絲杠作為精密傳動系統的核心部件，其使用壽命直接關系到設備運行的穩定性與精度保持能力。絲杠壽命的衰減是多重因素耦合作用的結果，需從材料科學、力學設計、環境適應性及維護策略等維度進行系統性分析。

　　As the core component of precision transmission systems, the service life of screw is directly related to the stability and accuracy maintenance ability of equipment operation. The decay of screw life is the result of the coupling effect of multiple factors, which requires systematic analysis from the dimensions of materials science, mechanical design, environmental adaptability, and maintenance strategies.

　　材料性能與熱處理工藝是決定絲杠壽命的基礎要素。合金鋼或不銹鋼是絲杠桿的常用材質，其化學成分需平衡硬度與韌性。例如，通過淬火+回火工藝可使鋼材表面形成致密馬氏體組織，硬度可達HRC58-62，同時心部保持良好韌性。滾珠與滾道材料則需兼顧耐磨性與尺寸穩定性，陶瓷球或高碳鉻軸承鋼的應用可顯著降低摩擦系數。材料缺陷如非金屬夾雜物、顯微裂紋會成為疲勞裂紋源，因此需通過超聲波探傷等手段進行質量控制。

　　The material properties and heat treatment process are the fundamental factors determining the lifespan of the screw. High quality alloy steel or stainless steel is a commonly used material for wire levers, and its chemical composition needs to balance hardness and toughness. For example, the quenching and tempering process can form a dense martensitic structure on the surface of steel, with a hardness of HRC58-62, while maintaining good toughness in the core. Ball and raceway materials need to balance wear resistance and dimensional stability, and the application of ceramic balls or high carbon chromium bearing steel can significantly reduce the friction coefficient. Material defects such as non-metallic inclusions and microcracks can become fatigue crack sources, so quality control measures such as ultrasonic testing are required.

　　接觸應力與疲勞損傷是絲杠失效的核心機制。在循環載荷作用下，滾珠與滾道接觸區域產生赫茲接觸應力，當應力幅值超過材料疲勞極限時，將引發微裂紋萌生與擴展。采用GCr15軸承鋼的絲杠副，其接觸疲勞壽命可通過Lundberg-Palmgren理論預測，壽命指數與材料硬度、殘余應力及潤滑狀態密切相關。過大的軸向載荷會導致接觸橢圓區擴大，加速表面下裂紋的形成，而徑向載荷則可能引發絲杠彎曲變形，造成邊緣接觸應力集中。

　　Contact stress and fatigue damage are the core mechanisms of screw failure. Under cyclic loading, Hertz contact stress is generated in the contact area between the ball and the raceway. When the stress amplitude exceeds the material fatigue limit, microcracks will initiate and propagate. The contact fatigue life of the screw pair using GCr15 bearing steel can be predicted by Lundberg Palmgren theory, and the life index is closely related to the material hardness, residual stress, and lubrication state. Excessive axial load can cause the expansion of the contact ellipse area, accelerating the formation of subsurface cracks, while radial load may cause bending deformation of the lead screw, resulting in edge contact stress concentration.

　　潤滑狀態與摩擦學設計對壽命延長具有杠桿效應。理想潤滑膜厚度需在埃林漢姆線附近，既避免邊界摩擦又防止黏性阻力過大。合成潤滑油中添加MoS?或PTFE納米顆粒可形成轉移膜，降低摩擦系數。在高速重載工況下，油氣潤滑系統能實現精準供油，避免潤滑劑攪拌發熱。潤滑失效會導致金屬直接接觸，摩擦功耗激增，溫度每升高10℃，潤滑脂基礎油氧化速率加倍，加速潤滑失效。

　　The lubrication state and frictional design have a lever effect on extending the service life. The ideal thickness of the lubricating film should be near the Elingham line to avoid boundary friction and excessive viscous resistance. Adding MoS to synthetic lubricating oil? Or PTFE nanoparticles can form a transfer film, reducing the friction coefficient. Under high-speed and heavy load conditions, the oil air lubrication system can achieve precise oil supply and avoid lubricant stirring and heating. Lubrication failure can lead to direct contact between metals, resulting in a significant increase in frictional power consumption. For every 10 ℃ increase in temperature, the oxidation rate of the lubricating grease base oil doubles, accelerating lubrication failure.

