Development of a general method for obtaining the geometry of microfluidic networks

Razavi, Mohammad; Shirani, Ebrahim; Salimpour, Mohammad Reza

doi:10.1063/1.4861067

Cited by 10 publications

(6 citation statements)

References 30 publications

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“…(18), (19), (23), (29) and (30), and writing that for a channel between parallel plates the friction factor is f ¼ 24=Re D h . The inequality (50) becomes…”

Section: Discussionmentioning

confidence: 99%

“…(21) and (23). The validity domain of the simplifying assumptions, X ) a, and H ) c, will be discussed at the end of Section 5.…”

Section: à2mentioning

confidence: 99%

“…Advances are published regularly for heat exchangers [4][5][6][7][8][9][10][11][12][13], fuel cells [14], fluid networks [15][16][17][18][19][20], steam generators [21,22], fluid channels [23][24][25][26][27], energy storage [28], transportation [29][30][31][32], power generation [33][34][35][36][37], and management [38].…”

Section: Technology Evolutionmentioning

confidence: 99%

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Entrance-length dendritic plate heat exchangers

Bejan

Alalaimi

Sabau

et al. 2017

International Journal of Heat and Mass Transfer

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a b s t r a c tHere we explore the idea that the highest heat transfer rate between two fluids in a given volume is achieved when plate channel lengths are given by the thermal entrance length, i.e., when the thermal boundary layers meet at the exit of each channel. The overall design can be thought of an elemental construct of a dendritic heat exchanger, which consists of two tree-shaped streams arranged in cross flow. Every channel is as long as the thermal entrance length of the developing flow that resides in that channel. The results indicate that the overall design will change with the total volume and total number of channels. We found that the lengths of the surfaces swept in cross flow would have to decrease sizably as number of channels increases, while exhibiting mild decreases as total volume increases. The aspect ratio of each surface swept by fluid in cross flow should be approximately square, independent of total number of channels and volume. We also found that the minimum pumping power decreases sensibly as the total number of channels and the volume increase. The maximized heat transfer rate per unit volume increases sharply as the total volume decreases, in agreement with the natural evolution toward miniaturization in technology.

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“…(18), (19), (23), (29) and (30), and writing that for a channel between parallel plates the friction factor is f ¼ 24=Re D h . The inequality (50) becomes…”

Section: Discussionmentioning

confidence: 99%

“…(21) and (23). The validity domain of the simplifying assumptions, X ) a, and H ) c, will be discussed at the end of Section 5.…”

Section: à2mentioning

confidence: 99%

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Entrance-length dendritic plate heat exchangers

Bejan

Alalaimi

Sabau

et al. 2017

International Journal of Heat and Mass Transfer

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“…1,2 The development of devices utilizing fluid flow and pressure in circuits akin to electronic devices is the focus of this area of engineering and technology. 3,4 Through the interplay of fluid (liquid or gas) streams, this technology enables sensing, processing, and regulating capabilities using fluid power. As a result, fluidics can carry out these tasks without using any mechanical moving parts.…”

Section: Introductionmentioning

confidence: 99%

Minireview on Fluid Manipulation Techniques for the Synthesis and Energy Applications of Two-Dimensional MXenes: Advances, Challenges, and Perspectives

Richard

Thomas²,

et al. 2023

Energy Fuels

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A new frontier in the design and applications of useful micro- and nanomaterials was unlocked by the combination of fluid mechanics with modern engineered technologies. Fluidic methods allow for the exact and active spatiotemporal manipulation of matter, which has enormous potential for the fabrication of advanced nanoplatforms with flexible material characteristics. Fluidic technologies bestow some advantages over conventional experimental methods, such as quick sample processing and precise fluid control during assays. When combined with different two-dimensional (2D) materials, these fluidic techniques opened up a new era in the area of material science and engineering. MXenes, the youngest family of layered 2D materials, have attracted great scientific attention as a result of their peculiar properties and are used for a multitude of applications. This review discusses the magnificent relationship between MXenes and fluid manipulation technique nanofluidics in the domain of energy research. This article proclaims a concise review of the synthesis, energy applications, challenges, and future outlook of MXenes in fluidic research. An emphasis is given to the applications of MXene-based fluidic techniques in the field of energy harvesting and storage. This analysis will provide anew insight into MXenes in the field of fluid manipulation techniques that followed custom approaches in the past and researchers to move toward a new direction in the future. This examinative article will fill a major gap in fluidic research in the world of materials. And to the best part of our perception, this is the first review that offers an overview of the combination of fluidics and MXenes for application, particularly in energy harvesting and storage devices.

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“…Razavi et al investigated the geometry of microfluidic networks numerically. 14,15 The model used constructal theory to optimize the performance of the network for different design parameters including cross-sectional areas, length of microfluidic channels, and shapes of the cross-section. The results from their model were in good agreement with Murray's law.…”

Section: Introductionmentioning

confidence: 99%

Numerical design and optimization of hydraulic resistance and wall shear stress inside pressure-driven microfluidic networks

Damiri

Bardaweel

2015

Lab Chip

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Microfluidic networks represent the milestone of microfluidic devices. Recent advancements in microfluidic technologies mandate complex designs where both hydraulic resistance and pressure drop across the microfluidic network are minimized, while wall shear stress is precisely mapped throughout the network. In this work, a combination of theoretical and modeling techniques is used to construct a microfluidic network that operates under minimum hydraulic resistance and minimum pressure drop while constraining wall shear stress throughout the network. The results show that in order to minimize the hydraulic resistance and pressure drop throughout the network while maintaining constant wall shear stress throughout the network, geometric and shape conditions related to the compactness and aspect ratio of the parent and daughter branches must be followed. Also, results suggest that while a "local" minimum hydraulic resistance can be achieved for a geometry with an arbitrary aspect ratio, a "global" minimum hydraulic resistance occurs only when the aspect ratio of that geometry is set to unity. Thus, it is concluded that square and equilateral triangular cross-sectional area microfluidic networks have the least resistance compared to all rectangular and isosceles triangular cross-sectional microfluidic networks, respectively. Precise control over wall shear stress through the bifurcations of the microfluidic network is demonstrated in this work. Three multi-generation microfluidic network designs are considered. In these three designs, wall shear stress in the microfluidic network is successfully kept constant, increased in the daughter-branch direction, or decreased in the daughter-branch direction, respectively. For the multi-generation microfluidic network with constant wall shear stress, the design guidelines presented in this work result in identical profiles of wall shear stresses not only within a single generation but also through all the generations of the microfluidic network under investigation. The results obtained in this work are consistent with previously reported data and suitable for a wide range of lab-on-chip applications.

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Development of a general method for obtaining the geometry of microfluidic networks

Cited by 10 publications

References 30 publications

Entrance-length dendritic plate heat exchangers

Entrance-length dendritic plate heat exchangers

Minireview on Fluid Manipulation Techniques for the Synthesis and Energy Applications of Two-Dimensional MXenes: Advances, Challenges, and Perspectives

Numerical design and optimization of hydraulic resistance and wall shear stress inside pressure-driven microfluidic networks

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