Manufacturing of mechanical shafts for aerospace: cold heading, CNC turning, and CNC machining for the aerospace industry

At LEMEC, we manufacture custom metal shafts for the aerospace sector, specializing in auxiliary and support components where dimensional accuracy, batch repeatability, and traceability are decisive.

The manufacturing of shafts for the aerospace sector is one of the most demanding processes within aerospace engineering. These components are responsible for transmitting power, withstanding extreme dynamic loads, and maintaining the stability of critical systems in engines, landing gear, or flight control mechanisms.

The selection of the right process affects not only the performance of the component, but also production efficiency, fatigue life, and cost competitiveness.

Depending on the diameter, geometry, load level, and production volume, the optimal solution may vary between cold heading with CNC machining for larger critical components, or precision CNC turning for smaller-diameter shafts equally demanding in tolerances.

What are mechanical shafts in the aerospace sector?

Mechanical shafts in aerospace are mechanical elements designed to transmit torque, withstand rotational loads, and maintain the alignment of components within complex aeronautical systems.

Based on their function and criticality level, aircraft shafts are classified into two main groups:

Shafts for critical components:

This is where failure can compromise flight safety:

Turbine engines
Main transmission systems
Flight control actuators
Landing gear
Engine auxiliary systems

Shafts for auxiliary and non-critical components:

These shafts are intended for support and comfort systems:

Hinge mechanisms in cabin doors and hatches
Compartment opening and closing systems
Seat and cabin furniture mechanisms
Wheels and ground support equipment (GSE)

Auxiliary components, although less demanding in load than critical ones, equally require high dimensional accuracy, full traceability, and EN 9100 certification. It is precisely in this segment where LEMEC specializes, offering custom metal shafts through cold heading and precision CNC turning for medium and high production runs within the aerospace sector.

Need help?

Contact our technical office and tell us about your project.

We will study your case and propose a solution to manufacture them.

Materials for manufacturing aerospace shafts

Material selection is the first critical decision in the manufacturing of an aerospace shaft, as it directly determines the manufacturing process, in-service behavior, and component service life.

Titanium Ti-6Al-4V

The most widely used option when weight is a critical variable. Its excellent strength-to-weight ratio makes it ideal for compressor shafts, actuators, and transmission systems. It responds very well to cold heading and CNC machining, although it requires specific tooling and cutting parameters due to its low thermal conductivity.

Inconel 718

A nickel-based superalloy reserved for areas subjected to high temperatures, especially shafts in turbine stages. Its creep resistance at high temperatures is irreplaceable in these environments, although its machinability is more demanding and generally requires isothermal forging as a preforming process.

300M Steel and 4340 Steel

High-strength aerospace steels are the dominant choice for landing gear shafts and high-load transmissions. They offer high toughness, excellent fatigue behavior, and are highly compatible with both cold heading and precision CNC turning for simpler geometries.

Manufacturing process for mechanical shafts in aviation

The manufacturing process for aviation shafts is defined according to the shaft diameter, the loads it must withstand, the production volume, and the required tolerances. In the aerospace industry, three main methods are used: cold heading, precision CNC turning, and CNC machining, each with a specific role within the production process.

The main processes used include:

Cold heading for aviation shafts

Cold heading is especially efficient when shafts feature changes in cross-section or larger diameters. Through plastic deformation of the material, a preform close to the final geometry is obtained, with key metallurgical advantages such as grain flow orientation, higher fatigue resistance, and lower material waste. For this reason, it is common in the batch production of structurally demanding shafts.

Precision CNC turning for smaller-diameter shafts

Precision CNC turning is the most competitive solution for smaller-diameter shafts with a defined geometry. By machining directly from bar stock using CNC automatic lathes, very tight tolerances are achieved with high repeatability and optimized costs for medium and high production runs. It is frequently used in actuators, auxiliary systems, and transmission mechanisms.

High-precision CNC machining

Aerospace CNC machining serves as the final finishing stage in both manufacturing routes. Operations such as precision turning, milling, deep drilling, or grinding allow tolerances of ±0.005 mm and surface finishes of Ra ≤ 0.4 μm to be achieved in critical areas.

Process combination: how to optimize the manufacturing of each aerospace shaft

In many aerospace programs, these technologies are combined to leverage the advantages of each. The cold heading + CNC machining route is optimal for larger shafts or high-load applications, while CNC turning + CNC machining offers maximum efficiency for smaller-diameter shafts produced in series.

Manufacturing method	Typical shaft diameter	Main advantage	Typical applications
Cold heading + CNC	Medium / large	Metallurgical improvement (grain flow) and high fatigue resistance	Structural shafts, landing gear, load-bearing components
Precision CNC turning + CNC	Small / medium	High repeatability and optimized cost in series	Actuators, transmission mechanisms, auxiliary systems
CNC machining from bar stock	Variable	Flexibility for prototypes or short runs	Development, special parts, small batches

Metal shafts for aerospace applications<br>

Metal shafts for non-critical aerospace applications: LEMEC’s specialty

Our cold heading and precision CNC turning processes, backed by EN 9100 certification, allow us to supply shafts for applications such as:

Hinge mechanisms in panels, cabin doors, and hatches
Compartment opening and closing systems
Seat and cabin furniture mechanisms
Wheels and ground support equipment (GSE)
Auxiliary systems and secondary transmission mechanisms

For these applications, we offer shafts in carbon steel, stainless steel, and aluminum, with surface treatments tailored to the requirements of each environment, and production runs ranging from a few thousand parts to several million.

