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Electrospinning Technique by Assistant Professor Dr. Akram R. Jabur Dept. of Materials Eng.

Electrospinning Technique by Assistant Professor Dr. Akram R. Jabur Dept. of Materials Eng. University of Technology. Electrospinning.  Uses an electrical charge to draw very fine   fibres  from a liquid. This method ensures that no solvent can be carried over into the final product.

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Electrospinning Technique by Assistant Professor Dr. Akram R. Jabur Dept. of Materials Eng.

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  1. Electrospinning Technique by Assistant Professor Dr. Akram R. Jabur Dept. of Materials Eng. University of Technology

  2. Electrospinning •  Uses an electrical charge to draw very fine  fibres from a liquid. • This method ensures that no solvent can be carried over into the final product. • Ability to produce novel synthetic fibers of small diameter and good mechanical properties.

  3. Advantages • Inexpensive and simple • method • Capable of producing • nanofibers • positive terminal • negative terminal

  4. Taylor Cone • refers to the cone observed in electrospinning, electrospraying and hydrodynamic spray processes from which a jet of charged particles emanates above a threshold voltage • was described by Sir Geoffrey Ingram Taylor in 1964 before electrospray was "discovered“ • to form a perfect cone required a semi-vertical angle of 49.3° (a whole angle of 98.6°) , the shape of such a cone approached the theoretical shape just before jet formation – Taylor Angle

  5. Taylor Cone • When a sufficiently high voltage is applied to a liquid droplet, the body of the liquid becomes charged, and electrostatic repulsion counteracts the surface tension and droplet is stretched, at a critical point a stream of liquid erupts from the surface. This point of eruption is known as the Taylor cone

  6. ELECTROSPINNING The distribution of charge in the fiber changes as the fiber dries out during flight

  7. ning Technique

  8. Advantages • Able to make very thin fibers easily, since the viscosity of many polymer solutions is very low.  • The lower viscosity of sample makes an elongational deformation easily.

  9. Disadvantages • The instability of elongational deformation increases with growing deformation of low viscosity polymer solutions.  • Beads are more easily formed as the fiber diameter decreases. Beads formation decreases the surface area of fabrics

  10. Process • Electrospinning: • A high voltage is passed through a polymer solution inducing an electrostatic repulsion force • The polymer is pumped through an insulin syringe, the repulsion force results in the formation of a thin jet • This jet is directed toward a grounded collection plate, the solvent evaporates before hitting the collection plate and results in the formation of a polymer scaffold

  11. Fiber dimension and morphology • The diameter of a fiber produced by electrospinning primarily depends on the spinning parameters. • An increase in solution concentration results in fibers with larger diameters.

  12. Parameters • With increasing concentration of the fiber content, increase in mechanical properties. But further increasing it, mechanical properties drops. • With increasing electric potential the fiber diameter decreases, and the fiber diameter distribution becomes increasing broader.

  13. Parameters • 1. Molecular Weight of the polymer2. Solution properties (viscosity, conductivity and surface tension)3. Electric potential, flow rate and concentration4. Distance between the capillary and collection screen5. Ambient parameters (temperature, humidity and air velocity in the chamber)6. Motion of target screen (collector)

  14. 2 main Properties of fibers produced • A very high surface to volume ratio • Defect free structure at the molecular level

  15. Single Box Ratio 6 m2 1 m3 = 6 m2/m3 Smaller Boxes Ratio 12 m2 1m3 = 12 m2/m3 Model of Surface-to-Volume Comparisons… • Neglecting spaces between the smaller boxes, the volumes of the box on the left and the boxes on the right are the same but the surface area of the smaller boxes added together is much greater than the single box.

  16. Nanofiber Structures Interconnected structure (Source: Ramakrishna, S., et.al, 2005)

  17. Filtration Polymeric nanofibers have significant applications in the area of filtration since their surface area is substantially greater and have smaller micropores than any other fibers like spun bond and melt blown (MB) webs.

  18. Potential Applications Tissue engineering scaffolds - Adjustable biodegradation rate - Better cell attachment - Controllable cell directional growth Wound dressing - Prevents scar - Bacterial shielding Medical prostheses - Lower stress concentration - Higher fracture strength Haemostatic devices - Higher efficiency in fluid absorption Drug delivery - Increased dissolution rate - Drug-nanofiber interlace Polymer Nanofiber Sensor devices - Higher sensitivity - For cells, arteries and veins Cosmetics - Higher utilization - Higher transfer rate Filter media - Higher filter efficiency Electrical conductors - Ultra small devices • Protective clothing • Breathable fabric that blocks chemicals • Optical applications • Liquid crystal optical shutters Material reinforcement - Higher fracture toughness - Higher delamination resistance

  19. NANOFIBERS Comparison of red blood cell with nanofibers web [1].

  20. NANOFIBERS   Entrapped pollen spore on nanofiber web [1].

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