References of "Mashhood, Muhammad 50035110"
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See detailThree-dimensional CFD-DEM simulation of raceway transport phenomena in a blast furnace
Aminnia, Navid UL; Adhav, Prasad UL; Darlik, Fateme UL et al

in Fuel (2023), 334(2),

Improving energy efficiency in a blast furnace (BF) has a significant effect on energy consumption and pollutant emission in a steel plant. In the BF, the blast injection creates a cavity, the so-called ... [more ▼]

Improving energy efficiency in a blast furnace (BF) has a significant effect on energy consumption and pollutant emission in a steel plant. In the BF, the blast injection creates a cavity, the so-called raceway, near the inlet. On the periphery of the raceway, a ring-type zone is formed which is associated with the highest coke combustion rate and temperatures in the raceway. Therefore, predicting the raceway size or in other words, the periphery of the ring-type zone with accuracy is important for estimating the BF’s energy and coke consumption. In the present study, Computational Fluid Dynamics (CFD) is coupled to Discrete Element Method (DEM) to develop a three-dimensional (3D) model featuring a gas–solid reacting flow, to study the transport phenomena inside the raceway. The model is compared to a previously developed two-dimensional (2D) model and it is shown that the assumptions associated with a 2D model, result in an overestimation of the size of the raceway. The 3D model is then used to investigate the coke particles’ combustion and heat generation and distribution in the raceway. It is shown that a higher blast flow rate is associated with a higher reaction rate and a larger raceway. A 10% increase in the inlet velocity (from 200 m/s to 220 m/s) caused the raceway volume to grow by almost 40%. The DEM model considers a radial discretization over the particle, therefore the heat and mass distributions over the particle are analyzed as well. [less ▲]

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See detailDeveloping the AM G-code based thermomechanical finite element platform for the analysis of thermal deformation and stress in metal additive manufacturing process
Mashhood, Muhammad UL; Peters, Bernhard UL; Zilian, Andreas UL et al

in Journal of Mechanical Science and Technology (2023)

The 3D printing process known as SLM involves the melting of the metal powder, which results in a melt-pool. When this melt-pool solidifies, the solidified metal undergoes cooling and reheating in the ... [more ▼]

The 3D printing process known as SLM involves the melting of the metal powder, which results in a melt-pool. When this melt-pool solidifies, the solidified metal undergoes cooling and reheating in the presence of air and multiple laser passes for continuous material consolidation. As a result of such thermal cycles, the manufactured part develops permanent thermal deformation and residual stresses. The current work proposes the FEM and AM G-code based numerical strategy to qualitatively analyze the formation of such deformations and stresses at part scale. A multi-physics model was developed by coupling of transient thermal heat equation with non-linear structural solver. To mimic the consolidation of material with laser motion, the finite elements were activated as per the pattern of metal deposition under the influence of AM G-code. A numerical experiment was conducted to virtually manufacture the part with mechanical properties of 15--5PH stainless steel [1]. We found that the thermomechanical FEM model interfaced with the AM G-code translated data helps to evaluate the comparable trends of thermal deformation and residual stress results with already established studies. This demonstrates that with a given set of operational instructions, how the thermal conduction, convection and radiation drive the AM process by thermally loading the deposited material. Furthermore, the AM G-code interfacing facilitated the communication of laser scanning path with numerical FEM solver. We anticipate that such development may enable the manufacturing and simulation engineers to early estimate the possible final deformation of the AM fabricated part. Additionally, the developed strategy may also be the initial step for the physically informed neural networks to optimize the laser scan path for precise manufacturing of the metal parts. [less ▲]

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See detailDEVELOPMENT OF RESIDUAL STRESS DURING PART BUILD IN METAL ADDITIVE MANUFACTURING
Mashhood, Muhammad UL

Doctoral thesis (2022)

The Additive Manufacturing (AM) process is the scale-able, flexible and prospective way of fabricating the parts. It forms the product of desired design by depositing layer upon layer of material to print ... [more ▼]

