CGTech List of Products and Services

CGTech has released the latest version 9.5 of the Vericut software in Japanese! Vericut is the industry leader in machine simulation, verification, and optimization for various types of CNC machining, additive, and hybrid manufacturing processes. While Vericut operates as a standalone application, it supports integration with major CAM and tool management systems. In addition to improvements in the core aspects of the product, 'Vericut V9.5' focuses on enhancing connectivity across the entire manufacturing workflow, enabling organizations to do more with the resources they already have. 【Vericut V9.5 Highlights】 ■ Efficient optimization ■ Improvements to VERICUT Reviewer files ■ Enhanced tool data ■ New ToolsUnited interface *For more details, please refer to the PDF materials or feel free to contact us.

By using the CNC simulation software Vericut, you can simulate machining parts on your PC before actually processing them with a machine. This helps prevent errors, mistakes, and human errors that could lead to damage to machines, parts (workpieces), jigs, and tools, as well as accidents with machine tools. Additionally, not only does it prevent errors and mistakes, but by using the NC program optimization module (feed rate optimization), you can shorten the machining cycle time and improve machining efficiency. Furthermore, Vericut offers many convenient features, such as precise part measurement using the cutting model after simulation and support for creating various reports like inspection sheets and machining instructions. Vericut has a modular licensing management system, providing flexibility for implementation. You can purchase the necessary functions (modules) in the required quantities. Even after implementing Vericut, you can easily add modules by purchasing the necessary modules and simply adding the license file.

Would you like to solve the problems of CNC machining? Non-functioning machines, damaged tools, expensive collision issues, discarded parts, prolonged test runs, wasted materials... These problems take away valuable time and costs. Vericut ensures machining accuracy by simulating the entire CNC machining process. It derives the "correct" result in a single machining operation.

Optimization of Force significantly reduces machining time. Vericut Force creates effective NC programs for the given materials, cutting tools, and machining conditions. As a result, it saves a considerable amount of time and improves the lifespan of cutting tools and machines. With the optimization of Force, machining time is greatly reduced, and tool life is significantly extended. By analyzing with Vericut Force, programmers can quickly and easily visualize what happens in the NC program for each cut when the tool contacts the material. Using Vericut Force, underutilized cutting conditions, overloads, cutting removal rates, output, torque, and tool deflection can be clearly observed. With one click, a review of the NC program and visual analysis in the graphic review window is provided. This analysis offers a view of the machining before running the NC program on the actual machine. Vericut Force provides users with proactive analysis of NC programs.

**Main Benefits of Vericut Optimizer** Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. Even if you are satisfied with your current CAM verification software and have no intention of purchasing Vericut, Vericut Optimizer is the optimal choice.

The main benefits of the Vericut Icam post are that Icam's CNC post-processor enables smooth integration with existing CAD systems and CNC machines, maximizing the efficiency and accuracy of the manufacturing process. This reduces cumbersome tasks and enhances productivity.

With Vericut's additive module, you can simulate hybrid composite processing. The Vericut additive module accurately simulates additive manufacturing (layered construction) and traditional subtractive processing (machining) in hybrid composite processing.

This document introduces cases where work efficiency has been improved by implementing "Vericut." By using the NC simulation software "Vericut," it is possible to simulate the cutting of parts on a PC before actual processing, thereby eliminating mistakes that could lead to damage of machine parts, jigs, tools, or accidents with machine tools. If you are seriously considering preventing troubles at the processing site, please consider implementing "Vericut." [Featured Cases (Excerpt)] - Railway Vehicle Manufacturing: Kawasaki Heavy Industries, Ltd. - Tools: Tungaloy Corporation - Machine Tools: Makino Milling Machine Co., Ltd. - Cast and Forged Steel Products: Kobe Steel, Ltd. - Prototype Processing: HILLTOP Corporation *For more details, please refer to the PDF document or feel free to contact us.

CGTech Releases the Latest Japanese Version of Vericut Software – Version 9.6! Vericut is the industry leader in machine simulation, verification, and optimization for various types of CNC machining, additive, and hybrid manufacturing processes. While Vericut operates as a standalone application, it also supports integration with major CAM and tool management systems. In addition to core product enhancements, Vericut V9.6 introduces two groundbreaking AI-powered features: ･ Vericut Assistant provides integrated AI support within the Vericut software. ･ Vericut Intelligence offers an easily accessible and user-friendly intelligent knowledge hub for Vericut. Highlights of Vericut V9.6: ･ AI Integration Features ･ Enhanced Reviewer Functionality ･ Support for PMI (Product Manufacturing Information) For more details, please refer to the PDF document or feel free to contact us.

