What are the ways to solve the installation and alignment problems of LF cooling tower fan reducer?

The following are three core practical methods to solve the installation and alignment problems of LF cooling tower fan reducer. They focus on key issues and have clear steps that can be implemented:

1. Foundation reinforcement and flatness correction (to eliminate 'innate offset')

Core problem: The installation foundation is not firm and the flatness exceeds the standard, causing the base to resonate during operation, causing alignment deviation and component wear.

Practical steps:

① Use a level to check the foundation surface to ensure that the flatness is ≤0.2mm/m. Use epoxy resin mortar to level the parts that exceed the standard (thickness 5~10mm), and cure it for 24 hours before installing;

② Install a Shore A 60~70 hardness rubber shock-absorbing pad (thickness 10~15mm) between the base and the foundation to ensure that each shock-absorbing pad is evenly stressed (gap ≤ 0.5mm);

③ Use M16~M24 expansion bolts (according to equipment weight Selection) to fix the base, tighten diagonally three times, the pretightening torque meets the manufacturer's requirements (generally 200~350N·m), and add spring washers + lock nuts.

Effect: Reduce the vibration amplitude of the base by ≥50% and avoid the recurrence of centering deviation caused by foundation problems.

2. Accurate alignment and correction (cold + hot double review)

Core issue: The misalignment of the motor and reducer shaft system (radial direction > 0.1mm, end face > 0.05mm) is the main reason for bearing heating, abnormal noise in the coupling, and seal leakage.

Practical steps:

① Cold calibration: Use a dial indicator or laser alignment instrument to measure at the four positions of the coupling: 0°, 90°, 180°, and 270°. Adjust the motor foot pads (thickness 0.1~2mm, no more than 3 layers on one side) to ensure that the radial deviation is ≤0.1mm and the end face runout is ≤0.05mm. After correction, tighten the anchor bolts according to the torque;

② Thermal state review: The equipment runs for 2 hours (after the temperature stabilizes), and the alignment accuracy is rechecked. The allowed radial deviation is ≤0.15mm, and the end face runout is ≤0.08mm. If the tolerance is exceeded, the gaskets are fine-tuned to compensate for thermal expansion and contraction.

Key tool: Prioritize the use of laser alignment instrument (accuracy 0.001mm) to replace ruler/naked judgment to avoid human error.

3. Optimization of couplings and connecting parts (reduces 'transmission shock')

Core problem: The aging of the coupling elastomer and the excessive clearance of the shaft hole lead to amplification of the alignment deviation and aggravated vibration and wear.

Practical steps:

① Disassemble the coupling, clean the end face and shaft hole (remove oil stains and burrs), check whether the elastomer is cracked or hardened, and replace the polyurethane elastomer with the same model (temperature resistance - 20~100°C);

② Measure the fitting clearance of the shaft hole. If it is ≥ 0.1mm, replace the coupling or repair the shaft head with chrome plating to ensure a tight fit without looseness;

③ Synchronous correction of the fan impeller end: Check the impeller end face runout ≤0.1mm, use a laser alignment tool to ensure that the coaxiality between the reducer output shaft and the impeller shaft is ≤0.1mm, pre-tighten the impeller fixing bolts to 80~150N·m and install a lock washer.

Effect: Reduce coupling transmission impact and extend the life of bearings and seals by ≥30%.