Image Processing Algorithm for Calculating Uniformity of Carbon Surface Image Heating Element

  • Abstract
  • Keywords
  • References
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  • Abstract

    Background/Objectives: In this paper, numerical calculation method using image processing technology for percentage and uniformity of carbon fibers of planar heating element was proposed.

    Methods/Statistical analysis: The manufacturing method of the planar heating element is made by chopping the carbon fiber in small size and bonding it again via the dispersing agent. Filter the carbon fiber solution bound using a dispersant on the next nonwoven fabric. The last step is to obtain planar carbon fibers in the form of nonwoven fabrics for drying the filtered carbon fibers.

    Findings: n the planar heating element, electricity may be applied to the carbon fiber on the surface produced in this manner. Calculation of the ratio and uniformity of the planar heating element in this paper addressed four sample images (0.2 wt.%, 0.4 wt.%, 0.8 wt.%, 2.4 wt.%). In this method, the image of the planar heating element was divided into 5 × 5, converted into a binary image, and then the ratio and uniformity were numerically calculated.

    Improvements/Applications: The image analysis of the planar heating element proposed in this paper can be interpreted more accurately by combining it with the conventional method.



  • Keywords

    Carbon fiber, Image processing, Uniformity, Ratio, Planar heating element

  • References

      [1] A. Al-Ghamdi and F. E. Tantawy. (2010).Comp. Part A : Appl. Sci.Manuf. 41.

      [2] Alan, M., Solid state lighting a world of expanding opportuities at LED 2002.(2003). Ⅲ-Ⅴs Review. 16(1). 30-33.

      [3] R. Kim, H. K. Lee, S. H. Park, and H. K. Kim. (2011).Thin Solid Films. 519. 3496.

      [4] C. Sun, T. X. Lee, S. H. Ma and S. M. Huand (2006)..Precise optical modeling for LED lighting verified by crosscorrelation in the midfield region.Optical Letters. 31(14).2193-2195.

      [5] Y. Huang, W. W. Mo, and M. L. Roan. (2004). Surf. Coat. Tech., 184, 123.

      [6] K Shinke, K Ando, T Koyama, T Takai, S Nakaji, T. Ogino. (2010). Properties of various carbon nanomaterial surfaces in bilirubin adsorption. , Colloids and Surfaces B: Biointerfaces. 77(1). 18-21.

      [7] H. C. Chen, K. C. Lee and J. H. Lin. (2004). Electromagnetic and electrostatic shielding properties of co-weaving-knitting fabrics reinforced composites.Composites Part1, 35(1). 1249-1256.

      [8] Rafael C. Gonzalez, Richard E. Woods. (2009).Digital Image Processing Using MATLAB 2nd ed

      [9] Hideto Hashiguchi and HiasshiKimugasa.(1994). Electrical Resistivity of α-SiC Ceramics Added with NiO. J. Ceram. Soc. Japan, 102(2). 160-164.

      [10] Mylene Brach, DilettaSciti, Andrea Balbo and AlidaBellosi,(2005). Short-Term Oxidation of a Ternary Composite in the System AlN-SiC-ZrB2. Journal of the European Ceramic Society, 25.1771-1780.

      [11] Yuping, D., Shunhua, L. and Hongtao. G. (2005). Investigation of electrical conductivity and electromagnetic Shielding Effectiveness of polyaniline composites. Science and Technoly of Advanced Material, 1(1). 1-6.

      [12] Diletta. Sciti, Cesare. Melandri and AlidaBellosi. (2004). Properties of ZrB2-Reinforced Tenary Composites. Adanced Engineering Materials, 6(9). 775-781.




Article ID: 19378
DOI: 10.14419/ijet.v7i3.34.19378

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