• Documentation Production: We craft classification documentation using specialized software. This includes plans, arrangements, drafts, calculations, and the like.
• Workshop Documentation: Comprehensive creation of workshop documentation to guide and streamline the production process.
• Design & Construction Solutions Collaboration: We work in harmony with other disciplines, covering all phases of design and crafting contractual, project, and workshop documentation.
• Commitment to Standards: Execution of business obligations on time and in accordance with applicable standards.
• Specific Equipment Design & Modeling: Our design and 3D modeling encompasses, but is not limited to, the following:

  • Shafts, gears, rollers, bearings, and heavy-duty frames

  • Casings, protective guards, and lightweight structural components

  • Small wind turbine towers, oil and gas pipelines, and storage tanks

  • Solar panel frames and certain components of renewable energy systems

  • Frames of mobility aids (like wheelchairs), certain medical instruments, and casings for medical equipment

  • Structural components of carriages, train body structures and interior components.

Leveraging state-of-the-art technology to analyze various load and stress scenarios on mechanical components

• Impact Loads: Assessing the effects and responses of structures to sudden loads.
• Brake Torque Loads: Evaluating the forces and potential issues arising from braking mechanisms.
• Assembly Process: Ensuring optimal assembly strategies and identifying potential challenges.
• Interferences: Analyzing and resolving overlapping or conflicting components in assembly designs.
• Bolt Sizing: Determining the appropriate size and type of bolts required for specific applications.
• Preloads: Calculating and suggesting the necessary preload forces for bolts and other fastening components.
• etc…

Utilizing advanced computational methods to study heat transfer and thermal stresses in materials and structures.

• Steady-State Analysis: Determining temperature distributions, heat flows, and gradients under steady conditions.
• Transient Thermal Analysis: Evaluating how temperature fields evolve over time in response to changing conditions.
• Conduction, Convection, and Radiation: Assessing all modes of heat transfer to ensure comprehensive thermal simulations.
• Thermal-Structural Interactions: Understanding how thermal changes can induce stresses or deformations in structures.
• Material Property Variations: Incorporating temperature-dependent properties to capture real-world behavior accurately.
• Thermal Fatigue: Predicting the life and durability of materials and components under cyclic thermal loads.
• etc…