The Additive Manufacturing (AM) process is the scale-able, flexible and prospective way of fabricating the parts. It forms the product of desired design by depositing layer upon layer of material to print the object in 3D. It has a vast field of applications from forming prototypes to the manufacturing of sophisticated parts for space and aeronautical industry. It has even found its way into the domain of biological research and the development of implants and artificial organs. Depending upon the form of the raw material and the mechanism of printing it layer upon layer, there are different techniques of AM in metal parts production. One of them is Selective Laser Melting (SLM). This process involves the raw material in the form of metal powder. To manufacture the product, this powder first undergoes melting through a moving laser. Afterwards, it solidifies and joins with the already solidified structure in the layer below. The movement of the laser is carried out in the shape of a 2D cross-section design which has to be consolidated at the corresponding height. This process involves the repetitive heating and cooling of the material which causes sharp thermal gradients in the object. Because of such gradients, the material during manufacturing consistently undergoes thermal loading. Such thermal loading, therefore, induces the residual stress and permanent distortion in the manufactured part. These residual stress and thermally induced distortions affect the quality of the part and cause the mismatch in dimensions between the final product and the required design. To reduce the waste of raw material and energy, therefore it is important to predict such problems beforehand. This research work presents the modelling of a numerical simulation platform which simulates the part-scale AM SLM part manufacturing process and its cooling down in a virtual environment. The objective of establishing this platform was to evaluate the residual stress and thermal distortion. It included the modelling of thermal & structural analysis and their coupling to establish the multi-physics simulation tool. The transient thermal analysis with the elastoplastic non-linearity of the material model was implemented to capture the permanent deformation behaviour of a material under thermal loading. The modelling was done on the Finite Elements Method (FEM) based open source numerical analysis tools to incorporate the flexibility of numerical modelling in the project. The modelling strategy of solidified material deposition was incorporated via the elements activation technique. To synchronize the activation of the elements in the multi-physics FEM solver with the laser movement, the interfacing with AM G-code based data was performed. With this modelling strategy, the simulation experiments were conducted to analyse the evolution of thermal gradients, residual stress and deformation in part manufacturing. The study also highlights the challenges of the applied elements activation technique and its limitations. It was also studied how the prediction of simulation results vary with the different material deposition methods. Moreover, the resulting numerical analysis of the established simulation platform was also compared with the experimental and validated simulation data to ensure its reliability. In this comparative study, the current numerical strategy replicated the trends of stress and deformation from physical experimental data and represented the expected material behaviour in the manufactured part. Additionally, during this study, the skill gained for results handling and their validation was also applied in the other field of numerical modelling e.g. in the numerical analysis conducted for a blast furnace with Computational Fluid Dynamics - Discrete Element Method (CFD-DEM) coupled multi-physics platform of eXtended Discrete Element Method (XDEM). The current working simulation platform, via its AM G-code machine data interface with numerical solver, can facilitate the manufacturing engineers to predict earlier the possible thermally caused residual stress and deformation in their AM SLM produced product via simulation. On the other hand with the identified challenges in the virtual depiction of material deposition, the simulation developers may also be able to expect such limitations and make relevant decisions in the choice of material deposition technique in their AM SLM process modelling. Moreover, with the potential of this simulation tool being the basic building block, it may also provide the opportunity to build upon it the multi-scale numerical techniques and add them to the multidisciplinary research work of Artificial Intelligence based digital twins. [less ▲]

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See detailMATERIAL MODELLING AND FINITE ELEMENT ANALYSIS IN METAL ADDITIVE MANUFACTURING
Mashhood, Muhammad UL; Baroli, Davide; Wyart, Eric et al

Poster (2022, May 31)

The additive manufacturing (AM) is competent method for the manufacturing of complex metal parts with wider process flexibility. During manufacturing, the metal part repetitively undergoes heating and ... [more ▼]

