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Standard Test Method for Residual Stress Measurement by X-Ray Diffraction for Bearing Steels
Automatische name übersetzung:
Standard Test Method for Eigenspannungsmessung durch Röntgenbeugung für Lagerstähle
NORM herausgegeben am 1.4.2012
Bezeichnung normen: ASTM E2860-12
Anmerkung: UNGÜLTIG
Ausgabedatum normen: 1.4.2012
SKU: NS-46164
Zahl der Seiten: 18
Gewicht ca.: 54 g (0.12 Pfund)
Land: Amerikanische technische Norm
Kategorie: Technische Normen ASTM
Keywords:
bearing, residual stress, X-ray diffraction, XRD, ICS Number Code 77.040.20 (Non-destructive testing of metals)
Significance and Use | ||||||||
This test method covers a procedure for experimentally determining macroscopic residual stress tensor components of quasi-isotropic bearing steel materials by XRD. Here the stress components are represented by the tensor σij as shown in Eq 1 (1, p. 40). The stress strain relationship in any direction of a component is defined by Eq 2 with respect to the azimuth phi(ϕ) and polar angle psi(ψ) defined in Fig. 1 (1, p. 132). Alternatively, Eq 2 may also be shown in the following arrangement (2, p. 126): Using XRD and Bragg’s law, interplanar strain measurements are performed for multiple orientations. The orientations are selected based on a modified version of Eq 2, which is dictated by the mode used. Conflicting nomenclature may be found in literature with regard to mode names. For example, what may be referred to as a ψ (psi) diffractometer in Europe may be called a χ (chi) diffractometer in North America. The three modes considered here will be referred to as omega, chi, and modified-chi as described in 9.5. Omega Mode (Iso Inclination) and Chi Mode (Side Inclination)—Interplanar strain measurements are performed at multiple ψ angles along one ϕ azimuth (let ϕ = 0°) (Figs. 2 and 3), reducing Eq 2 to Eq 3. Stress normal to the surface (σ33) is assumed to be insignificant because of the shallow depth of penetration of X-rays at the free surface, reducing Eq 3 to Eq 4. Post-measurement corrections may be applied to account for possible σ33 influences (12.12). Since the σij values will remain constant for a given azimuth, the s1{hkl} term is renamed C. The measured interplanar spacing values are converted to strain using Eq 24, Eq 25, or Eq 26. Eq 4 is used to fit the strain versus sin2ψ data yielding the values σ11, τ13, and C. The measurement can then be repeated for multiple phi angles (for example 0, 45, and 90°) to determine the full stress/strain tensor. The value, σ11, will influence the overall slope of the data, while τ13 is related to the direction and degree of elliptical opening. Fig. 4 shows a simulated d versus sin2ψ profile for the tensor shown. Here the positive 20-MPa τ13 stress results in an elliptical opening in which the positive psi range opens upward and the negative psi range opens downward. A higher τ13 value will cause a larger elliptical opening. A negative 20-MPa τ13 stress would result in the same elliptical opening only the direction would be reversed with the positive psi range opening downwards and the negative psi range opening upwards as shown in Fig. 5. Modified Chi Mode—Interplanar strain measurements are performed at multiple β angles with a fixed χ offset, χm (Fig. 6). Measurements at various β angles do not provide a constant ϕ angle (Fig. 7), therefore, Eq 2 cannot be simplified in the same manner as for omega and chi mode. Eq 2 shall be rewritten in terms of β and χm. Eq 5 and 6 are obtained from the solution for a right-angled spherical triangle (3). Substituting ϕ and ψ in Eq 2 with Eq 5 and 6 (see X1.1), we get: Stress normal to the surface (σ33) is assumed to be insignificant because of the shallow depth of penetration of X-rays at the free surface reducing Eq 7 to Eq 8. Post-measurement corrections may be applied to account for possible σ33 influences (see 12.12). Since the σij values and χm will remain constant for a given azimuth, the s1{hkl} term is renamed C, and the σ22 term is renamed D. The σ11 influence on the d versus sin2β plot is similar to omega and chi mode (Fig. 8) with the exception that the slope shall be divided by cos2χm. This increases the effective ½s2{hkl} by a factor of 1/cos2χm for σ11. The τij influences on the d versus sin2β plot are more complex and are often assumed to be zero (3). However, this may not be true and significant errors in the calculated stress may result. Figs. 9-13 show the d versus sin2β influences of individual shear components for modified chi mode considering two detector positions (χm = +12° and χm = -12°). Components τ12 and τ13 cause a symmetrical opening about the σ11 slope influence for either detector position (Figs. 9-11); therefore, σ11 can still be determined by simply averaging the positive and negative β data. Fitting the opening to the τ12 and τ13 terms may be possible, although distinguishing between the two influences through regression is not normally possible. The τ23 value affects the d versus sin2β slope in a similar fashion to σ11 for each detector position (Figs. 12 and 13). This is an unwanted effect since the σ11 and τ23 influence cannot be resolved for one χm position. In this instance, the τ23 shear stress of -100 MPa results in a calculated σ11 value of -472.5 MPa for χm = +12° or -527.5 MPa for χm = -12°, while the actual value is -500 MPa. The value, σ11 can still be determined by averaging the β data for both χm positions. The use of the modified chi mode may be used to determine σ11 but shall be approached with caution using one χm position because of the possible presence of a τ23 stress. The combination of multiple shear stresses including τ23 results in increasingly complex shear influences. Chi and omega mode are preferred over modified chi for these reasons.
Note—Stress matrix is rotated 90° about the surface normal compared to Fig. 2 and Fig. 14. FIG. 3 Chi Mode Diagram for Measurement in σ11 Direction
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1. Scope | ||||||||
1.1 This test method covers a procedure for experimentally determining macroscopic residual stress tensor components of quasi-isotropic bearing steel materials by X-ray diffraction (XRD). 1.2 This test method provides a guide for experimentally determining stress values, which play a significant role in bearing life. 1.3 Examples of how tensor values are used are: 1.3.1 Detection of grinding type and abusive grinding; 1.3.2 Determination of tool wear in turning operations; 1.3.3 Monitoring of carburizing and nitriding residual stress effects; 1.3.4 Monitoring effects of surface treatments such as sand blasting, shot peening, and honing; 1.3.5 Tracking of component life and rolling contact fatigue effects; 1.3.6 Failure analysis; 1.3.7 Relaxation of residual stress; and 1.3.8 Other residual-stress-related issues that potentially affect bearings. 1.4 Units—The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. |
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2. Referenced Documents | ||||||||
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