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Comprehensive Enhancement Plan for Fatigue Resistance of Railway Parts

Our factory has been deeply engaged in the casting of 철도 부품 for many years and fully understands that “안전” is the unshakable lifeline of the railway industry. Railway parts are constantly subjected to repeated impacts and loads during the long-term and high-intensity operation of trains. 그러므로, improving the fatigue resistance of products is not only a basic requirement to meet customer standards but also a solemn commitment we make to train safety. This plan will systematically propose the path for our next technical improvements from four aspects: “Treating the Root Cause”, “Precision Workmanship”, “Strengthening the Body”, 그리고 “Diagnosis”.

some parts of the locomotive from our factory

나. Treating the Root Cause: Perfection in Materials and Design

Fatigue begins from within. We must lay a solid foundation from the design and material selection stage before the parts areborn”.

Material Upgrade and Purification:

1.1 Selecting High-Quality Raw Materials: We will resolutely use high-purity and reliable primary iron and scrap steel, controlling the content of harmful elements such as sulfur and phosphorus from the source. These harmful elements are likeweak pointsinside the metal, easily becoming the origin of fatigue cracks under alternating stress.

1.2 Optimizing Alloying: Based on traditional materials, we will fine-tune the alloy ratio according to the specific force characteristics of each component. 예를 들어, appropriately increasing the content of elements such as manganese, chromium, and molybdenum can significantly refine the grain structure, enhancing the material’s strength and toughness, likestrengthening the bones and musclesof the metal to better resist fatigue.

Structural Optimization Design:

1.3 Eliminating Stress Concentration: Fatigue cracks prefer to start fromsharp corners” 그리고 “notches”. Our design team must ensure smooth transitions at all corners, grooves, holes, and other locations when drawing the blueprints. Even a small fillet can greatly disperse stress and avoid theweak link effect”.

1.4 Simulation Analysis Assistance: For core load-bearing parts, we will introduce computer-aided engineering analysis. Before mold opening, we will simulate the stress conditions under real working conditions through software to identify potential high-stress areas in advance and optimize the design in the design stage, achievingprevention before the problem occurs”.

II. Precision Workmanship: Process Control in Casting

The stability of the casting process directly determines the internal quality of the product.

Melting and Pouring:

2.1 Precise Temperature Control: We will adhere to the principle ofhigh-temperature melting and low-temperature pouring”. High-temperature melting ensures uniform composition and the complete floating of gases and inclusions; low-temperature pouring reduces defects such as shrinkage porosity and hot cracking caused by casting shrinkage. This is like cooking, where the dish is only delicious when the heat is just right.

2.2 Spheroidization and Inoculation: For ductile iron castings, this is a critical process. We must strictly control the amount and timing of the addition of spheroidizing agents and inoculants to ensure a high spheroidization rate and good roundness of graphite. These round graphite spheres can effectively prevent the expansion of cracks and are the core to enhancing toughness.

Molding and Cooling:

2.3 Sand Mold Strength and Permeability: Ensure that the sand mold has sufficient strength and uniform permeability to prevent surface defects such as sand sticking and porosity in the castings. Any surface defect is a ready-madefatigue source”.

2.4 Scientific and Orderly Cooling: The cooling rate of the casting in the sand mold must be uniform. Excessive cooling leads to excessive internal stress, while too slow cooling results in coarse grains. We should consider setting up reasonableinsulating risers” 그리고 “chill ironsto guide the casting to solidify in abottom-up, thin-to-thicksequence, obtaining a dense and uniform internal structure.

III. Strengthening the Body: Heat Treatment and Surface Strengthening

Casting is only therough form”, and heat treatment is the key step to unlocking its potential.

3.1 Tailored Heat Treatment:

Abandoning theone-size-fits-allheat treatment model. We will develop precise normalizing, annealing, 담금질 + tempering process curves based on different materials and performance requirements. Especially the quenching + high-temperature tempering (tempering after quenching), which can endow parts with excellent strength and toughness, is theace cardfor enhancing fatigue resistance. Strict control of tempering temperature and time: Tempering is to eliminate quenching stress and obtain a stable structure. We must precisely control the tempering process, like carefully stewing soup, to ensure stable performance.

3.2 Application of surface strengthening technology:

3.2.1 Shot peening: This is the process we should popularize and strengthen the most at present. By using a high-speed stream of shots to impact the surface of the parts, plastic deformation occurs, forming a dense layer of compressive stress. Fatigue cracks are difficult to form and expand under pressure. This is like putting on atight bulletproof veston the surface of the parts.

3.2.2 Strengthening of holes and threads: For stress concentration areas such as bolt holes and threads, a special rolling process is used to introduce compressive stress on the surface, which can increase the fatigue life of these weak links several times.

IV. Diagnosis and Treatment: Quality Inspection and Feedback throughout the Process

Quality without inspection is just empty talk. We must establish a quality monitoring system throughout the process.

4.1 Full coverage of non-destructive testing:

For core parts leaving the factory, 100% magnetic particle or ultrasonic testing is conducted to ensure there are no internal cracks, shrinkage cavities, or other fatal defects. This is thefinal physical examinationbefore the product leaves the factory, and no negligence is allowed.

4.2 Establishment of quality traceability files:

For each batch, even for key parts, a full-process file fromfurnace numbermolding – 열처리 – 가공 – 점검” is established. In case of any problems, the source can be quickly traced, the cause analyzed, and closed-loop management achieved.

4.3 Continuous improvement mechanism:

Regularly collect customer feedback during use, especially in cases of fatigue damage. Feed this first-hand information from thebattlefieldback to our design, production, and quality inspection departments as the most valuable basis for continuous optimization.

Improving the fatigue resistance of railway parts is not an overnight task and is not the responsibility of a single department. It is a systematic project that requires us to be meticulous in every link from design, smelting, 주조, 열처리, 가공, to inspection, and ensure that each link is closely connected.

Let’s implement the measures of this plan with the heart of a craftsman, persistently, and jointly forge safer, more reliable, and longer-lasting railway parts. This is not only the foundation of our enterprise but also our heavy responsibility and contribution to the national railway industry.

공급자

뤄양포뇨중공업(Luoyang Fonyo Heavy Industries), 주식회사, 1998년에 설립된 철도 주조 부품 제조업체입니다.. 우리 공장의 면적은 72,600㎡입니다., 이상으로 300 직원, 32 기술자, 포함 5 수석 엔지니어, 11 보조 엔지니어, 그리고 16 기술자. 우리의 생산 능력은 30,000 연간 톤. 현재, 우리는 주로 주조물을 생산하고 있습니다, 가공, 기관차 조립 및 조립, 철도 차량, 고속 열차, 광산 장비,풍력, 등.
우리는 CRRC에 철도 부품을 공급하고 있습니다.(이상 포함 20 CRRC의 지사 및 자회사), Gemac 엔지니어링 기계, 삼니그룹, 중공업, 등. 우리의 제품은 러시아로 수출되었습니다, 미국, 독일, 아르헨티나, 일본, 프랑스, 남아프리카, 이탈리아와 전 세계의 다른 나라들.

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