If the specimen recovers its initial length, the elastic limit will be higher than the applied stress, and the test must be continued with higher stresses. If the specimen shows permanent deformation, the stress will be greater than the elastic limit. Once deformed, the specimen is useless and must continue to be dimensioned below and above the elasticity limit using other specimens.

To solve these difficulties, two tensions are used:

Interpolation is a common practice when you have several pairs of data (x, y) and you want to determine the ordinate y, which corresponds to a certain abscissa (x).

Linear interpolation considers that the ordinate varies linearly between every two pairs of points. If you have the pair of data (1,2), (3,4) and (4,5), and you want to know the ordinate that corresponds to x = 2.5, you take the first two pairs of points and consider the line that passes through them. The ordinate sought (y = 3.5) will be the one that corresponds to x.

being the length of the specimen after the test.

being the smallest section of the test tube.

If the specimens are rectangular, the calculation of the breaking stresses, the section is expressed by:.

being a' and b' the dimensions.

As the test progresses, the section of the specimen gradually decreases, and the stress it supports is:

S being the section of the specimen at each instant, which reaches its minimum value in the necking zone, and the true tension.

As the test progresses, the length of the specimen gradually increases, and the deformation must be measured with respect to the length it presents at each moment. The deformation will be given by:.

L being the length of the specimen at each moment of the test, the true deformation and the engineering deformation.

In many metals the true stress and strain are linked by the Hollomon relation"):, where and are characteristic constants of the material.

Many metals, such as low carbon steels, do not present a gradual transition between the elastic and plastic behavior zones. Once the limit of the elastic zone has been exceeded, there is a zone of yielding or yielding, in which the specimen experiences plastic deformation under a fluctuating stress. The existence of creep is due to the presence of nitrogen impurities.

In these cases two tensions are defined:

When an element of a structure is designed, it is necessary to know all the forces that are exerted on it, to calculate its section in such a way that it is within the zone of proportionality between its deformation and tension. This ensures that the deformation suffered by the material is reversible and proportional to the stress supported.

You really cannot accurately assess the forces to which a piece will be subjected. In these cases, action is taken by increasing the forces to which the piece may be subjected and/or reducing the resistance of the material.

In the first case, the forces acting on the element are multiplied by a safety coefficient greater than unity. In the second case, a tension indicative of the resistance of the material is divided by another safety coefficient greater than unity.

The machines used in the tensile test consist of a load-producing device and another device that measures recorded loads and displacements. The machine must meet the following characteristics:.

The load producing device can be mechanical or pneumatic, with a moving head and another fixed head.

The load and displacement measuring device operates electronically, regulating the speed of load application and generating printed diagrams of the traction curve.

Tensile tests generally must meet the requirements given the standards with which it is carried out, which define the shape and dimensions of the specimen, the speed of the test, the calibration and precision of the equipment, the environmental conditions and the information that must be presented in the test report. For metallic materials, the standards implemented are EN ISO 6892-1 and ASTM E8/8M.

The specimens used in the tensile test have a circular or rectangular cross section. The central part must be machined so that its section is constant. If the material is fragile, the surface will need to be polished.

The initial length () of the test piece is marked on the calibrated part. The length of the calibrated part must be between and if the specimens are cylindrical. If the test pieces are rectangular or square, the length will be between and .

At the ends of the specimen the section increases to facilitate its attachment to the jaws "Clamp (mechanism)") of the traction machine. These areas are called heads. To avoid areas where stresses are concentrated, the section of the specimen varies from the calibrated part to the head in a smooth and gradual way.

For tests with specimens of different dimensions to be comparable, it must remain constant.

If the specimen recovers its initial length, the elastic limit will be higher than the applied stress, and the test must be continued with higher stresses. If the specimen shows permanent deformation, the stress will be greater than the elastic limit. Once deformed, the specimen is useless and must continue to be dimensioned below and above the elasticity limit using other specimens.

To solve these difficulties, two tensions are used:

Interpolation is a common practice when you have several pairs of data (x, y) and you want to determine the ordinate y, which corresponds to a certain abscissa (x).

Linear interpolation considers that the ordinate varies linearly between every two pairs of points. If you have the pair of data (1,2), (3,4) and (4,5), and you want to know the ordinate that corresponds to x = 2.5, you take the first two pairs of points and consider the line that passes through them. The ordinate sought (y = 3.5) will be the one that corresponds to x.

being the length of the specimen after the test.

being the smallest section of the test tube.

If the specimens are rectangular, the calculation of the breaking stresses, the section is expressed by:.

being a' and b' the dimensions.

As the test progresses, the section of the specimen gradually decreases, and the stress it supports is:

S being the section of the specimen at each instant, which reaches its minimum value in the necking zone, and the true tension.

As the test progresses, the length of the specimen gradually increases, and the deformation must be measured with respect to the length it presents at each moment. The deformation will be given by:.

L being the length of the specimen at each moment of the test, the true deformation and the engineering deformation.

In many metals the true stress and strain are linked by the Hollomon relation"):, where and are characteristic constants of the material.

Many metals, such as low carbon steels, do not present a gradual transition between the elastic and plastic behavior zones. Once the limit of the elastic zone has been exceeded, there is a zone of yielding or yielding, in which the specimen experiences plastic deformation under a fluctuating stress. The existence of creep is due to the presence of nitrogen impurities.

In these cases two tensions are defined:

When an element of a structure is designed, it is necessary to know all the forces that are exerted on it, to calculate its section in such a way that it is within the zone of proportionality between its deformation and tension. This ensures that the deformation suffered by the material is reversible and proportional to the stress supported.

You really cannot accurately assess the forces to which a piece will be subjected. In these cases, action is taken by increasing the forces to which the piece may be subjected and/or reducing the resistance of the material.

In the first case, the forces acting on the element are multiplied by a safety coefficient greater than unity. In the second case, a tension indicative of the resistance of the material is divided by another safety coefficient greater than unity.

The machines used in the tensile test consist of a load-producing device and another device that measures recorded loads and displacements. The machine must meet the following characteristics:.

The load producing device can be mechanical or pneumatic, with a moving head and another fixed head.

The load and displacement measuring device operates electronically, regulating the speed of load application and generating printed diagrams of the traction curve.

Tensile tests generally must meet the requirements given the standards with which it is carried out, which define the shape and dimensions of the specimen, the speed of the test, the calibration and precision of the equipment, the environmental conditions and the information that must be presented in the test report. For metallic materials, the standards implemented are EN ISO 6892-1 and ASTM E8/8M.