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SGD Orthodontic: Material

SGD Orthodontic: Material. Hamzi , Zulkhairi , Azizul , Haziq , Aishah , Anis, Asmat , Masyitah. Lecture outline: material. Wire fracture Mechanics of spring Bauchinger effect How does the material affect stability and the stiffness of the component?. Wire fracture.

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SGD Orthodontic: Material

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  1. SGD Orthodontic: Material Hamzi, Zulkhairi, Azizul, Haziq, Aishah, Anis, Asmat, Masyitah

  2. Lecture outline: material • Wire fracture • Mechanics of spring • Bauchinger effect • How does the material affect stability and the stiffness of the component?

  3. Wire fracture

  4. Small loads → the stress is below the elastic limit of the material, reversible elastic strain occurs that disappears completely when specimen is unloaded. • High stress • A ductile material begins to undergo irreversible plastic or permanent deformation • A brittle material will fracture without any significant permanent deformation

  5. Stainless steel wire • Orthodontic wire are generally shaped by bending and the wire should possess sufficient ductility to resist fracture during this bending procedure. • The amount of residual ductility remaining in a wire depends in part on the ductility used up in its manufacture.

  6. Mechanics of spring

  7. Mechanics of spring Force= (deflection)(radius4) @ F=dr4/l3 length3 • Force: • Single rooted: 25-40g • Excess force: delay movement, overload anchorage & discomfort. • Deflection: • Common spring activation: 3mm • Greater activation -> pt insert it incorrectly -> unwanted movement • Smaller activation -> force applied decrease -> wanted tooth movement (1-2mm/month)

  8. BAUSCHINGER EFFECT

  9. Named after German Engineer, Johann Bauschinger. • Applies to very small deformations.

  10. May be stated as follows “By applying a tensile or compressive load beyond the elastic limit, the elastic limit for compression or for tension, respectively, is reduced considerably, and the more the load exceeds the elastic limit, the greater the reduction”

  11. Tensile stress In this graph, lets treat tensile stress and strain as POSITIVE and compressive stress and strain as NEGATIVE 0 Compressive strain Tensile strain Compressive stress

  12. If an annealed specimen is loaded from 0 to B beyond its elastic limit, Tensile stress B A designated by point A, and unloaded, SeT Its condition is represent by C. Note that the elastic limit of the material in tensile is given by SeT 0 C Compressive strain Tensile strain Compressive stress

  13. If the same specimen is next loaded in compression, it follows the path CDE, Tensile stress B A where D is the elastic limit point on the compression curve, so that the elastic limit in compression is now S’eC SeT According to Bauschinger effect, S’eC < SeT 0 C Compressive strain Tensile strain S’eC D E Compressive stress

  14. If an annealed specimen instead of being loaded in tension and then in compression, as stated above, was directly loaded in compression, Tensile stress B A The elastic limit in compression of the annealed material should be SeC , SeC SeT And would be equal to magnitude to SeT . 0 C Compressive strain Tensile strain S’eC D Hence, SeC = SeT , and S’eC < SeT and S’eC < SeC E F Compressive stress

  15. Similar reasoning will happen if the annealed specimen was initially loaded in compression past the elastic limit, unloaded and loaded next in tension. • The resulting elastic limit in tension would be smaller than the elastic limit of annealed material in compression

  16. Whereas Bauschinger effect was originally stated in terms of the elastic limit, the discussion of this effect in the literature has involve the use of terms elastic limit and yield strength interchangeably. • The reason for this anomaly lies in the elastic limit and the yield point being located very close to each other on the stress-strain curve.

  17. The important thing is that one should not lose sight of the fact that Bauschinger effect applies to VERY small strains only.

  18. How does the material affect stability and the stiffness of the component?

  19. How does the material affect stability and the stiffness of the component? • The stability ratio of a spring in mechanical terms : Stiffness in the direction of unwanted displacement Stiffness in the intended direction of tooth movement • The spring must be guided so that its action is exerted only in the appropriate direction by: • Place the spring in an undercut of the tooth so that it does not slip occlusally during activation • Use a guide to hold the spring in its position during activation • Bond an attachment to the tooth surface to engage the spring

  20. In Practice • High stability spring eg. Finger spring • Straightforward to adjust/movement • Low stability spring eg. Buccal canine retractor • Difficult to position precisely on the tooth to be moved • The spring should be adjusted so that the point of application will give the desired direction of tooth movement.

  21. Self supported spring • These springs are made up of thicker wire to avoid distortion by the patient • Supported spring • These springs are made up of thinner wire , a guidewire maybe provided. Alternatively, they maybe supported by an additional sleeve or ‘boxed’ of acrylic – to ensure adequate stability

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