Automatic triaxial testing system
1. Description
The BTU-TTS series is a multi-functional geotechnical triaxial testing system used to determine the mechanical properties of soil under
different stress paths and drainage conditions. The series includes
multiple models, covering testing requirements from small specimens
to large coarse-grained soil specimens. The system integrates axial
load, cell pressure, back pressure, shear rate control, and data
acquisition modules, supporting various standard triaxial test
methods.
2. Test Standards
Although the table does not explicitly list standard numbers, based
on general triaxial test specifications, the system meets the
following domestic and international standards:
• ASTM D4767(Consolidated Undrained Triaxial Compression Test)
• ASTM D7181(Consolidated Drained Triaxial Compression Test)
• ASTM D2850(Unconsolidated Undrained Triaxial Test)
• BS 1377: Part 7(British Standard Triaxial Test)
• ISO 17892-8(Triaxial shear test of soil)
• SL 237-1999(Chinese Geotechnical Test Procedure), etc.
3. Specification
| Model | Max. specimen size (mm) | Max. axial force (kN) | Shear rate range (mm/min) | Cell/Back pressure volume (ml) | Max. air pressure (MPa) |
| BTU-TTS-1F | Φ70 × H140 | 10 | 0.00001~9.99999 | 150 (cell) / 250 (back) @ 2MPa | 2 |
| BTU-TTS-3F | Φ101 × H200 | 30 | 0.00001~9.99999 | 150 (cell) / 250 (back) @ 2MPa | 2 |
| BTU-TTS-5F | Φ38 × H76& Φ50 × H100 | 50 | 0.00001~9.99999 | 150 (cell) / 250 (back) @ 2MPa | 2 |
| BTU-TTS-6F | Φ150 × H300 | 60 | 0.00001~9.99999 | 150 (cell) / 250 (back) @ 2MPa | 2 |
| BTU-TTS-10F | Φ150 (height not specified) | 100 | 0.00001~10 | 3000 @ 3MPa | 3 |
| BTU-TTS-20F | estimated Φ200 | 200 | 0.00001~10 | 3000 @ 3MPa | 3 |
| BTU-TTS-100 | Φ300 × H600 | 1000 | 0.00001~5.6 | 8000 @ 3MPa | 3 |
| BTU-TTS-200 | Φ300 × H600 | 2000 | 0.00001~5.6 | 16000 @ 6MPa | 6 |
4. Detail
• Controller: Independent controllers for cell pressure and back pressure,
supporting high-precision pressure/volume control.
• Data acquisition module: Standard, for real-time recording of axial force, displacement,
pore pressure, volume change.
• Software functions: Includes the following test modules:
◦ Back pressure saturation
◦ Isotropic/anisotropic consolidation
◦ Unconsolidated Undrained (U-U)
◦ Consolidated Undrained (C-U) with pore pressure measurement
◦ Consolidated Drained (C-D) with volume change measurement
◦ K₀ consolidation
◦ Stress path testing
◦ Rheological testing
◦ Sensor calibration
◦ Post-processing and data export
• Air pressure: Used to apply cell and back pressure; models provide 2/3/6 MPa
levels.
5. Application
• Geotechnical site investigation: Determine shear strength parameters (c, φ) of foundation soils
and subgrade soils.
• Dam material testing: Large models (100/200) suitable for triaxial tests on
coarse-grained soils and rockfill.
• Slope stability analysis: Obtain stress-strain curves under different drainage conditions.
• Underground engineering: Simulate pore pressure response during excavation and loading.
• Research and teaching: Used for validation of soil constitutive models and stress path
studies.
6. Advantages
• Wide load and size range: From 10 kN to 2000 kN, covering fine-grained to very large
coarse-grained soils.
• Ultra-low shear control: Minimum 0.00001 mm/min, suitable for creep/rheological tests.
• High-precision volume measurement: Back pressure volume control up to 16000 ml, meeting large
specimen drainage/volume change requirements.
• Fully automatic software control: Integrates multiple standard test procedures, reducing human
error.