　　安裝精度與預緊力控制是工程應用中的關鍵變量。絲杠安裝的同軸度誤差需控制在0.02mm/m以內，角度偏差超過5'會導致滾珠循環路徑偏移，引發異常磨損。預緊力設置需兼顧軸向剛度與壽命，雙螺母墊片式預緊結構中，預緊力通常取額定動載荷的8%-12%。過大的預緊力會使接觸應力提升40%以上，顯著縮短疲勞壽命，而預緊力不足則導致反向間隙超差，引發振動噪聲。

　　Installation accuracy and preload control are key variables in engineering applications. The coaxiality error of the screw installation should be controlled within 0.02mm/m, and an angle deviation exceeding 5 'will cause the ball circulation path to deviate, leading to abnormal wear. The setting of preload force should take into account both axial stiffness and service life. In the double nut washer preload structure, the preload force is usually taken as 8% -12% of the rated dynamic load. Excessive pre tightening force can increase contact stress by more than 40%, significantly reducing fatigue life, while insufficient pre tightening force can lead to excessive reverse clearance and vibration noise.

　　環境侵蝕與防護技術對戶外應用場景關重要。在沿海環境中，氯離子滲透會導致滾道表面產生點蝕坑，防護涂層如Ni-P化學鍍層可提供有效屏障。高溫環境會使潤滑脂黏度下降，需選用合成烴基礎油并配置冷卻系統。微粒污染會加劇三體磨損，防護等級需達到IP65以上，采用雙唇密封圈與迷宮式防護罩組合設計，可將粉塵侵入量降低。

　　Environmental erosion and protection technologies are crucial for outdoor application scenarios. In coastal environments, chloride ion infiltration can cause pitting on the surface of the raceway, and protective coatings such as Ni-P chemical coatings can provide effective barriers. High temperature environment can cause a decrease in the viscosity of lubricating grease, so synthetic hydrocarbon base oil should be selected and a cooling system should be configured. Particle pollution can exacerbate three body wear, and the protection level needs to reach IP65 or above. The combination design of double lip sealing rings and labyrinth protective covers can reduce the amount of dust intrusion.

　　動態特性與振動抑制是高端裝備的特殊要求。絲杠系統的固有頻率需避開設備工作頻段，避免共振導致的動態應力放大。通過有限元分析優化絲杠支承跨距，可使一階彎曲模態頻率提升。采用變導程設計可分散振動能量，降低噪聲輻射。在數控機床應用中，絲杠軸向剛度需與伺服系統匹配，剛度不足會導致跟隨誤差增大，加速導軌副磨損。

　　Dynamic characteristics and vibration suppression are special requirements for high-end equipment. The natural frequency of the screw system should avoid the operating frequency band of the equipment to prevent dynamic stress amplification caused by resonance. By optimizing the support span of the screw through finite element analysis, the frequency of the first-order bending mode can be increased. The use of variable lead design can disperse vibration energy and reduce noise radiation. In the application of CNC machine tools, the axial stiffness of the screw needs to be matched with the servo system. Insufficient stiffness can lead to increased tracking error and accelerated wear of the guide rail pair.

　　絲杠壽命管理需貫穿設計、制造、使用全周期。通過材料基因工程優化合金成分，應用增材制造實現梯度材料結構，結合物聯網技術實施狀態監測，可構建預測性維護體系。在智能制造時代，絲杠壽命研究正從經驗驅動向數據驅動轉型，為高端裝備可靠性提升提供關鍵支撐。

　　The management of screw life needs to run through the entire design, manufacturing, and usage cycle. By optimizing alloy composition through material genetic engineering, applying additive manufacturing to achieve gradient material structure, and combining with IoT technology to implement state monitoring, a predictive maintenance system can be constructed. In the era of intelligent manufacturing, the research on screw life is transitioning from experience driven to data-driven, providing key support for improving the reliability of high-end equipment.

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