Contenido

Para las muestras de suelo, la muestra está contenida en una manga cilíndrica de látex con una placa de metal circular plana o una placa que cierra los extremos superior e inferior. Este cilindro se coloca en un baño de un fluido hidráulico para proporcionar presión a lo largo de los lados del cilindro. La placa superior puede ser conducida mecánicamente hacia arriba o hacia abajo a lo largo del eje del cilindro, para apretar el material. La distancia que recorre la placa superior se mide como una función de la fuerza requerida para moverla, ya que la presión del agua circundante se controla cuidadosamente. El cambio neto en el volumen del material también se puede medir por la cantidad de agua que ingresa o sale del baño circundante, pero generalmente se mide cuando la muestra está saturada de agua, valorando la cantidad de agua que entra o sale de los poros de la muestra.

Rock

For high-strength rock testing, the sleeve may be a thin metal sheet instead of latex. Triaxial testing is rarely performed on strong rock because the high forces and pressures required to break a tough rock sample require expensive and cumbersome testing equipment.

Effective efforts

The effective stresses in the sample can be measured by using a porous surface on a plate, and measuring the pressure of the fluid (usually water) during the test, and then calculating the effective stresses from the total stress and pore pressure.

Triaxial test to determine the shear strength of a discontinuity

The triaxial test can be used to determine the shear strength of a discontinuity. A homogeneous and isotropic sample fails due to shear stresses in the sample. If a sample with a discontinuity is oriented so that the discontinuity is approximately parallel to the plane in which the maximum shear stress will develop during the test, it will fail, due to shear displacement along the discontinuity, and therefore the shear strength of a discontinuity can be calculated.[5]​.

Hay variaciones del ensayo triaxial:.

Consolidated drained

In a "consolidated drainage" (CD) test, the sample is consolidated and sheared in compression slowly to allow the pore pressures built up from shear to dissipate. The axial strain rate is kept constant; that is, the strain is controlled. The idea is that the test allows the sample and pore pressures to fully consolidate (adjust) to the surrounding stresses. The test may take a long time to allow the sample to adjust. sample. Particularly low permeability samples need a long time to drain and adjust the deformation to the stress levels.

Consolidated undrained

In a “consolidated undrained” (CU) test, the sample cannot be drained. Cutting characteristics are measured according to such conditions. The sample is assumed to be completely saturated. Measuring the pore pressures in the sample (sometimes referred to as CUpp) allows the consolidated drained strength to be approximated. Shear rate is often calculated based on the consolidation rate under a specific confining pressure (while saturated). Confining pressures can range from one pound per square inch (psi) to 100 or more psi. Sometimes they require special load cells capable of generating higher pressures.

Unconsolidated undrained

In an “unconsolidated undrained” (UU) test, loads are applied quickly. The sample is not allowed to consolidate during the test. The sample is compressed at a constant rate (controlled by strain).

True triaxial test

Triaxial testing systems have been developed to allow independent control of stress in three perpendicular directions. This encourages the investigation of stress paths that cannot be generated in axisymmetric triaxial testing machines, which can be useful in studies of cemented sands and anisotropic soils. The test cell is cubic, and there are six separate plates that apply pressure to the sample, with linear variable differential transformer (LVDT) reading the motion of each plate.[6] Pressure in the third direction can be applied using hydrostatic pressure in the test chamber, which requires only four sets of stress applications. The apparatus is significantly more complex than for axisymmetric triaxial tests and is therefore used less frequently.

Free final condition triaxial test

Triaxial tests of classical construction had been criticized for their non-uniform stress and for the strain field imposed within the specimen during larger strain amplitudes.[7] Highly localized discontinuity within a shear zone is caused by the combination of rough end plates and specimen height.

To test specimens during a larger strain amplitude, "new"[8]​ and "improved"[9]​ versions of the triaxial apparatus were made. Both the “new” and the “improved” triaxial follow the same principle: the height of the sample is reduced to a diameter height and the friction with the end plates is cancelled.

The classic apparatus uses rough end plates: the entire surface of the piston head is formed by a rough and porous filter. In improved devices, the hard end plates are replaced with smooth, polished glass, with a small filter in the center. This configuration allows a sample to slide/expand horizontally as it slides along the polished glass. Therefore, the contact zone between the sample and the end plates does not generate unnecessary shear friction, and a linear/isotropic stress field is maintained within the sample.

