PCB Prototype the Easy Way

Full feature custom PCB prototype service.


Robotics Industry is the Technology of the Future

Online instant pricing & Free DFM
Rapid prototype as far as 2 days
Tight tolerance control into +/- 0.01mm
Bosch HP tesla foxconn

We provide unrivaled speed and efficiency for robotics industry prototyping and production.

Powerful Capabilities

Powerful Capabilities

Our powerful manufacturing capabilities are the cornerstone of our success.

Instant Quotation

Instant Quotation

Get accurate and timely quotes with our innovative instant quotation system.

High Precision Parts

High Precision Parts

Our advanced manufacturing techniques and cutting-edge technology allow us to produce intricate.

Fast Cycle Time

Fast Cycle Time

At PCBWay, we pride ourselves on delivering fast cycle times that keep you ahead of the competition.

Production Verification Test
Mass production


Accelerate early design turnaround with a variety of 3D printing and vacuum casting options.

Rapid Pototype
Consumer Electronics Parts Application

Robotics Parts Applications

Rapid prototyping
3D printing, CNC machining, to verify the feasibility of new designs.
Supply of production accessories
Volume manufacturing support

Cooperation With the Top Robotics Companies Worldwide

From custom designs to unique color and material options, PCBWay’s innovative manufacturing model gives you an advanced competitive edge.

  • Industrial robot arm
  • Smart home robot
  • AI Robot
  • Robotics reducer
  • Robotics controller
  • Robotics servo system
  • STEAM educational robot
  • Robotics vision communication system
  • Medical robot
  • Cloud computing processing robot
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Robotics Companies

Unleashing Our
Company's Strengths

  • Technologies
    52 & 4

    Partner Network & Industrial Base

  • EMS
    1,682,560 +

    Parts & Prototypes Produced

  • Passionate Employees
    100 +

    Materials and Finishings

PCBWay is a one-stop solution platform from prototyping, R&D to mass production. Utilizing our instant quoting platform and comprehensive supplier network, you can quickly obtain design validation and accelerate your product launch.

Production capacity

Industry certifications including ISO 9001, IATF16949

Strict quality control

Provide professional quality inspection report

  • Standard Inspection with Formal Report
  • CMM Inspection with Formal Report
  • Source Material Certification

Instant quote online

The online order page provides different parameters and processes to get a quote quickly

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Recognized by Many Large Enterprises

  • Consumer electronics companies
  • Personal and household products manufacturers
  • Automobile OEMs
  • Automotive Part Companies
  • Aircraft OEMs
  • Commercial aviation companies
  • Healthcare providers
  • Diagnostics equipment manufacturers
  • Industrial robot manufacturers
  • Heavy Machinery Manufacturers

Gallery of Robotics Parts


What are some other factors that are considered when selecting materials for robot components?

When selecting materials for robot components, several factors are considered. Apart from specific properties like strength, durability, and corrosion resistance, cost-effectiveness and compatibility with the manufacturing process are taken into account. The operating environment, weight, and mass distribution, as well as mechanical properties such as flexibility and impact resistance, are also important considerations. Electrical conductivity or insulation, compatibility with joining methods, and compliance with regulatory and safety standards play a role in material selection. Additionally, the availability and stability of the material's supply chain are considered. By considering these factors, materials can be chosen that meet the functional requirements, durability, performance, and cost-effectiveness for robot components in diverse applications.

In the robot industry, what metal or plastic materials are generally used?


Aluminum: Aluminum alloys are widely used in robotics due to their lightweight, high strength-to-weight ratio, and good corrosion resistance.

Steel: Steel is chosen for its strength, durability, and toughness, especially for structural components and gears.

Titanium: Titanium alloys offer a high strength-to-weight ratio, excellent corrosion resistance, and biocompatibility, making them suitable for advanced robotic applications.

Copper: Copper is utilized for its excellent electrical conductivity, making it useful for electrical components and wiring in robots.

Magnesium: Magnesium alloys are lightweight and have good mechanical properties, making them suitable for weight-sensitive robot parts.


