Testing Methods for JIS Steel Materials

Sommario:

Tensile test is the most widely used test to determine the mechanical properties of materials. In this test, a piece of material is pulled until it fractures.

Strain and stress are calculated from these values, and are used to construct a stress-strain curve. From this curve, the elastic modulus and yield strength are determined.

The tensile test is the most widely used test to determine the mechanical properties of materials. In this test, a piece of material is pulled until it fractures. During the test, the specimen elongation and applied load is measured. Strain and stress are calculated from these values, and are used to construct a stress-strain curve. From this curve, the elastic modulus and yield strength are determined.

The highest load in the tensile test gives the tensile or ultimate strength. After fracture, the final length and cross-sectional area of the specimen are used to calculate the percent elongation and percent reduction of area, respectively. These quantities indicate the ductility of the material. By using the instantaneous length and cross-sectional area, the true stress and true plastic strain are calculated from the load and elongation.

The strain hardening properties of the material are then determined from a log-log plot of the true stress vs. the true plastic strain. Thus, from one test a large amount of information can be obtained about the mechanical properties of a material.

Numerous groups have developed standard methods for conducting the tensile test. In the United States, standards published by ASTM are commonly used to define tensile-test procedures and parameters. Standard Methods for conducting the tensile test are also available from other standards organizations, such as the Japanese Industrial Standards (JIS), the Deutsche Institut für Normung (DIN), and the International Organization for Standardization (ISO). Other domestic technical groups in the United States have developed standards, but in general, these are based on ASTM E.8.

Typical test pieces are shown below. They are normally circular, but may be flat. The standard diameter is 12.5mm.



Figure 1: Typical test pieces



Figure 2: Unstretched and full stretched specimens



Figure 3: Test pieces after tensile testing

The tensile test piece is mounted into the grips of the tensile test machine. The grips are moved apart at a constant rate and the applied load is measured by a load cell while the extension is measured by an extensometer.



Figure 4: Tensile test machine

The test is normally destructive - the test piece is permanently deformed and usually fractured in the test.

This Japanese Industrial Standard specifies test pieces for tensile test for metallic materials (hereafter referred to as “test piece”). The type of test piece depends upon the form and size and these are generally classified into the proportional test piece and the non-proportional piece as described in Table 1.

Table 1: Classification of test piece

Form of test piece Flat form test piece Bar form test piece Tubular form test piece Arc section test piece Wire form test piece
Proportional test piece N°14B N°2; N°14A N°14C N°14B  
Non-proportional test piece N°1A; N°1B; N°5; N°13A; N°13B N°4; N°10; N°8A; N°8B; N°8C; N°8D N°11 N°12A; N°12B; N°12C N°9A; N°9B

The selection of the type of test piece to be used shall be in accordance with the requirements of the standard for that particular material, but it is recommended to be selected as given in Table 2.

Table 2: Classification of test piece

Material Test Piece Remarks
Form Dimensions Proportional Non-proportional
Sheet, Plate, Shape, Strip *t > 40 N°14A N°4; N°10 For bar form test piece
N°14B - For bar form test piece
20 < t ≤ 40 N°14A N°4; N°10 For bar form test piece
N°14B N°1A For flat form test piece
6 < t ≤ 20 N°14B N°1A; N°5
N°5; N°13A; N°13B
3 < t ≤ 6
t ≤ 3 -
Bar - N°2; N°14A N°4; N°10 -
Wire - - N°9A; N°9B -
Pipe Pipe of small outside diameter N°14C N°11 For tubular form test piece
**D ≤ 50 N°14B N°12A For arc section test piece
50 < D ≤170 N°12B
D >170 N°12C
D ≥200 N°14B N°5 For flat form test piece or arc section test piece
Thick wall pipe N°14A N°4 For bar form test piece
Casting - N°14A N°4; N°10 -
- - N°8A; N°8B; N°8C; N°8D To be used when elongation value is not required. To be taken from test coupon casted for test piece.
Forging - N°14A N°4; N°10 -

*t - thicknesses in mm
**D - outside diameter in mm

Remarks:
1. N°1B test piece shall be used in the case where the test pieces shown in Table 2 are not suitable to be used.
2. N°3, N°6 and N°7 test piece specified in Annex should be used when the use of test pieces given in Table 2 is not suitable.
3. For the materials specified in the International Standard, the division of use shown in the following remarks Table 1 may be used.

Remarks Table 1: Division of use and dimension of test piece based on International Standard

Shape of cross section of product Dimension
[mm]
Width
W
Gauge length
L
Parallel length
P
Distance from end of parallel portion to grip
Sheet t < 3 12.5 50 75 87.5
20 80 120 140
t ≥ 3   5.65√***A L+2√A  
Bar D < 4   200   250
  100   150
D ≥ 3   5D L+2D  
Wire D < 4   200   250
  100   150
D ≥ 4   5D L+2D  
Pipe t < 3 12.5 50 75 87.5
20 80 120 140
t ≥ 3   5.65√A L+2√A  
Shape t < 4   200   250
  100   150
t ≥ 4   5D L+2D  

***A- sectional area of parallel portion

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Sommario

Il Modulo opzionale Extended Range di Total Materia include una raccolta unica al mondo di curve Stress-Strain per calcoli in campo plastico relativi a migliaia di leghe metalliche, per differenti Trattamenti Termici e temperature di lavoro. Curve "true" e "engineering" sono fornite per varie velocità di deformazione ove applicabili.

Trovare un grafico Stress-Strain nel database è semplice e richiede solo pochi secondi.

Per prima cosa occorre inserire la Designazione della lega che interessa nel campo di Ricerca Rapida. Opzionalmente si può restringere la ricerca selezionando il Paese / Normativa dalla lista a discesa, e poi si clicca su "Invio".


Dopo aver selezionato il materiale di interesse, occorre cliccare sul collegamento "Curve Stress-Strain" per visualizzare i dati relativi al materiale selezionato. Il numero dei dati (diagrammi) disponibili viene visualizzato tra parentesi accanto al link.


Perché le curve Stress-Strain sono neutrali rispetto alle Normative, è possibile visualizzare i diagrammi cliccando sul link relativo per ogni Sottogruppo.

Oltre le curve Stress-Strain a diverse temperature, i dati sono forniti in forma di tabella che è esportabile a un software CAE come testo.


È anche possibile visualizzare curve Stress-Strain e relativi dati numerici per diverse temperature di lavoro.

Per fare questo, è sufficiente inserire una nuova temperatura nella casella specifica compresa nei limiti definiti e dare Invio.

Dopo aver fatto clic sul pulsante "Calcola", viene generata una nuova curva e i valori nella tabella corrispondono ora alla nuova temperatura. Si veda l'esempio qui sotto per 250°C.


Per consentirvi di testare il Database Total Materia "senza impegno", vi invitiamo a unirvi alla comunità degli Utenti registrati per i test gratuiti a Total Materia.