In the aerospace industry, the precision of part machining is extremely important to ensure the safety and reliability of aircraft. In particular, accurate manufacturing without machining errors is required for structural and engine components of aircraft. Vericut 9.6 addresses these challenges by simulating machine tools using G-code NC programs and detecting collisions and machining defects in advance. Vericut supports a wide variety of machine tools, including multi-axis machining such as high-efficiency, high-precision 5-axis machining, as well as lathes, composite machines, and multi-surface machining machines. 【Use Cases】 * Manufacturing of aircraft parts * Machining of complex shapes with high collision risk * Machining of parts requiring high precision 【Benefits of Implementation】 * Reduction of machining errors * Improvement of aircraft safety * Reduction of manufacturing costs

In the automotive industry, there is a demand for the efficient manufacturing of high-quality parts. Particularly for parts with complex shapes or those requiring high precision, reducing machining time and improving quality are important challenges. Vericut 9.6 addresses these challenges by performing machining simulations using G-code NC programs. Its AI integration feature optimizes the machining process and contributes to increased productivity. 【Use Cases】 - Reducing machining time in the prototyping and mass production of automotive parts - Efficient manufacturing of complex-shaped parts through multi-axis machining - Reducing machining defects and improving quality 【Benefits of Implementation】 - Maximizing machining time - Extending tool life - Improving machining precision

In the mold industry, there is a constant demand for improving the precision of molds, which directly affects product quality. Particularly for molds that require complex shapes and high precision, reducing machining errors is crucial. Vericut 9.6 conducts machining simulations using G-code NC programs, contributing to the improvement of mold machining accuracy through pre-inspection of overcutting/undercutting by comparing cutting models with design models, and optimizing NC programs considering tool load. 【Usage Scenarios】 - High-precision mold machining - Complex shape mold machining - Multi-axis machining 【Benefits of Implementation】 - Improved machining accuracy - Reduction of defective products - Shortened machining time

In the machine tool industry, improving product quality and productivity is always a critical issue. Particularly in parts processing that requires complex shapes and high precision, optimizing machining programs and validating them through machining simulations is essential. Inadequate programs or insufficient validation can lead to processing defects or machine damage. CGTech's Vericut 9.6 conducts simulations with G-code NC programs and supports performance evaluation for multi-axis machining, including high-precision 5-axis processing. 【Usage Scenarios】 - Performance evaluation of machine tools - Validation of machining programs - Reduction of machining time - Reduction of processing defects 【Benefits of Implementation】 - Improvement in processing quality - Increase in productivity - Cost reduction - Improvement in machine utilization rate

In the defense sector, maintaining a high level of confidentiality while ensuring product quality is the top priority. Particularly in the machining of parts with complex shapes, the accuracy of NC programs is essential. Errors in the program can lead to leaks of confidential information or degradation of product performance. CGTech's Vericut 9.6 aims to faithfully simulate G-code NC programs, enhancing machining accuracy while protecting confidential information. 【Usage Scenarios】 * Machining of highly confidential parts * Use of multi-axis machining centers * Manufacturing of parts with complex shapes 【Benefits of Implementation】 * Reduced risk of information leakage through verification of G-code NC programs * Cost reduction through optimization of machining time * Improved quality through comparison of cutting models and design models

In the energy industry, there is a demand for the optimization of manufacturing processes and improvement of quality. Particularly in the precision machining of components such as turbines and generators, high accuracy and reliability are essential. Vericut 9.6 performs simulations with G-code NC programs, achieving optimization and efficiency in machining. With AI support features and an intelligent knowledge hub, it streamlines the machining process and contributes to improved energy efficiency. 【Use Cases】 * Machining of turbine blades * Manufacturing of generator components * Multi-axis machining of high-precision parts 【Benefits of Implementation】 * Reduction in machining time * Extension of tool life * Improvement in quality

In the medical device industry, the safety and reliability of products are the top priorities. CNC-machined medical device parts require high precision and quality, as they directly impact patient safety. Even a slight mistake in machining can lead to product malfunction or risks to patients. Vericut 9.6 reduces these risks by simulating G-code NC programs at the stage of machining to verify accuracy. 【Usage Scenarios】 - Safety verification in CNC machining of medical device parts - Interference checks in machining complex-shaped parts - Cost reduction through optimization of machining time 【Benefits of Implementation】 - Improved product reliability by reducing machining errors - Shortened development time by reducing the number of prototypes - Mitigation of cost increases due to machining defects

In the electronics industry, there is a demand for miniaturization of products and high-precision processing. In particular, optimizing processing is essential to achieve complex shapes within limited space. If processing precision is low, it may lead to a decline in product performance and a deterioration in yield. Vericut 9.6 supports high-precision product manufacturing by optimizing processing steps through AI-driven simulation. 【Use Cases】 - Processing of enclosures for small electronic devices - Manufacturing of precision parts - Achieving complex shapes through multi-axis processing 【Benefits of Implementation】 - Reduction in processing time - Decrease in defective products - Improvement in product accuracy

In the heavy industry sector, the durability and reliability of products are the most important issues. To manufacture products that can withstand use in harsh environments, improving machining accuracy is essential. Vericut 9.6 supports the optimization of machining and quality improvement by simulating machine tools using G-code NC programs. This contributes to enhancing product durability. 【Application Scenarios】 * Machining of large machine parts * Manufacturing of parts requiring high precision * Multi-axis machining and complex processing 【Effects of Implementation】 * Reduction in machining time * Extension of tool life * Improvement in product quality

