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Comparison of two different ultrasound reactors for the treatment of cellulose fibers
Luleå University of Technology, Department of Civil, Environmental and Natural Resources Engineering, Operation, Maintenance and Acoustics.ORCID iD: 0000-0002-4657-6844
Luleå University of Technology, Department of Civil, Environmental and Natural Resources Engineering, Operation, Maintenance and Acoustics.ORCID iD: 0000-0003-2955-2776
Luleå University of Technology, Department of Computer Science, Electrical and Space Engineering, Embedded Internet Systems Lab.ORCID iD: 0000-0002-2833-2555
Luleå University of Technology, Department of Civil, Environmental and Natural Resources Engineering, Operation, Maintenance and Acoustics.
2020 (English)In: Ultrasonics sonochemistry, ISSN 1350-4177, E-ISSN 1873-2828, Vol. 62, article id 104841Article in journal (Refereed) Published
Abstract [en]

The pulp and paper industry is in continuous need for energy-efficient production processes. In the refining process of mechanical pulp, fibrillation is one of the essential unit operations that count for up to 80% of the total energy use. This initial study explores the potential and development of new type of scalable ultrasound reactor for energy efficient mechanical pulping. The developed reactor is of continuous flow type and based on both hydrodynamic and acoustic cavitation in order to modify the mechanical properties of cellulose fibers. A comparison of the prototype tube reactor is made with a batch reactor type where the ultrasonic horn is inserted in the fluid. The pulp samples were sonicated by high-intensity ultrasound, using tuned sonotrodes enhancing the sound pressure and cavitation intensity by a controlled resonance in the contained fluid. The resonant frequency of the batch reactor is 20.8 kHz and for the tube reactor it is 22.8 kHz. The power conversion efficiency for the beaker setup is 25% and 36% in case of the tube reactor in stationary mode. The objective is to verify the benefit of resonance enhanced cavitation intensity when avoiding the effect of Bjerkenes forces. The setup used enables to keep the fibers in the pressure antinodes of the contained fluid. In case of the continuous flow reactor the effect of hydrodynamic cavitation is also induced. The intensity of the ultrasound in both reactors was found to be high enough to produce cavitation in the fluid suspension to enhance the fiber wall treatment. Results show that the mechanical properties of the fibers were changed by the sonification in all tests. The continuous flow type was approximately 50% more efficient than the beaker. The effect of keeping fibers in the antinode of the resonant mode shape of the irradiation frequency was also significant. The effect on fiber properties for the tested mass fraction was determined by a low-intensity ultrasound pulse-echo based measurement method, and by a standard pulp analyzer.

Place, publisher, year, edition, pages
Elsevier, 2020. Vol. 62, article id 104841
Keywords [en]
Ultrasound reactor, Hydrodynamic and acoustic cavitation, Cellulose fiber properties, Cavitation, Birch fibers
National Category
Fluid Mechanics and Acoustics Other Electrical Engineering, Electronic Engineering, Information Engineering
Research subject
Engineering Acoustics; Electronic Systems
Identifiers
URN: urn:nbn:se:ltu:diva-76606DOI: 10.1016/j.ultsonch.2019.104841ISI: 000513988100003PubMedID: 31806547Scopus ID: 2-s2.0-85076529593OAI: oai:DiVA.org:ltu-76606DiVA, id: diva2:1367645
Funder
Swedish Energy Agency, 166518
Note

Validerad;2020;Nivå 2;2020-02-26 (alebob)

Available from: 2019-11-04 Created: 2019-11-04 Last updated: 2024-06-20Bibliographically approved
In thesis
1. Process Intensification through Acoustic and Hydrodynamic Cavitation
Open this publication in new window or tab >>Process Intensification through Acoustic and Hydrodynamic Cavitation
2021 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

Process industries are cornerstones in today’s industrialized world. They contribute significantly to the development of diverse commodities and materials that are used in our daily lives. Process intensification is an approach implemented to boost manufacturing efficiency and capacities in a more sustainable and energy efficient way. The focus of this thesis is to utilize the concept and advantages of hydrodynamic and acoustic cavitation in the ultrasonic range. High-intensity cavitation can improve the physical and chemical properties of a wide range of materials and provides a sustainable alternative for process intensification. Although the use of hydrodynamic and acoustic cavitation techniques have become advantageous, applications in process industry are still limited, as the approach needs thorough refinement based on several process parameters and complications encountered in a large-scale implementation. In order to address challenges such as stability and robustness as well as energy conservation and high flow speeds, scalable reactor designs are essential for industrial applications. 

