aluminum bronze (NAB) castings possess favourable combinations of strength and resistance to corrosion, biofouling and cavitation/erosion, and so have long been used in naval applications. Nonetheless, in seawater environments NAB castings are susceptible to selective phase corrosion and so such components periodically require either replacement, which is very costly, or repair. However, repairs involving traditional, high heat input welding operations can lead to distortion and microstructural changes that unacceptably degrade NAB corrosion performance, and so repairs are not commonly performed. In the present work, cold spray is explored as an alternative for NAB (alloy CuAl9Fe5Ni5) repair without excessive distortion or base metal degradation, and preliminary results of its performance reported. Suitable cold spray parameters have been determined using an iterative approach by analyzing deposits in terms of microstructure, porosity and adhesion to the substrate. It is intended that these parameters will later be used to create simulated repairs which can be more thoroughly characterized for strength, toughness and corrosion performance.
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31

UNO, Yoshiyuki, Akira OKADA, Tomohiko YAMADA, Yasuhiro HAYASHI, and Yoshiaki TABUCHI. "Surface Integrity in EDM of Aluminum Bronze with Nickel Powder Mixed Fluid." Journal of The Japan Society of Electrical Machining Engineers 32, no. 70 (1998): 24–31. http://dx.doi.org/10.2526/jseme.32.70_24.

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32

Thossatheppitak, Borpit, Surasak Suranuntchai, Vitoon Uthaisangsuk, Anchalee Manonukul, and Pinai Mungsuntisuk. "Microstructure Evolution of Nickel Aluminum Bronze Alloy during Compression at Elevated Temperatures." Advanced Materials Research 893 (February 2014): 365–70. http://dx.doi.org/10.4028/www.scientific.net/amr.893.365.

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In this work, effects of temperature and strain rate on microstructure development of a Nickel Aluminum Bronze (NAB) alloy during hot compression were investigated. The temperatures between 750°C and 900°C, strain rates between 0.1 s-1 and 10 s-1 and a deformation degree of 60% were considered. Microstructure analyses were performed for the samples after the compression using scanning electron microscopy technique. The results showed that microstructure of as-cast NAB alloy consisted of α, β' and κ phase. After homogenization β' phase transformed to the α and κ phase. Furthermore, different heating temperatures led to varying initial microstructures before forming and subsequent deformation, forming rates and cooling caused precipitation of various intermetallic phases. The α phase was found in the final microstructures of all forming conditions. At high forming temperatures, some intermetallic κ phases tended to dissolve and precipitated during cooling according to applied strain rate. However, at lower temperatures of 750-850°C, no significant effect of the strain rate on alteration of intermetallic κ phases.
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33

Lenard, D. R., C. J. Bayley, and B. A. Noren. "Electrochemical Monitoring of Selective Phase Corrosion of Nickel Aluminum Bronze in Seawater." CORROSION 64, no. 10 (October 2008): 764–72. http://dx.doi.org/10.5006/1.3278444.

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34

Takaloo, Ashkan Vakilipour, Mohammad Reza Daroonparvar, Mehdi Mazar Atabaki, and Kamran Mokhtar. "Corrosion Behavior of Heat Treated Nickel-Aluminum Bronze Alloy in Artificial Seawater." Materials Sciences and Applications 02, no. 11 (2011): 1542–55. http://dx.doi.org/10.4236/msa.2011.211207.

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35

McNelley, T., and S. Menon. "Microstructure and Microtexture Development during Friction Stir Processing of Nickel Aluminum Bronze." Microscopy and Microanalysis 18, S2 (July 2012): 1662–63. http://dx.doi.org/10.1017/s1431927612010161.

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36

Nandakumar, M. B., K. G. Sudhakar, Harshad Natu, and G. B. Jagadish. "Experimental investigation of slurry erosion characteristics of laser treated nickel aluminum bronze." Materials Today: Proceedings 5, no. 1 (2018): 2641–49. http://dx.doi.org/10.1016/j.matpr.2018.01.044.

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37

Heydarzadeh Sohi, M., S. M. H. Hojjatzadeh, A. Khodayar, and A. Amadeh. "Liquid phase surface alloying of a nickel aluminum bronze alloy with titanium." Surface and Coatings Technology 325 (September 2017): 617–26. http://dx.doi.org/10.1016/j.surfcoat.2017.07.019.

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38

Klassen, R. D., C. V. Hyatt, P. R. Roberge, G. A. Botton, and J. A. Gianetto. "Corrosion Behaviour of an Experimental Nickel Aluminum Bronze Within an Artificial Crevice." Canadian Metallurgical Quarterly 41, no. 1 (January 2002): 121–32. http://dx.doi.org/10.1179/cmq.2002.41.1.121.

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39

Zhang, Beibei, Jianzhang Wang, Hao Liu, Junya Yuan, Pengfei Jiang, and Fengyuan Yan. "Assessing the Tribocorrosion Performance of Nickel–Aluminum Bronze in Different Aqueous Environments." Tribology Transactions 62, no. 2 (January 17, 2019): 314–23. http://dx.doi.org/10.1080/10402004.2018.1557775.

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40

Chen, Zheng Han, Xiao Feng Sun, and Yuan Lin Huang. "A Brief Discussion about Nickel Aluminum Bronze Propeller Failure Modes and its Repair Methods." Key Engineering Materials 723 (December 2016): 125–29. http://dx.doi.org/10.4028/www.scientific.net/kem.723.125.

