Pumping characterisation of the maxblend impeller for Newtonian and strongly non‐Newtonian fluids

Stobiac, Vincent; Fradette, Louis; Tanguy, Philippe A.; Bertrand, François

doi:10.1002/cjce.21906

Cited by 11 publications

(10 citation statements)

References 46 publications

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“…The impeller that we studied has a similar performance to Maxblend TM , which is extensively used in industrial applications related to the mixing of highly viscous fluids. The Maxblend TM constant is in the range of 15-20 (Stobiac et al, 2014, Patel et al, 2011, Fradette et al, 2007. The Paravisc TM impeller is also used in industrial applications dealing with highly viscous fluids, and its constant is significantly higher; it is approximately 30 (Iranshahi et al, 2006).…”

Section: Power Consumptionmentioning

confidence: 99%

“…A number of studies can be found in the literature concerning these topics (see, for instance, Kazemzadeh et al, 2016, Patel et al, 2015, Stobiac et al, 2014, Pakzad et al, 2013b. These overall parameters, however, do not reveal details of the fluid dynamics and mixing patterns within the mixers, which can only be obtained with detailed flow field measurements.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Computational fluid dynamic studies of mixers for highly viscous shear thinning fluids and PIV validation

Cortada-García

Weheliye

Dore

et al. 2018

Chemical Engineering Science

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Often, impellers almost as large as the tanks containing them and impeller blades equipped with holes are adopted in industry. In this work, we studied experimentally the main features of the flow generated by this type of impellers for a mixture of glycerol with a carbomeric gel by means of particle image velocimetry. The experiments were conducted at temperatures ranging from 40 to 60°C and impeller speeds ranging from 40 to 140 rpm. In all cases, the flow regime was laminar or in the transition region. We also used computational fluid dynamics simulations to describe the behaviour of the mixer, validating the results experimentally with good agreement. We used the numerical results to obtain information on the performance of the mixer, determining the locations and size of vigorous agitation zones and the local effect of the holes present on the impeller blades. The power curves of the mixer were obtained, and the mixer efficiency in terms of power consumption was found to be similar to other impellers used to mix highly viscous non-Newtonian fluids.

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Section: Power Consumptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Computational fluid dynamic studies of mixers for highly viscous shear thinning fluids and PIV validation

Cortada-García

Weheliye

Dore

et al. 2018

Chemical Engineering Science

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“…These geometries are almost universally employed in the blending of complex fluids, as they all possess low power draw in laminar flow. Direct torque measurement has been performed to obtain power curves in laminar flow (Fradette et al, 2007;Zhang et al, 2013;Fontaine et al, 2013), whilst flow measurements have been found using both intrusive methods such as Laser Doppler Anemometry (Jahangiri, 2007) and nonintrusive methods investigating opaque systems (Patel et al, 2014;Ihejirika and Ein-Mozaffari, 2007) and transparent varieties (Stobiac et al, 2014;Chhabra et al, 2007;Shervin et al, 1991). PIV measurements have become prevalent as the method of choice for non-intrusive determination of flow fields, owing to their non-intrusive nature and ease of application.…”

Section: Figure 1: Typical Butterfly Impellermentioning

confidence: 99%

Mixing of Newtonian and viscoelastic fluids using “butterfly” impellers

Ramsay

Simmons

Ingram

et al. 2016

Chemical Engineering Science

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The mixing of high viscosity and viscoelastic fluids may be performed in industry using a "butterfly" impeller, which has received scant attention. This paper describes the characterisation of these impellers using both Newtonian and viscoelastic (Boger) fluids with an identical base viscosity under laminar flow conditions in batch tanks without baffles. Measurements are made using two rotational speeds (N = 30 or 60 rpm) over a wide range of impeller to tank diameter ratios from 0.53 to 0.98.Particle Image Velocimetry (PIV) and Planar Laser Induced Fluorescence (PLIF) have been used to determine local velocity fields, shear rates, flow numbers and mixing times respectively, with impeller power number Po obtained from torque measurements. A down-pumping flow pattern is observed, with maximum normalised velocities of 25% of the impeller tip speed observed in the axial plane, increasing to 60% in the rotational plane due to solid body rotation. Angle resolved measurements found these to be slightly increased as the impeller passes the image plane, with viscoelastic fluids displaying a greater uniformity of velocity across the image planes due to elastic energy storage. Maximum shear rates are greatest between the impeller and the wall, yet remain low i.e. O (10) s -1 . Mixing times obtained from PLIF show that mixing times in viscoelastic fluids show a slight reduction compared to the Newtonian equivalent. The impeller power number was determined as Po = 0.6 in the turbulent regime, while the laminar constant K p and the Metzner-Otto constant k s were equal to 122 and 16.0 respectively. Highlights: "Butterfly" impellers used for processing of viscoelastic fluids. Low impeller Power number Po due to low blade area. Maximum shear rates of 17 s -1 in region between impeller and wall at N = 60 rpm. Mixing times longer in viscoelastic fluids due to elastic effects.

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“…Many studies in literature have been performed on the flow in motionless mixers, employing optical methods such as planar laser‐induced fluorescence (PLIF) and particle image velocimetry (PIV) or decolorization measurement techniques , . The application of the reported methods requires both the fluid and the pipelines to be transparent; therefore, they are not implementable for opaque fluids.…”

Section: Introductionmentioning

confidence: 99%

Assessing Blending of Non‐Newtonian Fluids in Static Mixers by Planar Laser‐Induced Fluorescence and Electrical Resistance Tomography

et al. 2019

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Planar laser-induced fluorescence (PLIF) and electrical resistance tomography (ERT) were applied simultaneously to monitor the mixing performance of a KM static mixer for the blending of non-Newtonian fluids of dissimilar rheologies in the laminar regime. The areal distribution method was used to obtain quantitative information from the ERT tomograms and the PLIF images. Comparison of the ERT and PLIF results demonstrates the ability of ERT to detect the mixing performance in cases of poor mixing within the resolution of the measurement, though the accuracy decreases as the condition of perfect mixing is approached. Thus, ERT has the potential to detect poor mixing within the confines of its resolution limit and the required conductivity contrast, providing potential rapid at-line measurement for industrial practitioners.

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Pumping characterisation of the maxblend impeller for Newtonian and strongly non‐Newtonian fluids

Cited by 11 publications

References 46 publications

Computational fluid dynamic studies of mixers for highly viscous shear thinning fluids and PIV validation

Computational fluid dynamic studies of mixers for highly viscous shear thinning fluids and PIV validation

Mixing of Newtonian and viscoelastic fluids using “butterfly” impellers

Assessing Blending of Non‐Newtonian Fluids in Static Mixers by Planar Laser‐Induced Fluorescence and Electrical Resistance Tomography

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