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150 results on '"Hultmark, Marcus"'

1. Understanding the effects of rotation on the wake of a wind turbine at high Reynolds number

Author

Pique, Alexander, Miller, Mark A., and Hultmark, Marcus

Subjects
Physics - Fluid Dynamics
Abstract

The wake of a horizontal-axis wind turbine was studied at $Re_D=4\times10^6$ with the aim of revealing the effects of the tip speed ratio, $\lambda$, on the wake. Tip speed ratios of $4<\lambda<7$ were investigated and measurements were acquired up to 6.5 diameters downstream of the turbine. Through an investigation of the turbulent statistics, it is shown that the wake recovery was accelerated due to the higher turbulence levels associated with lower tip speed ratios. The energy spectra indicate that larger broadband turbulence levels at lower tip speed ratios contributes to a more rapidly recovering wake. Wake meandering and a coherent core structure were also studied, and it is shown that these flow features are tip speed ratio invariant, when considering their Strouhal numbers. This finding contradicts some previous studies regarding the core structure, indicating that the structure was formed by a bulk rotor geometric feature, rather than by the rotating blades. Finally, the core structure was shown to persist farther into the near wake with decreasing tip speed ratio. The structure's lifetime is hypothesized to be related to its strength relative to the turbulence in the core, which decreases with increasing tip speed ratio.

Published
2024

2. Spanwise wall forcing can reduce turbulent heat transfer more than drag

Author

Rouhi, Amirreza, Hultmark, Marcus, and Smits, Alexander J.

Subjects
Physics - Fluid Dynamics
Abstract

Direct numerical simulations are performed of turbulent forced convection in a half channel flow with wall oscillating either as a spanwise plane oscillation or to generate a streamwise travelling wave. The friction Reynolds number is fixed at $Re_{\tau_0} = 590$, but the Prandtl number $Pr$ is varied from 0.71 to 20. For $Pr>1$, the heat transfer is reduced by more than the drag, 40\% compared to 30\% at $Pr=7.5$. This outcome is related to the different responses of the velocity and thermal fields to the Stokes layer. It is shown that the Stokes layer near the wall attenuates the large-scale energy of the turbulent heat-flux and the turbulent shear-stress, but amplifies their small-scale energy. At higher Prandtl numbers, the thinning of the conductive sublayer means that the energetic scales of the turbulent heat-flux move closer to the wall, where they are exposed to a stronger Stokes layer production, increasing the contribution of the small-scale energy amplification. A predictive model is derived for the Reynolds and Prandtl number dependence of the heat-transfer reduction based on the scaling of the thermal statistics. The model agrees well with the computations for Prandtl numbers up to 20.

Published
2024

3. Contact-angle hysteresis provides resistance to drainage of liquid-infused surfaces in turbulent flows

Author

Saoncella, Sofia, Suo, Si, Sundin, Johan, Parikh, Agastya, Hultmark, Marcus, van der Wijngaart, Wouter Metsola, Lundell, Fredrik, and Bagheri, Shervin

Subjects
Physics - Fluid Dynamics
Abstract

Lubricated textured surfaces immersed in liquid flows offer tremendous potential for reducing fluid drag, enhancing heat and mass transfer, and preventing fouling. According to current design rules, the lubricant must chemically match the surface to remain robustly trapped within the texture. However, achieving such chemical compatibility poses a significant challenge for large-scale flow systems, as it demands advanced surface treatments or severely limits the range of viable lubricants. In addition, chemically tuned surfaces often degrade over time in harsh environments. Here, we demonstrate that a lubricant-infused surface (LIS) can resist drainage in the presence of external shear flow without requiring chemical compatibility. Surfaces featuring longitudinal grooves can retain up to 50% of partially wetting lubricants in fully developed turbulent flows. The retention relies on contact-angle hysteresis, where triple-phase contact lines are pinned to substrate heterogeneities, creating capillary resistance that prevents lubricant depletion. We develop an analytical model to predict the maximum length of pinned lubricant droplets in microgrooves. This model, validated through a combination of experiments and numerical simulations, can be used to design chemistry-free LISs for applications where the external environment is continuously flowing. Our findings open up new possibilities for using functional surfaces to control transport processes in large systems., Comment: 20 pages, 12 figures

Published
2024

4. Acceleration is the Key to Drag Reduction in Turbulent Flow

Author

Ding, Liuyang, Sabidussi, Lena, Holloway, Brian C., Hultmark, Marcus, and Smits, Alexander J.

