Assembly systems solutions

Automated assembly solutions that streamline production with precision and flexibility.

Loxin designs and delivers automated assembly solutions designed to streamline manufacturing processes by replacing manual labor with robotic or mechanical components. These solutions have become increasingly popular in various industries due to their potential to improve efficiency, quality, and cost-effectiveness.

Using robotic arms, robotic platforms, conveyors, feeding systems, and other automation devices in conjunction with inspection and control systems, assembly systems benefit of:

  • Increased efficiency: Automated systems can operate 24/7 without fatigue, leading to higher production rates.
  • Improved quality: Robots can perform tasks with greater precision and consistency than humans, resulting in fewer defects.
  • Reduced costs: Automation can lower labor costs and reduce waste.
  • Enhanced safety: Automated systems can eliminate dangerous tasks that pose risks to human workers.
  • Flexibility: Many automated systems can be easily reconfigured to accommodate changes in product design or production volume.


Automated assembly systems are used in a wide range of industries, including:

  • Automotive: Manufacturing of engines, transmissions, and other components.
  • Electronics: Assembly of printed circuit boards, smartphones, and other devices.
  • Aerospace: Production of aircraft parts and components.
  • Pharmaceutical: Packaging of drugs and medical devices.
  • Food and beverage: Packaging and processing of food and beverages.


Our assembly systems can be configured in standalone cells, assembly lines or as Flexible manufacturing systems (FMS).

In conclusion, automated assembly cells and systems offer significant benefits to manufacturers across various industries. By leveraging these technologies, companies can improve their efficiency, quality, and competitiveness in today’s global marketplace.

Some examples of assembly systems solutions delivered by LOXIN:

Wing Trailing Edge automated assembly cells

In a traditional wing trailing Edge assembly, a considerable amount of manual work takes place within the confined space of the closed wing box, both during the structural assembly and subsequent systems installation.  Our designs aim to eliminate manual work by automating trailing Edge assembly operations.

  1. Three complex independent 6-DOF manipulators managed by external metrology equipment is capable of sub-millimeter accuracy when controlling the defined insertion path of the trailing Edge parts
  2. The path of each section can be controlled individually, or in coordination within the overall insertion path. Force sensors ensure that the components are not stressed, and no collisions happen.
  3. Only the final manual locking is left to the operator.

Marry-up cells

The term “marrying up cells” in aeronautical engineering typically refers to the process of joining or integrating different components or systems within an aircraft. This can involve anything from connecting structural elements to integrating electronic systems. The marry-up automated process can be applied to:

  • Structural assembly: Joining individual components like ribs, spars, and skin panels to form larger structural sections of the aircraft. This often involves techniques such as riveting, bolting, or bonding.
  • System integration: Connecting various systems, such as the electrical, hydraulic, and fuel systems, to ensure they function together seamlessly. This involves careful design and installation of wiring, tubing, and other components.
  • Avionics integration: Connecting and configuring various avionics systems, including flight controls, navigation equipment, communication systems, and displays. This often involves complex software and hardware integration.
  • Engine integration: Connecting the engine to the aircraft’s structure and systems, including the propeller or fan, fuel lines, and exhaust system. This requires precise alignment and sealing to ensure efficient and safe operation.


In essence, “marrying up cells” is a critical process in aircraft manufacturing that requires careful planning, precision, and attention to detail. It ensures that the aircraft’s components are properly connected and integrated, resulting in a safe, reliable, and efficient machine.

Rebar Grid automated assembly cells

Rebar grids are a common reinforcement technique used in construction, particularly in concrete structures. They consist of steel bars (rebar) arranged in a grid-like pattern, providing structural integrity and strength to the concrete.

The process of creating a Rebar Grid

  1. Rebar selection: The appropriate diameter and type of rebar are chosen based on the design requirements and load-bearing capacity needed for the structure.
  2. Grid layout: The desired grid geometry is determined, considering factors such as spacing between bars, overall dimensions, and the specific application.
  3. Rebar cutting: The rebar is cut to the required lengths using a rebar cutter.
  4. Grid assembly: The cut rebar pieces are arranged in the specified pattern and secured together. This is done using an automated rebar arrangement cell designed by Loxin, which automates deploying rebars in the proper geometry.
  5. Tie wire: Tie wire is used to bind the rebar together at the intersections of the grid. This ensures that the grid remains intact during the concrete pouring process. Loxin provides both a tool for assisted tying assisted in manual process, or a robotic solution with a tying head.
  6. Inspection: The assembled rebar grid is inspected to verify that it meets the design specifications and is free of defects.

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