 This research focuses on the methods to develop and maximize cavitation activity in a flow-through reactor. The application comprises of hydrodynamic activation of tiny gas bubbles in the fluid to be excited and collapsed by high intensity ultrasound. The transient collapse of cavitation bubbles and clouds of bubbles generates high temperatures, extreme pressures and shockwaves in a microscale, leading to both a physical and chemical impact. To achieve an efficient energy transfer and conversion optimization with respect to physical and process related parameters are needed. The optimization of the reactor design requires both experimental and numerical investigations. Numerical simulations have been carried out with the help of a commercially accessible multiphysics simulation software that incorporates acoustics, structural dynamics, fluid dynamics and piezoelectrics. The reactor design methodology is validated by measurements of impedance and acoustic pressure as well as aluminum foil erosion and calorimetric tests. The developed cavitation reactors have been implemented in two case studies: I) Modification of cellulose fiber properties and II) Leaching of metals from mineral concentrates.

 In case study I, the developed method for fibrillation of cellulose fibers enables an energy-efficient change in mechanical properties of the fiber wall. As a consequence of cavitation, fibers are exposed to shear forces and micro-jets, inducing peeling, swelling, delamination and external and internal fibrillation. The parameters of significance are excitation frequency, electrical power, flow characteristics, concentration (viscosity), static pressure and temperature.  The maximum flow rate of the reactor is 80 l/min and power density is 0.45 W/cm3. The developed reactor has a 36 % power conversion efficiency and is well adapted for scale-up. The critical aspect is to balance the contribution of hydrodynamic and acoustic cavitation to the pulp properties. For high temperature chemi–thermomechanical pulp (HT-CTMP) from spruce, the best quality of fiber properties was obtained at 1.5 % concentration and 60° C using an electrical energy supply of 386 kWh/bdt. 

 In case study II, the aim of the investigation was to explore the impact of hydrodynamic and acoustic cavitation (HAC) on the leaching ability of tungsten. The objectives were to minimize leaching time, reduce energy usage and increase the recovery rate. Various experimental conditions such as dual-frequency excitation and various orifice geometries have been explored during this investigation. The reactor was excited by 23 kHz and 39 - 43 kHz frequencies in different flow settings. The effects of leaching time, temperature, acoustic pressure and geometry of the orifice plate have been studied. The leaching temperature varied from 40°C to 80°C. The concentration of sodium hydroxide (NaOH) leaching agent was 10 mol/L. The results has been compared to traditional chemical and laboratory autoclave leaching. The energy enhancement of 130 kWh/kg concentrates acoustic cavitation resulting in a 71.5 % leaching recovery of tungsten (WO3), relative to 36.7 % obtained in the absence of ultrasound. The developed method is found to be energy effective and provides a higher recovery rate than current chemical methods at lower temperature and static pressure.

Energy efficient process intensification requires hydrodynamic initiation of cavitation bubbles, high acoustic cavitation strength by several excitation frequencies tailored to the reactor's optimized design and optimum process pressure and temperature concerning the materials to be processed. The cavitation effect improves extensively in the flow-through mode and offers stable results. The effect of flow conditions and hydrodynamic cavitation at the same ultrasonic power input is essential and nearly doubles the yield.

Place, publisher, year, edition, pages
Luleå: Luleå University of Technology, 2021
Series
Doctoral thesis / Luleå University of Technology 1 jan 1997 → …, ISSN 1402-1544
Keywords
Ultrasonic Cavitation, Hydrodynamic Cavitation, Process Intensification, Cellulose fiber, Tungsten, Refining, Leaching
National Category
Fluid Mechanics and Acoustics
Research subject
Engineering Acoustics
Identifiers
urn:nbn:se:ltu:diva-82028 (URN)978-91-7790-736-7 (ISBN)978-91-7790-737-4 (ISBN)
Public defence
2021-06-03, F1031, Luleå, 10:00 (English)
Opponent
Supervisors
Available from: 2020-12-18 Created: 2020-12-17 Last updated: 2023-09-05Bibliographically approved

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Pamidi, Taraka Rama KrishnaJohansson, ÖrjanLöfqvist, TorbjörnShankar, Vijay

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