Subjects
Physics - Fluid Dynamics
Abstract

A turbulent pipe flow experiment was conducted where the surface of the pipe was oscillated azimuthally over a wide range of frequencies, amplitudes and Reynolds number. The drag was reduced by as much as 30\%. Past work has suggested that the drag reduction scales with the velocity amplitude of the motion, its period, or the Reynolds number. Here, we find that the key parameter is simply the acceleration, which reduces the complexity of the phenomenon by two orders of magnitude. This insight opens new potential avenues for reducing fuel consumption by large vehicles and for reducing energy costs in large piping systems., Comment: 8 pages, 5 figures

Published
2023

5. Kirigami-inspired wind steering for natural ventilation

Author

Stein-Montalvo, Lucia, Ding, Liuyang, Hultmark, Marcus, Adriaenssens, Sigrid, and Bou-Zeid, Elie

Subjects
Physics - Fluid Dynamics
Abstract

Ensuring adequate ventilation of exterior and interior urban spaces is essential for the safety and comfort of inhabitants. Here, we examine how angled features can steer wind into areas with stagnant air, promoting natural ventilation. Using Large Eddy Simulations (LES) and wind tunnel experiments with particle image velocimetry (PIV) measurements, we first examine how louvers, located at the top of a box enclosed on four sides, can improve ventilation in the presence of incoming wind. By varying louver scale, geometry, and angle, we identify a geometric regime wherein louvers capture free-stream air to create sweeping interior flow structures, increasing the Air Exchange Rate (ACH) significantly above that for an equivalent box with an open top. We then show that non-homogeneous louver orientations enhance ventilation, accommodating winds from opposing directions, and address the generalization to taller structures. Finally, we demonstrate the feasibility of replacing louvers with lattice-cut kirigami ("cut paper"), which forms angled chutes when stretched in one direction, and could provide a mechanically preferable solution for adaptive ventilation. Our findings for this idealized system may inform the design of retrofits for urban structures -- e.g. canopies above street canyons, and "streeteries" or parklets -- capable of promoting ventilation, while simultaneously providing shade., Comment: 16 pages, 11 figures. Appendix: 2 pages, 1 figure

Published
2023

6. FlowDrone: Wind Estimation and Gust Rejection on UAVs Using Fast-Response Hot-Wire Flow Sensors

Author

Simon, Nathaniel, Ren, Allen Z., Piqué, Alexander, Snyder, David, Barretto, Daphne, Hultmark, Marcus, and Majumdar, Anirudha

Subjects
Computer Science - Robotics
Abstract

Unmanned aerial vehicles (UAVs) are finding use in applications that place increasing emphasis on robustness to external disturbances including extreme wind. However, traditional multirotor UAV platforms do not directly sense wind; conventional flow sensors are too slow, insensitive, or bulky for widespread integration on UAVs. Instead, drones typically observe the effects of wind indirectly through accumulated errors in position or trajectory tracking. In this work, we integrate a novel flow sensor based on micro-electro-mechanical systems (MEMS) hot-wire technology developed in our prior work onto a multirotor UAV for wind estimation. These sensors are omnidirectional, lightweight, fast, and accurate. In order to achieve superior tracking performance in windy conditions, we train a `wind-aware' residual-based controller via reinforcement learning using simulated wind gusts and their aerodynamic effects on the drone. In extensive hardware experiments, we demonstrate the wind-aware controller outperforming two strong `wind-unaware' baseline controllers in challenging windy conditions. See: https://youtu.be/KWqkH9Z-338., Comment: Submitted to ICRA 2023. See supplementary video at https://youtu.be/KWqkH9Z-338

Published
2022

7. Fast-response hot-wire flow sensors for wind and gust estimation on UAVs

Author

Simon, Nathaniel, Piqué, Alexander, Snyder, David, Ikuma, Kyle, Majumdar, Anirudha, and Hultmark, Marcus