Due to an extremely uniform quasi-isotropic stress field, isotropic performance takes place. During isotropic performance, the volumetric strain is isotopically distributed within the sample. This improves measurement of volumetric response during CD testing and pore water pressure during CU loading. Additionally, isotropic performance expands the sample radially uniformly as it is compressed axially. The walls of a cylindrical sample remain straight and vertical even during large strain amplitudes (Vardoulakis, 1980) documented 50% of the strain amplitude, using an “improved” triaxial on unsaturated sand). This contrasts with the classical configuration, where the sample forms a cornet in the center, and maintains a constant radius in contact with the end plates.

The "new" apparatus has been updated to the daish triaxial by L. B. Ibsen.[10]​ The Danish triaxial can be used to test all types of soil. It provides improved measurements of the volumetric response since, during isotropic performance, the volumetric strain is isotopically distributed within the sample. Isotropic volume change is especially important for CU testing, because pore water cavitation sets the limit on the strength of undrained sand.[11]​ Measurement accuracy is improved by taking measurements close to the sample. The load cell is submerged and in direct contact with the elevated pressure head of the sample. The strain transducers are also attached directly to the piston heads. The control of the device is highly automatic, so the cyclic loading can be applied with great efficiency and precision.

The combination of high automation, improved sample durability and great strain compatibility expands the scope of triaxial testing. Danish triaxial can produce CD and CU sand samples in plasticity without forming shear break or bulge. A sample can be tested for production multiple times in a single continuous loading sequence. Samples can even be liquefied at a large strain amplitude, and then pressed to CU failure. CU tests can be allowed to transition to the CD state and be tested cyclically in CD mode to observe the recovery of stiffness and strength after liquefaction.[12]​ This allows samples to be controlled to a very high degree and to observe sand response patterns that cannot be accessed using classical triaxial test methods.

The list is not complete. Only the main standards are included. For a more extensive list, consult the websites of ASTM International (USA), British Standards (UK), International Organization for Standardization (ISO), or local organizations.

Contenido

Para las muestras de suelo, la muestra está contenida en una manga cilíndrica de látex con una placa de metal circular plana o una placa que cierra los extremos superior e inferior. Este cilindro se coloca en un baño de un fluido hidráulico para proporcionar presión a lo largo de los lados del cilindro. La placa superior puede ser conducida mecánicamente hacia arriba o hacia abajo a lo largo del eje del cilindro, para apretar el material. La distancia que recorre la placa superior se mide como una función de la fuerza requerida para moverla, ya que la presión del agua circundante se controla cuidadosamente. El cambio neto en el volumen del material también se puede medir por la cantidad de agua que ingresa o sale del baño circundante, pero generalmente se mide cuando la muestra está saturada de agua, valorando la cantidad de agua que entra o sale de los poros de la muestra.

Rock

For high-strength rock testing, the sleeve may be a thin metal sheet instead of latex. Triaxial testing is rarely performed on strong rock because the high forces and pressures required to break a tough rock sample require expensive and cumbersome testing equipment.

Effective efforts

The effective stresses in the sample can be measured by using a porous surface on a plate, and measuring the pressure of the fluid (usually water) during the test, and then calculating the effective stresses from the total stress and pore pressure.

Triaxial test to determine the shear strength of a discontinuity

The triaxial test can be used to determine the shear strength of a discontinuity. A homogeneous and isotropic sample fails due to shear stresses in the sample. If a sample with a discontinuity is oriented so that the discontinuity is approximately parallel to the plane in which the maximum shear stress will develop during the test, it will fail, due to shear displacement along the discontinuity, and therefore the shear strength of a discontinuity can be calculated.[5]​.

Hay variaciones del ensayo triaxial:.

Consolidated drained

In a "consolidated drainage" (CD) test, the sample is consolidated and sheared in compression slowly to allow the pore pressures built up from shear to dissipate. The axial strain rate is kept constant; that is, the strain is controlled. The idea is that the test allows the sample and pore pressures to fully consolidate (adjust) to the surrounding stresses. The test may take a long time to allow the sample to adjust. sample. Particularly low permeability samples need a long time to drain and adjust the deformation to the stress levels.

