# Lubrication Challenges in Deep-Sea Gear Trans-Missions: A Review of High-Pressure and Low-Temperature Effects

**Authors:** Weiqiang Zou, Xigui Wang, Yongmei Wang, Jiafu Ruan

PMC · DOI: 10.3390/ma19051020 · 2026-03-06

## TL;DR

This paper reviews lubrication challenges in deep-sea gear systems caused by extreme pressure and cold temperatures, and proposes strategies to improve reliability.

## Contribution

The study introduces a systematic analysis of lubrication degradation mechanisms and proposes novel mitigation strategies like meshing interface texturing.

## Key findings

- Optimized micro-texture architectures can compensate for viscosity-induced fluidity deficits.
- Seawater intrusion causes lubricant emulsification and additive deactivation.
- Conventional TEHL theory requires modification to address extreme deep-sea conditions.

## Abstract

Deep-sea gear transmission systems encounter critical lubrication challenges arising from the synergistic coupling of extreme hydrostatic pressure and cryogenic temperatures. These environmental stressors induce exponential viscosity escalation in lubricants, precipitating severe fluidity degradation, elevated startup resistance, and lubrication starvation. Concurrently, seawater intrusion triggers lubricant emulsification, additive deactivation, and electrochemical corrosion at meshing interfaces, collectively escalating the risk of catastrophic lubrication failure and compromising long-term operational reliability. This study systematically elucidates the lubrication degradation mechanisms inherent to deep-sea environments and proposes targeted mitigation strategies. Through comprehensive characterization of deep-sea environmental parameters and their impact on lubricant rheological behavior, we critically evaluate the applicability and inherent limitations of conventional Thermal Elasto-Hydrodynamic Lubrication (TEHL) theory under extreme conditions. Our analysis reveals that established TEHL frameworks necessitate substantial modification to accurately capture pressure-viscosity-temperature coupling phenomena and seawater contamination kinetics. Meshing interface texturing, as an effective anti-friction and wear-mitigation strategy, is investigated to delineate its mechanistic pathways for enhancing lubricant film formation and tribological performance under starved lubrication regimes. Key findings demonstrate that optimized micro-texture architectures can effectively compensate for viscosity-induced fluidity deficits and attenuate the deleterious effects of seawater ingress. Critical knowledge gaps are identified, and future research trajectories are charted: (i) multiphysics coupling models integrating thermo-hydrodynamic, chemo-physical, and mechanical degradation processes; (ii) synergistic texture-coating design paradigms; (iii) high-pressure low-temperature experimental validation protocols; and (iv) engineering implementation frameworks for deep-sea gear transmission systems. This review establishes theoretical foundations and provides technical guidelines for robust lubrication design and long-term operational stability of deep-sea transmission equipment.

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12985982/full.md

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Source: https://tomesphere.com/paper/PMC12985982