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Nickel-gold alloys

In this paper, the performanees of laser-ultrasound are estimated in order to identify lacks of weld penetration. The laser-ultrasonic technique is applied to cylindrical metallic strucmres (few mm thick) in a single-sided control. The results obtained for different materials (gold-nickel alloy and tantalum) are presented by B-sean views for which the control configuration is discussed with regard to the thermal effects at the laser impact. This testing is performed for different lacks of weld penetration (up to 0.5 mm for a thickness of 2 mm) even in the presence of the weld bead, which corresponds to an actual industrial problem. [Pg.693]

This paper deals with the control of weld depth penetration for cylinders in gold-nickel alloy and tantalum. After introducing the experimental set-up and the samples description, the study and the optimization of the testing are presented for single-sided measurements either in a pulse-echo configuration or when the pump and the probe laser beams are shifted (influence of a thermal phenomenon), and for different kind of laser impact (a line or a circular spot). First, the ultrasonic system is used to detect and to size a flat bottom hole in an aluminium plate. Indeed, when the width of the hole is reduced, its shape is nearly similar to the one of a slot. Then, the optimization is accomplished for... [Pg.693]

Fig. 2 Description of the weld depths penetration for gold-nickel alloy and tantalum cylinders. Fig. 2 Description of the weld depths penetration for gold-nickel alloy and tantalum cylinders.
Fig. 3 Description of the artificial slots for gold-nickel alloy cylinders. Fig. 3 Description of the artificial slots for gold-nickel alloy cylinders.
Fig. 7 B-scan views of the artificial slots of height 1.7 nun left image) and 0.6 mm (right image) in a split configuration for gold-nickel alloy. Fig. 7 B-scan views of the artificial slots of height 1.7 nun left image) and 0.6 mm (right image) in a split configuration for gold-nickel alloy.
Then, the weld depths penetration are controlled in a pulse-echo configuration because the weld bead (of width 2 mm) disturbs the detection when the pump and the probe beams are shifted of 2.2 mm. The results are presented in figure 8 (identical experimental parameters as in figure 7). The slow propagation velocities for gold-nickel alloy involve that the thermal component does not overlap the ultrasonic components, in particular for the echo due to the interaction with a lack of weld penetration. The acoustic response (V shape) is still well observed both for the slot of height 1.7 mm and for a weld depth penetration of 0.8 mm (lack of weld penetration of 1.7 mm), even with the weld bead. This is hopeful with regard to the difficulties encountered by conventional ultrasound in the case of the weld depths penetration. [Pg.698]

The weld depths penetration for gold-nickel alloy and tantalum cylinders have been well controlled by an entirely contactless ultrasound method. Nevertheless, the development of signal and image processing will allow to increase the resolution of the ultrasonic images. Moreover, in order to be able to size quite well the lacks of weld penetration, the simulation of the interaction beam-defect is presently developed in our laboratory. [Pg.699]

Gold-copper alloys exhibit exceptional resistance to corrosion, and have very low vapour pressures. Gold-nickel alloys, with similar low vapour pressure, are somewhat stronger than gold-copper at high temperatures. Both series of alloys are widely employed in vacuum systems. [Pg.937]

Gold-copper, alloy (Au5Cu5, AuBCuB(S)), calculation of thermodynamic quantities, 136, 142 solid solution (CuAu), 129 Gold-lead, alloy (Au5Pb5), calculation of thermodynamic quantities, 136 Gold-nickel, alloy (Au5Ni8), calculation of thermodynamic quantities, 136, 142... [Pg.406]

An explanation of why a gold/nickel surface alloy is formed, whereas no bulk three-dimensional gold/nickel alloy exists (reflecting the fact that the heat of... [Pg.107]

Binary Alloys. The material Au-20wt%Ag is used for low-voltage electrical contacts. Gold-copper alloys form the ordered phases AusCu [60748-60-9], AuCu [12006-51-8], and AuCus [12044-96-1]. Gold-nickel alloys decompose into gold-rich and nickel-rich solid... [Pg.361]