Subjects
Physics - Fluid Dynamics
Abstract

Due to limitations in available sensor technology, unmanned aerial vehicles (UAVs) lack an active sensing capability to measure turbulence, gusts, or other unsteady aerodynamic phenomena. Conventional in situ anemometry techniques fail to deliver in the harsh and dynamic multirotor environment due to form factor, resolution, or robustness requirements. To address this capability gap, a novel, fast-response sensor system to measure a wind vector in two dimensions is introduced and evaluated. This system, known as `MAST' (for MEMS Anemometry Sensing Tower), leverages advances in microelectromechanical (MEMS) hot-wire devices to produce a solid-state, lightweight, and robust flow sensor suitable for real-time wind estimation onboard a UAV. The MAST uses five pentagonally-arranged microscale hot-wires to determine the wind vector's direction and magnitude. The MAST's performance was evaluated in a wind tunnel at speeds up to 5~m/s and orientations of 0 - 360 degrees. A neural network sensor model was trained from the wind tunnel data to estimate the wind vector from sensor signals. The average error of the sensor is 0.14 m/s for speed and 1.6 degrees for direction. Furthermore, 95% of measurements are within 0.36 m/s error for speed and 5.0 degree error for direction. With a bandwidth of 570 Hz determined from square-wave testing, the MAST stands to greatly enhance UAV wind estimation capabilities and enable capturing relevant high-frequency phenomena in flow conditions., Comment: 23 pages, 11+2 figures, under review

Published
2022
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8. Heat transfer increase by convection in liquid-infused surfaces for laminar and turbulent flows

Author

Sundin, Johan, Ciri, Umberto, Leonardi, Stefano, Hultmark, Marcus, and Bagheri, Shervin

Subjects
Physics - Fluid Dynamics
Abstract

Liquid-infused surfaces (LIS) can reduce friction drag in both laminar and turbulent flows. However, the heat transfer properties of such multi-phase surfaces have still not been investigated to a large extent. We use numerical simulations to study conjugate heat transfer of liquid-filled grooves. It is shown that heat transfer can increase for both laminar and turbulent liquid flows due to recirculation in the surface texture. For the increase to be substantial, the thermal conductivity of the solid must be similar to the thermal conductivity of the fluids, and the recirculation in the grooves must be sufficiently strong (P\'eclet number larger than 1). The ratio of the surface cavity to the system height is an upper limit of the direct contribution from the recirculation. While this ratio can be significant for laminar flows in microchannels, it is limited for turbulent flows, where the system scale (e.g. channel height) usually is much larger than the texture height. However, heat transfer enhancement on the order of $10\%$ is observed (with a net drag reduction) in a turbulent channel flow at a friction Reynolds number $Re_\tau \approx 180$. It is shown that the turbulent convection in the bulk can be enhanced indirectly from the recirculation in the grooves., Comment: 23 pages, 14 figures

Published
2021
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9. Reynolds stress scaling in the near-wall region of wall-bounded flows

Author

Smits, Alexander J., Hultmark, Marcus, Lee, Myoungkyu, Pirozzoli, Sergio, and Wu, Xiaohua

Subjects
Physics - Fluid Dynamics
Abstract

A new scaling is derived that yields a Reynolds number independent profile for all components of the Reynolds stress in the near-wall region of wall bounded flows, including channel, pipe and boundary layer flows. The scaling demonstrates the important role played by the wall shear stress fluctuations and how the large eddies determine the Reynolds number dependence of the near-wall turbulence behavior.

Published
2021
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11. Scaling turbulence in the near-wall region

Author

Hultmark, Marcus and Smits, Alexander J.

Subjects
Physics - Fluid Dynamics
Abstract

A new velocity scale is derived that yields a Reynolds number independent profile for the streamwise turbulent fluctuations in the near-wall region of wall bounded flows for $y^+<25$. The scaling demonstrates the important role played by the wall shear stress fluctuations and how the large eddies determine the Reynolds number dependence of the near-wall turbulence distribution.

Published
2021
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14. Acceleration is the key to drag reduction in turbulent flow.

Author

Liuyang Ding, Sabidussi, Lena F., Holloway, Brian C., Hultmark, Marcus, and Smits, Alexander J.

