Understanding and optimizing the SMX static mixer

M.K. Singh; P.D. Anderson; H.E.H. Meijer

doi:10.1002/marc.200800710

Understanding and optimizing the SMX static mixer

M.K. Singh, P.D. Anderson, H.E.H. Meijer

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Using the Mapping Method different designs of SMX motionless mixers are analyzed and optimized. The three design parameters that constitute a specific SMX design are: The number of cross-bars over the width of channel, Nx, the number of parallel cross-bars per element, Np, and the angle between opposite cross-bars . Optimizing Nx, somewhat surprisingly reveals that in the standard design with Np = 3, Nx = 6 is the optimum using both energy efficiency as well as compactness as criteria. Increasing Nx results in under-stretching and decreasing Nx leads to over-stretching of the interface. Increasing Np makes interfacial stretching more effective by co-operating vortices. Comparing realized to optimal stretching, we find the optimum series for all possible SMX(n) designs to obey the universal design rule Np = (2/3) Nx-1, for Nx = 3, 6, 9, 12, .

Original language	English
Pages (from-to)	362-376
Journal	Macromolecular Rapid Communications
Volume	30
Issue number	4-5
DOIs	https://doi.org/10.1002/marc.200800710
Publication status	Published - 2009

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title = "Understanding and optimizing the SMX static mixer",

abstract = "Using the Mapping Method different designs of SMX motionless mixers are analyzed and optimized. The three design parameters that constitute a specific SMX design are: The number of cross-bars over the width of channel, Nx, the number of parallel cross-bars per element, Np, and the angle between opposite cross-bars . Optimizing Nx, somewhat surprisingly reveals that in the standard design with Np = 3, Nx = 6 is the optimum using both energy efficiency as well as compactness as criteria. Increasing Nx results in under-stretching and decreasing Nx leads to over-stretching of the interface. Increasing Np makes interfacial stretching more effective by co-operating vortices. Comparing realized to optimal stretching, we find the optimum series for all possible SMX(n) designs to obey the universal design rule Np = (2/3) Nx-1, for Nx = 3, 6, 9, 12, .",

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T1 - Understanding and optimizing the SMX static mixer

AU - Singh, M.K.

AU - Anderson, P.D.

AU - Meijer, H.E.H.

PY - 2009

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N2 - Using the Mapping Method different designs of SMX motionless mixers are analyzed and optimized. The three design parameters that constitute a specific SMX design are: The number of cross-bars over the width of channel, Nx, the number of parallel cross-bars per element, Np, and the angle between opposite cross-bars . Optimizing Nx, somewhat surprisingly reveals that in the standard design with Np = 3, Nx = 6 is the optimum using both energy efficiency as well as compactness as criteria. Increasing Nx results in under-stretching and decreasing Nx leads to over-stretching of the interface. Increasing Np makes interfacial stretching more effective by co-operating vortices. Comparing realized to optimal stretching, we find the optimum series for all possible SMX(n) designs to obey the universal design rule Np = (2/3) Nx-1, for Nx = 3, 6, 9, 12, .

AB - Using the Mapping Method different designs of SMX motionless mixers are analyzed and optimized. The three design parameters that constitute a specific SMX design are: The number of cross-bars over the width of channel, Nx, the number of parallel cross-bars per element, Np, and the angle between opposite cross-bars . Optimizing Nx, somewhat surprisingly reveals that in the standard design with Np = 3, Nx = 6 is the optimum using both energy efficiency as well as compactness as criteria. Increasing Nx results in under-stretching and decreasing Nx leads to over-stretching of the interface. Increasing Np makes interfacial stretching more effective by co-operating vortices. Comparing realized to optimal stretching, we find the optimum series for all possible SMX(n) designs to obey the universal design rule Np = (2/3) Nx-1, for Nx = 3, 6, 9, 12, .

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DO - 10.1002/marc.200800710

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SP - 362

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JO - Macromolecular Rapid Communications

JF - Macromolecular Rapid Communications

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Understanding and optimizing the SMX static mixer

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