Fig. 3. Liquidus isotherms of gold—cooper—nickel alloys and phase diagrams of the binary substituents (85). Fig. 3. Liquidus isotherms of gold—cooper—nickel alloys and phase diagrams of the binary substituents (85).
GoldJilloys, Wrought Type. Two types of wrought gold alloys were formerly recognized by the ADA specification no. 7 for the fabrication of orthodontic and prosthetic dental appHances, ie, type I, high-precious-metal alloys, and type II, low-precious-metal alloys (gold color). Alloys of this type are seldom used in the United States they have been replaced by stainless steels and nickel—titanium alloys. [Pg.484]

Palladium and Palladium Alloys. Palladium is used in telephone equipment and in electronics appHcations as a substitute for gold in specific areas. Palladium is plated from ammoniacal and acid baths available along with chelated variations as proprietary processes. One typical alkaline bath uses 8 g/L diammine-dinitropalladium, 100 g/L ammonium nitrate, and 10 g/L sodium nitrite. The pH is adjusted to 9—10 using ammonium hydroxide, and the bath is operated at 100 A/m at 50° C. If ammonium sulfamate, 100 g/L, is used in some baths to replace the nitrate and sodium nitrite salts, the bath is mn at lower temperature, 25—35°C, and a pH of 7.5—8.5. A palladium—nickel alloy, 75% Pd, is plated from a bath having 6 g/L palladium from the same salt, 3 g/L nickel from nickel sulfamate concentrate, and 90 g/L ammonium hydroxide. The bath is operated at 20—40°C with 50-100 A/m/... [Pg.163]

The kinetics of spinodal decomposition is complicated by the fact that the new phases which are formed must have different molar volumes from one another, and so tire interfacial energy plays a role in the rate of decomposition. Anotlrer important consideration is that the transformation must involve the appearance of concenuation gradients in the alloy, and drerefore the analysis above is incorrect if it is assumed that phase separation occurs to yield equilibrium phases of constant composition. An example of a binary alloy which shows this feature is the gold-nickel system, which begins to decompose below 810°C. [Pg.191]

The effects on oxidation resistance of copper as a result of adding varying amounts of one or more of aluminium, beryllium, chromium, manganese, silicon, zirconium are described in a number of papers Other authors have investigated the oxidation of copper-zincand copper-nickel alloys , the oxidation of copper and copper-gold alloys in carbon dioxide at 1 000°C and the internal oxidation of various alloys ". ... [Pg.705]

The development of new alloys in new fields for example the development of molybdenum and tungsten with iron, cobalt or nickel for coating of dies and nozzles, or the development of palladium-nickel alloy as an alternative to gold for connectors. [Pg.377]

Industry, however, favours electrodeposited palladium-nickel alloy since it is cheaper than palladium, harder and less prone to cracking, fingerprinting and formation of polymer films Its wear resistance is poor, so it is usually given a thin topcoat of hard (sometimes, soft) gold. ... [Pg.566]

Hardy and Linnett (59) studied the heterogeneous recombination of atomic hydrogen at room temperature on nickel and nickel alloy foils. They did not find any similarity to the behavior of palladium and its alloys with gold studied earlier (35). There was no evidence that, as a result of exposure to atomic hydrogen, hydride was formed in any metal catalyst investigated with a resulting change in the activity of the initial parent metal catalysts. [Pg.273]


See other pages where Nickel-gold alloys is mentioned: [Pg.694]    [Pg.695]    [Pg.696]    [Pg.699]    [Pg.107]    [Pg.107]    [Pg.694]    [Pg.695]    [Pg.696]    [Pg.699]    [Pg.107]    [Pg.107]    [Pg.322]    [Pg.87]    [Pg.379]    [Pg.383]    [Pg.384]    [Pg.384]    [Pg.385]    [Pg.183]    [Pg.484]    [Pg.485]    [Pg.486]    [Pg.48]    [Pg.30]    [Pg.31]    [Pg.106]    [Pg.145]    [Pg.942]    [Pg.514]    [Pg.49]   


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