Subjects
DRAG reduction, TURBULENCE, TURBULENT flow, PIPE flow, REYNOLDS number
Abstract

A turbulent pipe flow experiment was conducted where the surface of the pipe was oscillated azimuthally over a wide range of frequencies, amplitudes, and Reynolds numbers. The drag was reduced by as much as 35%. Past work has suggested that the drag reduction scales with the velocity amplitude of the motion, its period, and/or the Reynolds number. Here, we find that the key parameter is the acceleration, which greatly simplifies the complexity of the phenomenon. This result is shown to apply to channel flows with spanwise surface oscillation as well. This insight opens potential avenues for reducing fuel consumption by large vehicles and for reducing energy costs in large piping systems. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Measurement of local dissipation scales in turbulent pipe flow

Author

Bailey, Sean C. C., Hultmark, Marcus, Schumacher, Joerg, Yakhot, Victor, and Smits, Alexander J.

Subjects
Physics - Fluid Dynamics
Abstract

Local dissipation scales are a manifestation of the intermittent small-scale nature of turbulence. We report the first experimental evaluation of the distribution of local dissipation scales in turbulent pipe flows for a range of Reynolds numbers, 2.4x10^4<=Re_D<=7.0x10^4. Our measurements at the nearly isotropic pipe centerline and within the anisotropic logarithmic layer show excellent agreement with distributions that were previously calculated from numerical simulations of homogeneous isotropic box turbulence and with those predicted by theory. The reported results suggest a universality of the smallest-scale fluctuations around the classical Kolmogorov dissipation length., Comment: 4 pages, 4 Postscript figures, Physical Review Letters, v1: accepted version, v2: published version, v3: replaced published version with authors' tex version to avoid copyright violation

Published
2009
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32. Similarity of length scales in high-Reynolds-number wall-bounded flows.

Author

Gustenyov, Nikolay, Egerer, Margit, Hultmark, Marcus, Smits, Alexander J., and Bailey, Sean C. C.

Subjects
TURBULENT boundary layer, BOUNDARY layer (Aerodynamics)
Abstract

The wall dependence of length scales used to describe large- and small-scale structures of turbulence is examined using highly resolved experiments in zero-pressure-gradient turbulent boundary layers and pipe flows spanning the range 2000 < Reτ < 37 700. Of particular interest is the influence of external intermittency on the scaling of these length scales. It is found that when suitable scaling parameters are selected and external intermittency is accounted for, the dissipative motions follow inner scaling even into the outer-scaled regions of the flow, and that certain large-scale descriptions follow outer scaling even in the inner-scaled regions of the flow. The wall dependence is the same for both internal pipe and external boundary layer flows, and the different length scales can be related to recognizable features in the longitudinal wavenumber spectrum. [ABSTRACT FROM AUTHOR]

Published
2023
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33. A Soft Material Flow Sensor for Micro Air Vehicles

Author

Sundin, Johan, Kokmanian, Katherine, Fu, Matthew K., Bagheri, Shervin, and Hultmark, Marcus

Subjects
Wearable Electronic Devices, Silver, stretchable electronics, PDMS, Nanowires, Polymers, soft sensor, micro air vehicles, Original Articles, flow measurements
Abstract

To control and navigate micro air vehicles (MAVs) efficiently, there is a need for small, lightweight, durable, sensitive, fast, and low-power airspeed sensors. When designing sensors to meet these requirements, soft materials are promising alternatives to more traditional materials due to the large deformations they can withstand. In this article, a new concept of a soft material flow sensor is presented based on elastic filament velocimetry, which fulfills all necessary criteria. This technique measures flow velocity by relating it to the strain of a soft ribbon suspended between two static supports and subjected to a flow of interest. The ribbon is manufactured from polydimethylsiloxane and can be made piezoresistive by the addition of silver nanowires. With the described manufacturing method, the sensor can be made using common laboratory tools, outside of a clean room, significantly reducing its complexity. Furthermore, it can be operated using a simple and lightweight circuit, making it a convenient alternative for MAVs. Using a piezoresistive material allows for the flow velocity to be calibrated to the resistance change of the strained ribbon. Although certain challenges remain unsolved, such as polymer creep, the sensor has demonstrated its ability to measure flow velocities down to 4 m/s in air through experiments. A time-dependent analytical model is also provided. The model shows that the current sensor has a bandwidth of 480 Hz. Most importantly, the sensitivity and the bandwidth of the sensor can be varied strictly by modifying the geometry and the material properties of the ribbon.

