Test Machine Base - Specialized Vibration Damping and Stabilizing Base for Test Machines and Fatigue Testing, Ensuring Precision.

What are the recommendations for the installation and maintenance of iron flooring for automotive fatigue testing?
The "lifespan and accuracy" of the test iron flooring depend on the full-process control of selection, installation, and maintenance—choosing the wrong model leads to inherent deficiencies, improper installation creates hidden risks, and inadequate maintenance accelerates aging. Many users focus only on selection but neglect installation and maintenance, resulting in increased vibration and accuracy drift within 1-2 years of use. This article breaks down key points across the full process from "selection pitfalls to avoid, standardized installation, and scientific maintenance" to ensure long-term stable performance of the base and eliminate data distortion.
1. Selection: 3 Steps to Choose the Right Model and Avoid "Inherent Deficiencies"
The core of selection is "matching test requirements," following a three-step screening process of "load → vibration resistance → environment" to avoid blind procurement:
Determine material and load capacity based on total load: Total load = testing machine weight + test piece weight + dynamic loading force (e.g., 12-ton testing machine + 6-ton part + 4-ton dynamic force = 22-ton total load). The base’s rated load capacity must be ≥26.4 tons (with a 20% margin). For light loads (≤5 tons), choose HT250 gray cast iron; for medium loads (5-20 tons), choose HT300; for heavy loads (>20 tons), QT600 ductile iron is essential to ensure deflection ≤0.02mm.
Determine vibration resistance configuration based on vibration frequency: For low frequencies (5-50Hz, e.g., automotive chassis testing), choose a cross-ribbed box structure + HT300 material (damping ratio 0.03-0.04). For high frequencies (>500Hz, e.g., component testing), choose QT600 material + air spring vibration isolators (vibration transmissibility ≤10%), avoiding steel bases (damping ratio 0.01) that cause data fluctuations.
Determine protective coating based on environment: For humid/salt spray environments, choose "galvanized + epoxy resin coating" (salt spray resistance 480 hours). For high-low temperature environments (-40°C to 150°C), choose QT600 material (thermal deformation ≤0.005mm/m). For dusty environments, choose models with 5mm dust-proof edges.
2. Installation: Standardized Operations to Prevent "Acquired Defects"
Improper installation directly compromises base accuracy. Strictly follow the four-step process: "preparation → positioning → calibration → fixation":
Pre-installation preparation: Verify concrete floor strength ≥C30 and flatness ≤0.1mm/m. Use fast-curing epoxy mortar to level uneven areas (30-minute curing time). Prepare a laser level (accuracy ±0.001mm/m) and torque wrench (range 0-500Nm).
Positioning: Use a laser alignment tool to project reference lines. Adjust the base to align with the testing machine’s axis (deviation ≤0.01mm) and ensure edges are parallel to floor reference lines (parallelism ≤0.005mm/m), avoiding visual positioning errors.
Level calibration: Place a level at five points on the base. Rotate leveling bolts (0.5mm adjustment per rotation) to achieve leveling error ≤0.01mm/m, with differences between any two points ≤0.005mm. Mark bolt positions after calibration.
Full Process: 3 Key Reminders
Don’t compromise on quality for cost: Inferior bases lack aging treatment (high residual stress) and deform within 6 months. Choose products with "dual aging certification."
Don’t skip installation steps: Skipping floor leveling or diagonal bolt tightening causes base tilt, which cannot be fully corrected later.
Don’t neglect maintenance: Oil stains on the table surface can penetrate the coating and accelerate corrosion. Develop a habit of "cleaning immediately after testing."
Full-process management of test iron flooring combines "proper selection, quality installation, and smart maintenance"—selection matching requirements is the foundation, standardized installation is the guarantee, and scientific maintenance extends longevity. Following this guide can extend base lifespan from 2-3 years to 8-10 years, maintaining vibration amplitude ≤0.003mm and flatness error ≤0.02mm long-term, providing a stable benchmark for fatigue testing and eliminating issues like "data drift and frequent repairs."
Ms. Xie, Qili Machine Tool, 13785751790