Consolidated undrained

In a “consolidated undrained” (CU) test, the sample cannot be drained. Cutting characteristics are measured according to such conditions. The sample is assumed to be completely saturated. Measuring the pore pressures in the sample (sometimes referred to as CUpp) allows the consolidated drained strength to be approximated. Shear rate is often calculated based on the consolidation rate under a specific confining pressure (while saturated). Confining pressures can range from one pound per square inch (psi) to 100 or more psi. Sometimes they require special load cells capable of generating higher pressures.

Unconsolidated undrained

In an “unconsolidated undrained” (UU) test, loads are applied quickly. The sample is not allowed to consolidate during the test. The sample is compressed at a constant rate (controlled by strain).

True triaxial test

Triaxial testing systems have been developed to allow independent control of stress in three perpendicular directions. This encourages the investigation of stress paths that cannot be generated in axisymmetric triaxial testing machines, which can be useful in studies of cemented sands and anisotropic soils. The test cell is cubic, and there are six separate plates that apply pressure to the sample, with linear variable differential transformer (LVDT) reading the motion of each plate.[6] Pressure in the third direction can be applied using hydrostatic pressure in the test chamber, which requires only four sets of stress applications. The apparatus is significantly more complex than for axisymmetric triaxial tests and is therefore used less frequently.

Free final condition triaxial test

Triaxial tests of classical construction had been criticized for their non-uniform stress and for the strain field imposed within the specimen during larger strain amplitudes.[7] Highly localized discontinuity within a shear zone is caused by the combination of rough end plates and specimen height.

To test specimens during a larger strain amplitude, "new"[8]​ and "improved"[9]​ versions of the triaxial apparatus were made. Both the “new” and the “improved” triaxial follow the same principle: the height of the sample is reduced to a diameter height and the friction with the end plates is cancelled.

The classic apparatus uses rough end plates: the entire surface of the piston head is formed by a rough and porous filter. In improved devices, the hard end plates are replaced with smooth, polished glass, with a small filter in the center. This configuration allows a sample to slide/expand horizontally as it slides along the polished glass. Therefore, the contact zone between the sample and the end plates does not generate unnecessary shear friction, and a linear/isotropic stress field is maintained within the sample.

Due to an extremely uniform quasi-isotropic stress field, isotropic performance takes place. During isotropic performance, the volumetric strain is isotopically distributed within the sample. This improves measurement of volumetric response during CD testing and pore water pressure during CU loading. Additionally, isotropic performance expands the sample radially uniformly as it is compressed axially. The walls of a cylindrical sample remain straight and vertical even during large strain amplitudes (Vardoulakis, 1980) documented 50% of the strain amplitude, using an “improved” triaxial on unsaturated sand). This contrasts with the classical configuration, where the sample forms a cornet in the center, and maintains a constant radius in contact with the end plates.

The "new" apparatus has been updated to the daish triaxial by L. B. Ibsen.[10]​ The Danish triaxial can be used to test all types of soil. It provides improved measurements of the volumetric response since, during isotropic performance, the volumetric strain is isotopically distributed within the sample. Isotropic volume change is especially important for CU testing, because pore water cavitation sets the limit on the strength of undrained sand.[11]​ Measurement accuracy is improved by taking measurements close to the sample. The load cell is submerged and in direct contact with the elevated pressure head of the sample. The strain transducers are also attached directly to the piston heads. The control of the device is highly automatic, so the cyclic loading can be applied with great efficiency and precision.

The combination of high automation, improved sample durability and great strain compatibility expands the scope of triaxial testing. Danish triaxial can produce CD and CU sand samples in plasticity without forming shear break or bulge. A sample can be tested for production multiple times in a single continuous loading sequence. Samples can even be liquefied at a large strain amplitude, and then pressed to CU failure. CU tests can be allowed to transition to the CD state and be tested cyclically in CD mode to observe the recovery of stiffness and strength after liquefaction.[12]​ This allows samples to be controlled to a very high degree and to observe sand response patterns that cannot be accessed using classical triaxial test methods.

The list is not complete. Only the main standards are included. For a more extensive list, consult the websites of ASTM International (USA), British Standards (UK), International Organization for Standardization (ISO), or local organizations.