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Technical presentation on shot peening
- 1. Technical Presentation on Shot Peening
- 2. Contents 1. Introduction 2. Why & Where shot peening used ? 3. How shot peening works ? 4. Introduction to the Machine. 5. Controlling the Process. 6. Steel shots specification. 7. Factors affecting shot peening. 8. Benefits of shot peening.
- 3. Introduction Shot peening is a cold working process in which the surface of a part is bombarded with small spherical media called shot. Each piece of shot striking the metal acts as a tiny peening hammer, imparting a small indentation or dimple on the surface. Below the surface, the compressed grains try to restore the surface to its original shape, producing a hemisphere of cold-worked metal highly stressed in compression . Overlapping Dimples develop a uniform layer of residual compressive stress.
- 4. Why shot peening ?? The atoms on the surface of manufactured metal will be mostly under tensile stresses left over from grinding, welds, heat treatments & machining. Cracks propagate easily in areas of tensile stress because the tensile stresses are already working to pull the atoms of the metal apart. By shot peening the material you introduce a layer of compressive stress by compacting the material. As the shot peening is performed, the atoms on the surface of the metal become crowded and try to restore the metal's original shape by pushing outward.
- 5. Where shot peening used ? Shot peening is used on gear parts, cams and camshafts, clutch springs, coil springs, connecting rods, crankshafts, gearwheels, leaf and suspension springs, rock drills, and turbine blade.
- 6. How shot peening works ? The shot peening process impacts the metal surface with small pellets (round metallic, glass or ceramic particles) with a high enough force to deform the surface plastically. A compressive layer is generated when the impact of all the particle shots produce small indentations in the top surface layer. The layer beneath the top surface is then compressed, generating a compressively stressed layer underneath the shot peened area. This layer helps to prevent the stressed area to crack as a crack cannot propagate in a compressive environment. Compressed Material Multiple Shots Compressed layer Multiple shots Shots
- 7. Controlling the process 1. Fluorescent test (Coverage test) The job is painted with fluorescent paint and shot peened with same parameters that we do with Almen strip test and if the paint is completely washed away then the parameters are said to be ok. This inspection of test is done using magnifying lens to check the coverage of the peening. Before After
- 8. Size & material of the spherical shot is important, as its velocity ,rate and angle at which the blast pattern sweeps across the surface. The relative work done to the surface is called the ‘Peening intensity’. If a flat strip of metal is shot peened on one side only it will slightly curl away from the side which has be treated and produce a convex surface. If a standard strip is used, the degree of curvature is a measure of the peening intensity. 2.Almen strip test (Intensity test) Types of almen strips It is made from spring steel of carefully controlled quality to a size within close tolerances. It is used in three thickness called C, A and N. The C strip is thickest and N strip the thinnest. The curvature or are height, of the strip is measured with the aid of a dial gauge Fig.1 after the strip is placed and retained magnetically against two pairs of ball contacts a fixed distance apart. The gauge is zeroed with the unpeened strip in position.
- 9. After peening the strip is replaced against the contacts with the unpeened side towards the dial gauge stem and the Almen are height is read directly in thousandsth of an inch or millimeters. When peening intensity is measured it is important to subject one side of the Almen strip to exactly the same blast conditions as the object to be peened. 1 Thou = 0.0254 mm = 25.4 microns
- 11. Factors affecting shot peening 1. Peening exposure time 2. Shot Size & Type 3. Impact angle 4. Shot velocity 5. Distance between nozzle & surface
- 12. Saturation Curve The saturation curve is generated by exposing the Almen strip to the shot stream for varying amounts of time. When arc height is plotted against time. The (first) point on the curve for which doubling the peening time increases the arc height by 10%. 1.Peening exposure time
- 13. 2.Shot Size & Type The physical and mechanical properties of the shot determine the quality of the impact on the surface. If the shot is softer than the surface it is intended to compress, then the shot will be deformed and the full intended peening effect will not be achieved. The method is careful to prevent shot fracture in the conditioning stage. Other factors, such as roundness, broken or fractured particles and miscellaneous contamination. The depth of deformed layer decreases with increasing hardness of the material treated. Peening intensity increases as the shot size increased.
- 14. 3.Impact angle The angle of impact of the shot with the target should be as close to normal (i.e 90 ) , with attention paid to effect of rebounding shot interfering with the impinging shot . Below 45° is considered to be detrimental practice for surface treatment for two reasons. First, the energy imparted is less than optimum and will not impart a deep compressive layer. The velocity of the shot as it impacts the surface is largely determined by three factors: nozzle size, air pressure and distance to the work-piece. 4.Shot Velocity
- 15. Effect of Peening on cycles of failure. • These compressive stresses improved the surface fatigue life, of the gears by 1.6 times compared to those that were not shot peened.