Unstable Machining Precision of Machine Tools? 6 Key Factors + Calibration Methods to Stabilize Tolerances

Common Problems: Loose anchor bolts (causing slight machine displacement during operation), uneven installation floor (floor level difference exceeding 0.1mm/m, leading to machine tilting), and uncompressed leveling pads (uneven force distribution, causing deformation during vibration).

Troubleshooting Methods: Use a level to check the worktable flatness (allowable deviation ≤0.02mm/1000mm for ordinary milling machines, ≤0.01mm/1000mm for high-precision machining centers); inspect anchor bolts for looseness and retighten them with a torque wrench to the torque specified in the manual (usually 30-50N·m).

Common Problems: Guideway wear due to insufficient lubrication (scratches on surfaces, increased movement resistance), excessive backlash in screw nuts (resulting in "idle travel" during reverse movement), and worn screw bearings (increased spindle radial runout).

Troubleshooting Methods: Manually move the worktable to check for jamming or uneven resistance (indicates guideway wear or poor lubrication); use a dial indicator to measure screw backlash (fix the indicator to the worktable, move it 10mm in one direction, then reverse — the indicator difference is backlash. Allowable backlash ≤0.01mm for ordinary machines, ≤0.005mm for high-precision machines).

Common Problems: Excessive depth of cut in roughing (exceeding tool capacity, deforming the tool shank and causing finishing deviations), overly fast feed rate (especially for thin-walled parts, causing vibration and irregular surface dimensions), and excessively low cutting speed (accelerating tool wear, leading to dimensional drift in later machining).

Troubleshooting Methods: Observe chip condition (overly fragmented or overheated black chips indicate unreasonable parameters); touch the tool shank during machining (obvious heat or vibration means excessive cutting force); compare dimensions of the first part and middle parts — increasing deviations with machining quantity may indicate rapid tool wear (adjust cutting speed or replace tool material).

Common Problems: Worn tool edges (worse surface roughness, "negative direction" dimensional deviation — e.g., worn external turning tools produce smaller outer diameters), tool runout during clamping (runout exceeding 0.005mm, causing uneven cutting depth), and worn tool holders (excessive fit gap between holder and spindle taper, leading to tool eccentricity after clamping).

Troubleshooting Methods: Inspect tool edges with a magnifying glass (replace or regrind if obvious wear or chipping is present); install the tool on the spindle and use a dial indicator to measure tool edge runout (allowable runout ≤0.01mm for ordinary machining, ≤0.005mm for precision machining); check for scratches or wear on the tool holder taper — lightly sand with fine sandpaper or replace if damaged.

Common Problems: Worn fixture locating surfaces (excessive flatness deviation, causing part tilting), uneven clamping force (part deformation during clamping, leading to dimensional rebound after machining — especially for thin-walled parts), and inconsistent references (different references for different processes, accumulating deviations).

Troubleshooting Methods: Use a dial indicator to check fixture locating surface flatness (allowable deviation ≤0.005mm); after clamping the part, measure the runout of the part’s reference surface (runout exceeding 0.003mm indicates loose clamping or low fixture precision); ensure consistent references across processes (e.g., using one end face and outer circle as the reference for all steps) to avoid reference switching.

Common Problems: Large workshop temperature fluctuations (day-night temperature difference exceeding 5℃, causing thermal expansion/contraction of the machine and dimensional deviations), high-frequency vibration sources nearby (e.g., punch presses, air compressors — vibrations transfer to the machine, affecting stability), and excessive humidity (humidity >65%, causing moisture damage to the electrical system and parameter drift).

Troubleshooting Methods: Use a thermometer to record 24-hour workshop temperature changes (high-precision machines require stable ambient temperature of 20±2℃); check for nearby vibration sources — install vibration isolation trenches or pads between the machine and sources if present; use a hygrometer to monitor humidity — install a dehumidifier if levels exceed standards.

Parameter Compensation Calibration: If screw backlash is excessive, set "backlash compensation" in the CNC system (e.g., input 0.012mm if measured backlash is 0.012mm — the system will automatically compensate); for spindle radial runout, use "spindle error compensation" parameters to correct deviations.

Tool Compensation Adjustment: For consistent dimensional deviations in a process (e.g., 0.015mm oversized drilled holes), adjust tool radius compensation (reduce the radius compensation value by 0.0075mm, as hole diameter deviation is twice the radius deviation); for dimensional drift from tool wear, fine-tune tool length compensation periodically (e.g., every 10 parts) to offset wear.

Guideway Repair: For minor guideway scratches, sand with fine sandpaper (800# or higher) and apply guideway-specific grease (per machine manual specifications); for severe wear, contact professionals for guideway grinding (restoring flatness and straightness).

Screw Maintenance: If screw nut backlash is excessive, adjust nut preload (tighten preload screws on the nut to reduce gap); replace worn screw bearings with high-precision bearings (e.g., P4-class bearings to ensure spindle radial runout ≤0.005mm).

Spindle Calibration: For excessive spindle radial runout, disassemble the spindle front cover, inspect bearing wear, replace bearings, and recalibrate runout with a dial indicator (ensure ≤0.005mm).

Rational Tool Selection: Choose tools based on part material and precision requirements (e.g., CBN tools for hardened steel — slow wear, stable precision); avoid overly long or thin tool shanks (reduce deformation — e.g., rigid integral deep-hole drills for deep-hole machining).

Optimize Clamping Methods: For thin-walled parts, use "multi-point support" or "flexible clamping" (e.g., soft jaws to prevent deformation); ensure uniform clamping force (control with a torque wrench — e.g., 20-30N·m to avoid excessive/insufficient force).

Segmented Machining: For complex parts, divide into "roughing → semi-finishing → finishing" with reasonable allowances after each step (0.2-0.3mm for roughing, 0.05-0.1mm for semi-finishing) to avoid stress deformation from one-time cutting.

Regular Precision Inspection: Check machine levelness with a level weekly; measure positioning and repeat positioning accuracy with a laser interferometer monthly (every 6 months for ordinary machines, every 3 months for high-precision machines) to detect deviations early.

Precision Records: Document "part dimensions, machining quantity, and precision deviations" for each batch. If deviations in a process tend to increase (e.g., from ±0.005mm to ±0.008mm), troubleshoot promptly (e.g., tool wear, insufficient guideway lubrication).

Standardize Operations: Develop a Machine Tool Operation Manual specifying standard steps for clamping, tool setting, and parameter configuration (e.g., mandatory use of tool setters, no trial cutting for tool setting; clean fixture locating surfaces before clamping) to avoid precision fluctuations from irregular operations.