If your project requires metal shafts for non-critical components within the aerospace sector, contact our technical team and we will study your case.

Standards and certifications in the manufacturing of components for the aerospace industry

The aerospace industry demands extremely rigorous standards to ensure the safety and reliability of components.

EN 9100 Certification

EN 9100 certification establishes specific requirements for quality management systems in the aerospace sector.

Special processes and Nadcap audits

Processes such as heat treatments or non-destructive testing often require Nadcap accreditation to ensure their technical conformity.

Non-destructive testing

To guarantee the integrity of the component, the following techniques are used:

Ultrasonic testing
Magnetic particle inspection
Liquid penetrant inspection
Industrial computed tomography

How to choose a supplier of mechanical components for aerospace

Selecting an EN 9100-certified aerospace component supplier requires evaluating multiple technical and industrial factors:

Quality certifications
Experience in the aerospace sector
Batch production capability
Integration of processes such as cold heading and CNC machining
Traceability and document control systems

A supplier capable of integrating several manufacturing technologies offers greater efficiency, shorter lead times, and better process control.

Precision engineering for the manufacturing of aerospace shafts

The aerospace industry demands levels of precision and reliability that can only be achieved through the integration of advanced engineering, process control, and high-precision manufacturing technologies.

The combination of metal stamping and CNC machining makes it possible to produce aerospace shafts with excellent structural integrity, high repeatability, and significant cost optimization in batch production.

Specialized suppliers such as LEMEC, capable of integrating cold heading, precision CNC turning, and CNC machining under a single quality system, can guarantee the selection of the most efficient process for each shaft and offer greater traceability control, industrial competitiveness, and reliability in aerospace applications.

Get in touch with us

Contact our technical office and tell us what kind of steel parts you need to manufacture.

We will study your case and propose a customized, fast and efficient cold stamping solution.

Preguntas frecuentes sobre fabricación de ejes aeronáuticos

¿Qué tolerancias dimensionales suelen requerir los ejes utilizados en aeronáutica?

Los ejes utilizados en aplicaciones aeronáuticas requieren tolerancias extremadamente estrictas para garantizar la estabilidad del sistema rotativo. En muchas aplicaciones críticas, las tolerancias pueden situarse alrededor de ±0.005 mm o incluso inferiores en superficies de rodamiento, acoplamientos o zonas de sellado, evitando vibraciones y asegurando una transmisión de cargas precisa durante millones de ciclos de operación.

¿Qué factores influyen en la vida a fatiga de un eje aeronáutico?

La vida a fatiga de un eje depende de varios factores clave: la calidad y microestructura del material, el proceso de fabricación utilizado, el acabado superficial final y las condiciones de carga durante el servicio. Procesos que mantienen la integridad del material, como la estampación en frío con flujo de grano orientado, pueden mejorar significativamente la resistencia a fatiga en componentes sometidos a cargas cíclicas.

¿Qué ensayos se realizan para verificar la integridad de un eje aeronáutico?

En la fabricación de componentes aeronáuticos se aplican diferentes ensayos no destructivos (NDT) para verificar la integridad del material. Entre los más utilizados se encuentran los ultrasonidos para detectar defectos internos, las partículas magnéticas para identificar grietas superficiales en aceros, los líquidos penetrantes para revelar discontinuidades superficiales y, en algunos casos, tomografía computarizada industrial para piezas de alta criticidad.

¿En qué se diferencia un eje aeronáutico de un eje industrial convencional?

Aunque ambos cumplen funciones similares de transmisión de movimiento o torque, los ejes aeronáuticos deben cumplir estándares mucho más exigentes. Esto incluye trazabilidad completa del material, tolerancias dimensionales más estrictas, controles de calidad más rigurosos y cumplimiento de normativas específicas del sector aeroespacial como EN 9100 o requisitos equivalentes de certificación aeronáutica.

¿Cómo se garantiza la trazabilidad de los materiales en componentes aeronáuticos?

La trazabilidad en la industria aeroespacial permite identificar el origen exacto del material utilizado en cada componente. Para ello se documenta el lote del material, los certificados de conformidad del proveedor, los procesos de fabricación aplicados y los resultados de inspecciones y ensayos realizados. Este sistema asegura que cada pieza pueda rastrearse a lo largo de todo su ciclo de vida.

¿Qué proveedor especializado puede fabricar ejes aeronáuticos en España?

En España existen fabricantes especializados en componentes de alta precisión para el sector aeroespacial. Empresas como LEMEC integran procesos como estampación en frío, decoletaje de precisión y mecanizado CNC bajo sistemas de calidad certificados, lo que permite seleccionar el método de fabricación más eficiente para cada eje y garantizar altos niveles de precisión, trazabilidad y fiabilidad en aplicaciones aeronáuticas.