Study on double-shaft mixing paddle undergoing planetary motion in the laminar flow mixing system

Zhang, Jiaqi; Li, Xiwen; He, Ruibo; Jiang, Liang

doi:10.1177/1687814015592603

Cited by 7 publications

(10 citation statements)

References 25 publications

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“…Similarly, [41] studied "the impact of double shaft mixing paddle undergoing planetary motion on laminar flow mixing system using flow field visualization experiments and computational fluid dynamics simulation. Digital image processing was conducted to analyze the mixing efficiency of mixing paddle in co-rotating and counter rotating modes.…”

Section: Type I -Mixer With Onementioning

confidence: 99%

Development of Operating Model for the Design of Stirrer Arms of Slurries: A Review

Okpighe

Shadrack

Nwosu

2022

CJAST

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An in dept review of the Development of Operating Model for the Design of Stirrer Arms of Slurries is reported. The works of several authors were reviewed. These works covered research on the importance of slurries, application of different slurries in the area of Agriculture and agricultural farming, construction and allied industries, foods and pharmaceutical industries, chemical and paints industries. Also considered were the research works on the design, fabrication and test investigation of performance of different stirrer arms. From the review, three key outcomes from three set of researchers were identified thus: Researcher team 1: the TTP propeller was the most efficient in liquid phase mixing; Researcher team 2: the TEET geometry contributed the best quality of the mixing and significantly reduced the cost of the mixing process; Researcher team 3: the two Z blade stirrer arm was considered as the best in terms of mixing effectiveness. These three outcomes appear as standalone and do not give the user(s) information on comparative advantages for deployment of stirrer arms. Consequent on the above, further theoretical and empirical research will need to be done to evaluate the Order of Merit of these stirrer arms to be called to bar.

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Section: Type I -Mixer With Onementioning

confidence: 99%

Development of Operating Model for the Design of Stirrer Arms of Slurries: A Review

Okpighe

Shadrack

Nwosu

2022

CJAST

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“…Therefore, researchers still continue to redesign the stirrer blade in order to obtain efficient systems in terms of energy, mixing time, and product quality. [1][2][3][4] Recently, many researchers focus on the performance of impellers with curved blades, and some works have been achieved using this type of impellers to study the flow pattern generated with rheological complex fluids. [5][6][7][8][9][10][11][12][13] Other researchers interested to Newtonian fluids with curved blade impellers in single or dual arrangements.…”

Section: Introductionmentioning

confidence: 99%

Energy efficiency of a deep hollow bladed impeller for mixing viscoplastic fluids in a cylindrical vessel

Ameur

Sahel

Kamla

2017

Advances in Mechanical Engineering

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The energy efficiency of a deep hollow blade disk turbine in unbaffled mixing vessel is determined in this article via numerical simulations. The vessel is filled with xanthan gum solutions, which have a shear thinning behavior with yield stress (viscoplastic). The Herschel-Bulkley law is used to model the fluid behavior. Three-dimensional calculations are achieved by the computer tool CFX (version 16.0), and the computational domain is meshed using the software ICEM CFD (version 16.0). Mixing is achieved at low impeller rotational speeds which correspond to the laminar and transitional flow regimes. Our main purpose is to explore the effect of blade size (width and height), Reynolds number, and fluid properties on the mixing efficiency of deep hollow bladed impellers. A validation test of our predicted results with experimental data of a previous study was done, and it has shown a good agreement.

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“…Yi, P. X. et al 1 via CFD method concluded that the geometric parameter, for example the clearance, plays a great role on the dispersive mixing efficiency, and the reasonable design of clearance can improve the mixing efficiency of the mixer. Zhang, J. Q. et al 2 obtained that inside the mixing vessel of the twin-blade planetary mixer, the alternative variation of the axial velocity, the tangential velocity and the radial velocity promote the convecting mixing of different compositions. Devals, C. et al 3 and Fradette, L. et al 4 found that decreasing the clearance increasing the shear rate and the power consumption, however, decreasing the bottom recirculation of the fluid flow.…”

Section: Introductionmentioning

confidence: 99%

Numerical analysis in the effects of blade’s arrangement on the torque load characteristics of the three-blade planetary mixer

Jiang¹,

He²,

Zhan³

et al. 2017

AIP Conference Proceedings

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Abstract. The three-blade planetary mixer is one of the important solid propellant mixing equipment, the layout of blades will affect the blades' torque load and the power consumption. In this paper, the effects of the eccentric distance (Es=0~16 mm), the solid blade form (two paddles, and four paddlers), and the blade arrangement (linear arrangement, triangle arrangement) on the blades' torque load are investigated during the mixer stirring the solid propellant process.

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Study on double-shaft mixing paddle undergoing planetary motion in the laminar flow mixing system

Cited by 7 publications

References 25 publications

Development of Operating Model for the Design of Stirrer Arms of Slurries: A Review

Development of Operating Model for the Design of Stirrer Arms of Slurries: A Review

Energy efficiency of a deep hollow bladed impeller for mixing viscoplastic fluids in a cylindrical vessel

Numerical analysis in the effects of blade’s arrangement on the torque load characteristics of the three-blade planetary mixer

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