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Nickel aluminum bronze is widely used in manufacturing propeller, in marine environment, propellers are easy to generate corrosion, it is important to find efficient solutions to repair corrosive propeller. In this study, it utilized OM and SEM to observe the failure modes of propeller, and discuss the feasibility of using cold spray (CS) technology to repair corrosive propeller. The study showed that failure modes of propeller includes corrosion, cavitations and abrasion, cold spray is possible an effective solution to solve these failures.
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41

Rao, De Lin, and Yin Zhong Shen. "Mechanical Behavior Evaluation of a Nickel-Aluminum Bronze Alloy Weld with Micro Indentation Method." Key Engineering Materials 734 (April 2017): 293–300. http://dx.doi.org/10.4028/www.scientific.net/kem.734.293.

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In this research, the mechanical behavior of a multi-pass nickel-aluminum bronze alloy weld joint is investigated. Macro-tensile testing shows the mechanical behavior difference of the weld and base materials. Micro indentation data is applied to calculate the local mechanical properties in a multi-pass weld and base materials. The indentation loading-unloading cycle and stress-strain calculation model are introduced in the paper. It shows that the micro indentation results are in good agreement with the macro-tensile test data. Both the micro structure and uncertainties within the analysis model affect the discrepancy of two testing methods.
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42

Thossatheppitak, Borpit, Surasak Suranuntchai, Vitoon Uthaisangsuk, Anchalee Manonukul, and Pinai Mungsuntisuk. "Mechanical Properties at High Temperatures and Microstructures of a Nickel Aluminum Bronze Alloy." Advanced Materials Research 683 (April 2013): 82–89. http://dx.doi.org/10.4028/www.scientific.net/amr.683.82.

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Nickel Aluminum Bronze (NAB) alloys have been widely used in different kinds of machine parts where the superior resistance to corrosion and erosion in saltwater is needed. In this work, mechanical properties at high temperatures and microstructures of a NAB alloy were investigated. First, NAB specimens were prepared as an as-cast ingot and were subsequently heat-treated at 675°C for 6 hours in order to improve microstructure and mechanical properties. The mechanical properties at high temperatures in form of the plastic flow curves of the NAB alloy were characterized by a deformation dilatometer. The NAB samples were compressed at high temperature and rapidly cooled down to room temperature. The deformation temperatures of 825°C, 850°C and 900°C, a strain rate of 0.01 s-1, and a maximum compression strain of 0.4 were considered. The influences of the temperature on flow behavior of the NAB alloy were investigated. The plastic stress-strain curves at different temperatures were compared with regard to the rate of material strain hardening and softening. It was found that the compression stresses decreased with increasing temperatures. Additionally, the resulted hardness and microstructures of the alloy after forming at high temperatures were analyzed.
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43

Lotfollahi, M., M. Shamanian, and A. Saatchi. "Effect of friction stir processing on erosion–corrosion behavior of nickel–aluminum bronze." Materials & Design (1980-2015) 62 (October 2014): 282–87. http://dx.doi.org/10.1016/j.matdes.2014.05.037.

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44

Klassen, R. D., C. V. Hyatt, and P. R. Roberge. "Passivation of Laser-Treated Nickel Aluminum Bronze as Measured By Electrochemical Impedance Spectroscopy." Canadian Metallurgical Quarterly 39, no. 2 (January 2000): 235–46. http://dx.doi.org/10.1179/cmq.2000.39.2.235.

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45

Zhang Zebin, 章泽斌, 花银群 Hua Yinqun, 叶云霞 Ye Yunxia, 陈瑞芳 Chen Ruifang, 李志宝 Li Zhibao, 杨进 Yang Jin, and 帅文文 Shuai Wenen. "Fabrication of Superhydrophobic Nickel-Aluminum Bronze Alloy Surfaces Based on Picosecond Laser Pulses." Chinese Journal of Lasers 46, no. 3 (2019): 0302013. http://dx.doi.org/10.3788/cjl201946.0302013.

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46

Lee, Taeyong. "Enhanced viscoelastic properties of nickel–aluminum–bronze alloyed with indium or its alloys." Advanced Composite Materials 26, no. 1 (August 3, 2016): 45–54. http://dx.doi.org/10.1080/09243046.2016.1187820.

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47

Xu, Xiaoyan, Yuting Lv, Meng Hu, Di Xiong, Lefu Zhang, Liqiang Wang, and Weijie Lu. "Influence of second phases on fatigue crack growth behavior of nickel aluminum bronze." International Journal of Fatigue 82 (January 2016): 579–87. http://dx.doi.org/10.1016/j.ijfatigue.2015.09.014.

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48

Zhou, Ruihu, and Wenyu Yang. "Analytical modeling of residual stress in helical end milling of nickel-aluminum bronze." International Journal of Advanced Manufacturing Technology 89, no. 1-4 (July 15, 2016): 987–96. http://dx.doi.org/10.1007/s00170-016-9145-8.

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49

Küçükömeroğlu, T., E. Şentürk, L. Kara, G. İpekoğlu, and G. Çam. "Microstructural and Mechanical Properties of Friction Stir Welded Nickel-Aluminum Bronze (NAB) Alloy." Journal of Materials Engineering and Performance 25, no. 1 (December 17, 2015): 320–26. http://dx.doi.org/10.1007/s11665-015-1838-x.

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50

McDonald, Daniel T., Cameron J. Barr, and Kenong Xia. "Effect of Equal Channel Angular Pressing on Lamellar Microstructures in Nickel Aluminum Bronze." Metallurgical and Materials Transactions A 44, no. 12 (September 6, 2013): 5556–66. http://dx.doi.org/10.1007/s11661-013-1888-3.

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