Published
2021

36. Heat transfer increase by convection in liquid-infused surfaces for laminar and turbulent flows

Author

Sundin, Johan, Ciri, Umberto, Leonardi, Stefano, Hultmark, Marcus, Bagheri, Shervin, Sundin, Johan, Ciri, Umberto, Leonardi, Stefano, Hultmark, Marcus, and Bagheri, Shervin

Abstract

Liquid-infused surfaces can reduce friction drag in both laminar and turbulent flows. However, the heat transfer properties of such multi-phase surfaces have still not been investigated to a large extent. We use numerical simulations to study conjugate heat transfer of liquid-filled grooves. It is shown that heat transfer can increase for both laminar and turbulent liquid flows due to recirculation in the surface texture. Laminar flow simulations show that for the increase to be substantial, the thermal conductivity of the solid must be similar to the thermal conductivity of the fluids, and the recirculation in the grooves must be sufficiently strong (Peclet number larger than 1). The ratio of the surface cavity to the system height is an upper limit of the direct contribution from the recirculation. While this ratio can be significant for laminar flows in microchannels, it is limited for turbulent flows, where the system scale (e.g. channel height) usually is much larger than the texture height. However, heat transfer enhancement of the order of 10 % is observed (with a net drag reduction) in a turbulent channel flow at a friction Reynolds number Re-tau approximate to 180. It is shown that the turbulent convection in the bulk can be enhanced indirectly from the recirculation in the grooves., QC 20220505

Published
2022
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40. Reynolds stress scaling in the near-wall region

Author

Smits, Alexander J. and Hultmark, Marcus

Subjects
Physics::Fluid Dynamics, Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, Physics - Fluid Dynamics
Abstract

A new scaling is derived that yields a Reynolds number independent profile for all components of the Reynolds stress in the near-wall region of wall bounded flows. The scaling demonstrates the important role played by the wall shear stress fluctuations and how the large eddies determine the Reynolds number dependence of the near-wall turbulence behavior.

Published
2021

47. An atmospheric surface layer study: The Idealized horizontal Planar Array experiment for Quantifying Surface Heterogeneity (IPAQS)

Author

Morrison, Travis, primary, Calaf, Marc, additional, Pardyjak, Eric, additional, Hultmark, Marcus, additional, Higgins, Chad, additional, Iungo, Giacomo, additional, Drake, Stephan, additional, Hoch, Sebastian, additional, Zajic, Dragan, additional, Perelet, Alexei, additional, Bingham, Alex, additional, Brunner, Claudia, additional, DeBell, Thomas, additional, Gunawardena, Nipun, additional, Huang, Yi-Chun, additional, Mogollon, Gabe, additional, Najafi, Behzad, additional, Pandya, Yajat, additional, Puccioni, Matteo, additional, and Kumar Singh Sr, Dhiraj, additional

Published
2020
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50. Horizontal axis wind turbine testing at high Reynolds numbers

Author

Miller, Mark A., Kiefer, Janik, Westergaard, Carsten, Hansen, Martin Otto Laver, Hultmark, Marcus, Miller, Mark A., Kiefer, Janik, Westergaard, Carsten, Hansen, Martin Otto Laver, and Hultmark, Marcus

Abstract

Detailed studies of modern large-scale wind turbines represent a significant challenge. The immense length scales characteristic of these machines, in combination with rotational effects, render numerical simulations and conventional wind tunnel tests unfeasible. Field experiments can give us important insight into the aerodynamics and operation, but they are always accompanied by large amounts of uncertainty, due to the changing nature of the inflow and the lack of accurate control of the test conditions. Here, a series of experiments is presented, using an alternative method that enables us to represent and study much of the physics governing the large-scale wind turbines in small-scale models. A specialized, compressed-air wind tunnel is used to achieve dynamic similarity with the field-scale, but under accurately controlled conditions of the laboratory. Power and thrust coefficients are investigated as a function of the Reynolds number up to ReD=14×106, at tip speed ratios representative of those typical in the field. A strong Reynolds number dependence is observed in the power coefficient, even at very high Reynolds numbers (well exceeding those occurring in most laboratory studies). We show that for an untripped rotor, the performance reaches a Reynolds number invariant state at Rec≥3.5×106, regardless of the tip speed ratio. The same model was also tested with scaled tripping devices, with a height of only 9μm, to study the effect of transition on the rotor performance. In the tripped case, the Reynolds number dependence was eliminated for all tested cases, suggesting that the state of the boundary layer is critical for correct predictions of rotor performance.

Published
2019

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