The additive manufacturing (AM) is competent method for the manufacturing of complex metal parts with wider process flexibility. During manufacturing, the metal part repetitively undergoes heating and cooling under the influence of laser passes and ambient conditions respectively. In turn, the material experiences the thermal strain and residual stress. The aim of the work is to predict them using certain material model. Where the solidified metal part from melt-pool is considered in current analysis. For numerical simulation, Finite Element Method (FEM) is chosen. The heat equation is first solved for thermal profile of AM Process. Afterwards, the structural analysis is performed with such thermal load. The non linear constitutive material model is utilised. For concerned material model, the temperature dependence upon the material properties is also implemented. The resulting Finite Element Analysis (FEA) platform offers the macro-scale thermal solution and the prediction of resulting plastic distortion in material. This prediction however has become more accurate when the variable material property, depending upon the temperature of analysis zone, is introduced. [less ▲]

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See detailTHE EVOLUTION OF THERMAL DISTORTION AND STRESSES AT MACRO SCALE FOR METAL ADDITIVELY MANUFACTURED PART
Mashhood, Muhammad UL; Zilian, Andreas UL; Peters, Bernhard UL et al

Scientific Conference (2022, February 05)

[1] R.K. Ganeriwala, M. Strantza, W.E. King, B. Clausen, T.Q. Phan, L.E. Levine, D.W. Brown, N.E. Hodge, Evaluation of a thermomechanical modelfor prediction of residual stress during laser powder bed ... [more ▼]

[1] R.K. Ganeriwala, M. Strantza, W.E. King, B. Clausen, T.Q. Phan, L.E. Levine, D.W. Brown, N.E. Hodge, Evaluation of a thermomechanical modelfor prediction of residual stress during laser powder bed fusion of Ti-6Al- 4V, Additive Manufacturing(2019), Vol. 27., 489–502. [2] M. S. Alnaes, J. Blechta, J. Hake, A. Johansson, B. Kehlet, A. Logg, C. Richardson, J. Ring, M. E. Rognes and G. N. Wells, The FEniCS Project Version 1.5, Archive of Numerical Software(2015), Vol. 3., 100:9–23. [less ▲]

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See detailThermo-mechanical modelling for metal additive manufacturing
Mashhood, Muhammad UL; Baroli, Davide; Wyart, Eric et al

Scientific Conference (2021, October 27)

[1] Alnaes, M. S. Blechta, J. Hake, J. Johansson, A. Kehlet, B. Logg, A. Richardson, C. Ring, J.Rognes, M. E. and Wells, G. N. The FEniCS Project Version 1.5. Archive of Numerical Software(2015), Vol. 3 ... [more ▼]

[1] Alnaes, M. S. Blechta, J. Hake, J. Johansson, A. Kehlet, B. Logg, A. Richardson, C. Ring, J.Rognes, M. E. and Wells, G. N. The FEniCS Project Version 1.5. Archive of Numerical Software(2015), Vol. 3., 100:9–23. [2] Carraturo, M. and Kollmannsberger, S. and Reali, A. and Auricchio, F. and Rank, E. An immersed boundary approach for residual stress evaluation in SLM processes. [less ▲]

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See detailThermo-mechanical coupling and part-level analysis for additive manufacturing processes
Mashhood, Muhammad UL; Baroli, Davide; Zilian, Andreas UL et al

Scientific Conference (2021, January 13)

[1] Hussein, A. and Hao, L. and Yan, C. and Everson, R. Finite element simulation of the temperature and stress fields in single layers built without-support in selective laser melting. Materials & Design ... [more ▼]

[1] Hussein, A. and Hao, L. and Yan, C. and Everson, R. Finite element simulation of the temperature and stress fields in single layers built without-support in selective laser melting. Materials & Design (1980-2015), (2013), 52:638–647. [2] Bangerth, W. and Hartmann, R. and Kanschat, G. deal.II – a General Purpose Object Oriented Finite Element Library. ACM Trans. Math. Softw.(2007), Vol. 33., 4:24/1–24/27. [less ▲]

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See detailModelling challenges & simulation results comparison study for inactive elements activation approach in numerical simulation of Selective Laser Melting Additive Manufacturing process
Mashhood, Muhammad UL; Peters, Bernhard UL; Wyart, Eric et al

E-print/Working paper (n.d.)

Detailed reference viewed: 45 (12 UL)