ABS (Acrylonitrile Butadiene Styrene): ABS is a commonly used thermoplastic known for its impact resistance and durability. It is often used for robot housing and structural components.

Polycarbonate (PC): PC is a tough, transparent plastic that offers good impact resistance and high temperature resistance. It is used for robot covers and protective shields.

Nylon:Nylon, or polyamide, is valued for its strength, flexibility, and wear resistance. It is used for gears, bearings, and flexible components in robots.

Polypropylene (PP): PP is a lightweight and chemical-resistant plastic. It finds applications in robot casings and components requiring chemical resistance.

Polyethylene (PE): PE is a versatile plastic with good chemical resistance and low friction properties. It is used for various robot components, including cables and connectors.

What are the innovative applications of 3D printing in the robotics industry?


CNC machining and 3D printing have a wide range of applications in the healthcare industry. In terms of CNC machining, it is used for manufacturing medical instruments and equipment components with high precision, ensuring accuracy and reliability. It is also employed in the production of implants, such as artificial joints, bone plates, and screws, allowing for precise cutting and shaping of metal and alloy materials to meet personalized implant requirements. CNC machining is further utilized for rapid prototyping of medical devices, enabling design validation, functional testing, and iterative improvements. Additionally, it facilitates customized production of medical instruments and devices, including prosthetics and orthopedic appliances, tailored to individual patient needs.

As for 3D printing, it finds applications in the rapid prototyping of medical instruments and devices, accelerating product development and refinement processes. It is particularly suitable for the production of customized implants, where it allows for the creation of personalized implants based on patients' anatomical structures and requirements, such as artificial joints, dental implants, and prosthetics. Furthermore, 3D printing technology is used to manufacture highly realistic medical models, utilized for surgical simulations, medical education, and training, enhancing the skills and knowledge of healthcare professionals. It also enables the production of medical aids like orthotics, supports, and transparent aligners.


3D printing has several applications in the robotics industry. It can be used to quickly prototype and model robots to verify design and functionality. In addition, 3D printing can also manufacture robot parts with complex shapes, such as lightweight structures and hollow structures, to improve the performance and efficiency of robots. 3D printing also supports personalized customization, which can manufacture robot components and shells according to specific needs.


3D printing has numerous innovative applications in the robotics industry. It can be used to manufacture robot exoskeletons, providing rehabilitation, mobility assistance, and human-robot collaboration. Custom-made exoskeleton structures, lightweight and comfortable, can be created using 3D printing technology, tailored to individual dimensions and requirements.

Furthermore, 3D printing enables the production of flexible and elastic robot components such as sensors, joints, and grippers. These components enhance the adaptability and operational capabilities of robots in complex environments. The flexibility of 3D printing also allows for the manufacturing of intricate structures and internal channels, offering design flexibility and integration of functionalities.

Another innovative application is the ability to combine multiple materials within a single printed component. In the robotics field, this means incorporating different properties and functions, such as hardness, elasticity, and conductivity, into a single part. This opens up opportunities for multifunctional and multitasking operations of robots.

Additionally, 3D printing facilitates rapid prototyping and customized development in the robotics industry. It accelerates the production of robot prototypes and customized parts, speeding up the product development and testing processes. Designers and researchers can iterate and optimize designs more quickly, meeting specific application needs.

Wearable robotics is another area where 3D printing shines. It enables the manufacturing of lightweight and ergonomic wearable robot components. Through 3D printing, personalized wearable robot parts can be custom-made to fit individual body structures and movements, providing functions such as human augmentation, walking assistance, and rehabilitation training.

These innovative applications of 3D printing showcase its potential in the robotics industry, offering design flexibility, performance optimization, and personalized applications. As technology continues to advance, we can expect more exciting and groundbreaking applications to emerge.

What are the applications of 3D printing in the robotics industry?

3D printing has several applications in the robotics industry. It can be used to quickly prototype and model robots to verify design and functionality. In addition, 3D printing can also manufacture robot parts with complex shapes, such as lightweight structures and hollow structures, to improve the performance and efficiency of robots. 3D printing also supports personalized customization, which can manufacture robot components and shells according to specific needs.



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