Pile Dynamic Testing Equipment Pile Load Capacity Testing Instrument Deep Foundation Bearing Capacity Testing Load Testing Piles Driving Analyzer

Pile Dynamic Testing Equipment Pile Load Capacity Testing Instrument Deep Foundation Bearing Capacity Testing Load Testing Piles Driving Analyzer



In the high strain method, a vertical transient impact load is applied to the pile top by the hammering system. The force acting on the pile top is close to the actual stress level of the pile, resulting in significant acceleration and inertia force. The strain of the pile body is equivalent to the strain level of the engineering pile. The impact force causes relative displacement between the pile and soil, so as to give full play to the pile side friction and stimulate the end resistance accordingly, Force and acceleration sensors are symmetrically installed on both sides of the pile at a certain distance from the pile top to measure the force and the response signal of the pile-soil system. The hammer response signal (pile strain stress curve and pile particle motion speed curve) is received through the foundation pile dynamic tester. Its dynamic response signal not only reflects the pile-soil characteristics, but also is closely related to the dynamic load intensity, spectrum composition and duration, Thus, the bearing capacity of single pile and the structural integrity of pile body are calculated and analyzed.



Technical Features
The first in the industry, with one - body screen. Visible in sunlight with better effect than new phones. Currently the industry's Only one of its kind.
Adopt full superimposed display method. More image observation of signal consistency, stability.
Low strain RS mode, PIT mode same machine operation.
Velocity, displacement, stress, velocity displacement, Case curve, split screen display, can clearly see each channel signal change.
Automatic implementation of click, hit, and monitor modes. Real-time monitoring of strain transducer deformation.
Up to 110 hammers per minute pile monitoring.
Case method analysis and display of F-ZV curve and traveling wave curve can be realized on site.
Adopt 24-bit high-precision low-noise ADC, ADC built-in digital filter, high signal-to-noise ratio, high reliability and low noise.

 

The high strain testing example of a foundation pile is shown below.
Information of foundation pile: pile number: 75_ 2, total length of pile: 31.22m, length of pile under test point and length of pile buried underground: 29.62m, Sounding: 0m, pile diameter: 800mm, wave velocity of pile body and test point: 3970m/s, density of pile body and test point: 2548kg/m', design carrying capacity: 500kN, safety factor: 2

Assumption: project name: PY, weight of blow: 3500kg, drop distance: 0.3m, calculation method: RSP, Keyes coefficient JC: 0.3
Information of sensor: high strain accelerometer sensitivity coefficient (A1: 3.06mV/g, A2: 3.03mV/g) and strain sensor sensitivity coefficient (E1: 6.3μV/με, E2: 6.3μV/με,)

Click the "Monitor" button at the operation command area on the right side of data acquisition interface to view the initial state of strain sensor after installation. If the initial strains of strain sensors in the two strain channels are in the range of several ~ several tens of μεs, it is considered that the installation of strain sensors is balanced;
if the initial strains of 10 strain sensors in the two strain channels are above two hundred μεs, it is considered that the installation of strain sensors is unbalanced and the installation of appropriate strain sensors needs to be adjusted until the initial strains of appropriate strain sensors are in an equilibrium state,