• Modular design: Flexible configuration of cell/back pressure and air pressure;
easy sensor calibration.
7. Parameter (Summary)
| Parameter | Range / Value |
| Specimen diameter | 70 mm ~ 300 mm (or larger) |
| Max. axial force | 10 kN ~ 2000 kN |
| Shear rate | 0.00001 ~ 10 mm/min (depending on model) |
| Cell pressure | 2 MPa / 3 MPa / 6 MPa |
| Cell volume | 150 ml ~ 16000 ml |
| Back pressure volume | 250 ml ~ 16000 ml |
| Control method | Computer automatic control + data acquisition |
| Test types | UU, CU, CD, K₀, stress path, rheology |
8. What To Choose
Recommendations based on specimen type and test requirements:
| Specimen type | Recommended model | Reason |
| Fine-grained soil (clay, silt) diameter ≤70mm | BTU-TTS-1F | 10kN sufficient, high speed accuracy, suitable for UU/CU/CD |
| Sand, fine gravel diameter ≤101mm | BTU-TTS-3F | 30kN, 3MPa cell pressure, meets routine triaxial needs |
| Medium gravel, coarse sand diameter ≤150mm | BTU-TTS-5F or 10F | 60~100kN, cell pressure 3~6MPa, optional large back pressure volume |
| Coarse-grained soil, crushed stone diameter ≤200mm | BTU-TTS-20F | 200kN, suitable for subgrade/dam materials |
| Very large coarse-grained soil, rockfill diameter ≤300mm | BTU-TTS-100 | 1000kN, high stiffness, for high-stress triaxial tests |
| Ultra-high stress (e.g., deep rock) | BTU-TTS-200 | 2000kN, confirm specimen size |
Also consider: need for pore pressure measurement, volume change
accuracy, stress path control capability, and on-site compressed
air supply.
9. Process Flow
Below is a standardized procedure for a typical Consolidated Undrained (CU) test using the BTU-TTS series (most steps automatically controlled by
software):
Step 1: Specimen preparation and installation
• Prepare remolded or undisturbed soil specimen according to the
model’s specimen size (e.g., Φ70×H140 mm).
• Assemble porous stone, filter paper, rubber membrane around the
specimen, and place on the triaxial cell base.
• Install pore pressure sensor and top drainage line, seal the
cell.
Step 2: System filling and de-airing
• Open cell and back pressure controllers, fill lines and cell with
de-aired water, remove air bubbles.
• Use software’s “line de-airing” function to ensure accurate
volume change measurement.
Step 3: Back pressure saturation
• Select “Back Pressure Saturation” module in software.
• Set target back pressure (e.g., 300 kPa) and cell pressure (20~50
kPa above back pressure).
• Automatically apply stepped back pressure while monitoring pore
pressure coefficient B (typically B≥0.95 indicates full
saturation).
Step 4: Isotropic/Anisotropic consolidation
• Select “Consolidation” module in software.
• Set target cell pressure (or K₀ condition) and consolidation
time/volume change stability criteria.
• System automatically records volume change and pore pressure
dissipation, generates consolidation log.
Step 5: Shearing (undrained or drained)
• Select “Shearing” module, set shear rate (e.g., 0.05 mm/min).
• Start axial loading; system real-time records axial force,
displacement, pore pressure (CU) or volume change (CD).
• Automatically detect peak or termination condition (e.g., strain
reaches 20%).
Step 6: Test termination and data processing
• Software automatically stops loading, releases cell pressure,
exports raw data (stress, strain, pore pressure, volume change).
• Post-processing module calculates shear strength parameters (c,
φ), elastic modulus, failure strain, etc.
• Generate test report, export to Excel/PDF.
Step 7: Equipment cleaning and maintenance
• Drain cell water, remove specimen.
• Clean lines and porous stone; perform sensor zeroing check.
For other test types (U-U, CD, stress path, rheology), only the
drainage conditions and control targets during
saturation/consolidation/shearing stages change; the software
provides built-in wizards accordingly.
