Welding Metallurgy. Sindo Kou. Читать онлайн. Newlib. NEWLIB.NET

Автор: Sindo Kou
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Техническая литература
Год издания: 0
isbn: 9781119524915
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      3.4.3 Physical Simulation of Fluid Flow and Weld Penetration

Schematic illustration of the Welds in Wood's metal which is produced under the influence of: (a) buoyancy force, and (b) Lorentz force.

      Source: Kou and Sun [23]. © TMS.

Schematic illustration of the bead-on-plate weld of 304 stainless steel with 40 ppm sulfur made by conduction-mode laser beam welding at 3 kW and 7.62 mm/s.

      Source: Chao and Kou [34].

      Heiple's theory represents a major milestone in welding science and should be verified, especially the reversal of Marangoni flow by a surface‐active agent. The computer simulation of Sun and Kou [23] was the first theoretical verification of the reversed Marangoni flow and deepened weld penetration caused by a surface‐active agent. Although this was significant, the most direct verification is still flow visualization, that is, to actually see the flow going inward along the pool surface and downward along the pool axis when the surface‐active agent is present. Since liquid metal is opaque to visible light, visualization of fluid flow below the weld pool surface is difficult to do.

Schematic illustration of the visualization of Marangoni flow using laser light-cut technique: (a) vertical light sheet and (b) horizontal light sheet.

      Source: Limmaneevitchitr, Kou, Wei. Welding Journal, May 2000 and December 2011, © American Welding Society

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Schematic illustration of the verifying effect of surface-active agent on Marangoni flow using NaNO3: (a) outward flow, (b) inward flow in a NaNO3 pool containing 2 mol percent C2H5COOK as a surface-active agent.

      Source: Limmaneevitchitr and Kou [40, 41]. Welding Journal, May 2000 and November 2000, © American Welding Society.

      It is worth noting that in conduction‐mode (no keyholing) laser beam welding, the pool surface can be concave due to Marangoni convection and surface tension [32] and, in fact, this has been shown to be the case experimentally [42] and by computer simulation [43]. The concave NaNO3 pool surface in Figure 3.22, however, is just a coincidence – that is, the melt wets the container wall and the meniscus makes the pool surface concave.

      3.4.4 Computer Simulation of Fluid Flow and Weld Penetration

      Mishra et al. [45] showed that for a 304 stainless steel with 0.003 wt% (30 ppm) sulfur, ∂γ/∂T < 0 for the entire temperature range, and the outward surface flow transferred heat to the pool edge, thus resulting in a shallow weld. At 0.024 wt% (240 ppm) sulfur ∂γ/∂T > 0 up to about 2100 K (Fig. 3.18). The surface flow became inward and turned downward near the center of the pool surface to the pool bottom, carrying heat downward to the bottom and thus resulting in a deeper weld.

      It is interesting to note that fluid flow in the weld pool can affect the shape of the pool surface.