In the shipbuilding industry, as the trend towards larger sizes continues, the precision of parts and processing efficiency are becoming increasingly important. Particularly in the manufacturing of massive structures, even slight errors can significantly impact the overall quality. Vericut 9.6 enhances processing accuracy by faithfully simulating G-code NC programs and reduces unnecessary processes. It also features AI support functions to assist in optimizing complex machining processes. 【Usage Scenarios】 - Machining of large ship parts - Machining of complex-shaped parts - Utilization of multi-axis machining machines 【Effects of Implementation】 - Reduction in processing time - Decrease in defective products - Cost reduction

In the watch manufacturing industry, there is a demand for the efficient production of high-quality watch components. Particularly for parts that require complex shapes and fine processing, balancing machining accuracy and productivity is crucial. Machining defects and process delays can lead to a decline in product quality and increased costs. Vericut 9.6 addresses these challenges through AI-powered simulation and optimization features. 【Usage Scenarios】 - Machining of complex-shaped watch components - Optimization of tool paths in fine processing - Simulation of multi-axis machining 【Benefits of Implementation】 - Reduction in machining time - Improvement in machining accuracy - Extension of tool life - Reduction of defective products

In the aerospace industry, there is a trend towards increasing complexity and high quality of parts, which demands a reduction in processing time and effective use of materials. Particularly for parts that use expensive materials and require high precision, optimizing NC programs is crucial. Inappropriate NC programs can lead to increased processing time, premature tool wear, and material waste. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. It optimizes NC programs output from CAM systems, enhancing processing efficiency. 【Usage Scenarios】 - Manufacturing aerospace components - Manufacturing parts that require high-precision machining - Multi-axis machining (3-axis, 4-axis, 5-axis) 【Benefits of Implementation】 - Reduction in processing time - Decrease in material waste - Extension of tool life - Acceleration of time-to-market for parts

In the aerospace industry, there is a trend towards increasing complexity and high quality of parts, which demands a reduction in processing time and effective use of materials. Particularly for parts that use expensive materials and require high precision, optimizing NC programs is crucial. Inappropriate NC programs can lead to increased processing time, premature tool wear, and material waste. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. It optimizes NC programs output from CAM systems, improving processing efficiency. 【Usage Scenarios】 - Manufacturing aerospace components - Manufacturing parts that require high-precision processing - Multi-axis machining (3-axis, 4-axis, 5-axis) 【Benefits of Implementation】 - Reduction in processing time - Decrease in material waste - Extension of tool life - Acceleration of time-to-market for parts

In the automotive industry, there is a constant demand for shortening product development cycles and reducing costs. In particular, optimizing NC programs during the prototyping and mass production stages is essential for reducing machining time, minimizing material waste, and enabling early market entry of parts. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. This allows for the streamlining of NC programs without changing the existing CAM environment, contributing to enhanced competitiveness in automotive parts manufacturing. 【Usage Scenarios】 - Optimization of NC programs in the prototyping and mass production of automotive parts - Cost reduction through shortened machining time - Minimization of material waste 【Effects of Implementation】 - Reduction in machining time - Decrease in material costs - Shortened time to market for parts

In the mold industry, high-precision processing that affects product quality is essential. Particularly for molds that require complex shapes and fine processing, optimizing NC programs becomes crucial. Inappropriate NC programs can lead to decreased processing accuracy, tool damage, and increased processing time. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. It optimizes NC programs output from CAM systems, achieving improved accuracy and efficiency in mold processing. 【Usage Scenarios】 - High-precision mold processing - Processing of complex shapes - Multi-axis processing (3-axis, 4-axis, 5-axis) 【Benefits of Implementation】 - Improved processing accuracy - Extended tool life - Reduced processing time - Decreased material waste

In the medical device industry, the safety and reliability of products are the top priorities. Deficiencies in NC programs can lead to processing defects and equipment malfunctions, potentially jeopardizing patient safety. The Vericut Optimizer enhances processing accuracy and reduces potential risks by optimizing NC programs. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. Even if you are satisfied with your current CAM verification software and have no intention of purchasing Vericut, the Vericut Optimizer is the optimal choice. 【Usage Scenarios】 - Manufacturing of medical device parts - Processing of implants and surgical instruments - Improvement of quality control and safety 【Benefits of Implementation】 - Improved processing accuracy - Reduction of defective products - Assurance of patient safety

In the energy industry, efficiency and quality in the manufacturing of components are crucial. Particularly for high-precision parts used in power generation equipment and plants, there is a demand for reduced processing time and improved quality. Optimizing NC programs addresses these challenges and contributes to cost reduction and enhanced product reliability. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. Even if you are satisfied with your CAM verification software, the Vericut Optimizer is the optimal choice. 【Use Cases】 - Machining of power generation turbine blades - Manufacturing of plant equipment components - Production of renewable energy-related parts 【Benefits of Implementation】 - Reduction in processing time - Minimization of material waste - Improvement in component quality - Cost reduction

In the machine tool industry, there is always a demand for reducing machining time and extending tool life. Particularly in the machining of complex-shaped parts, optimizing NC programs is essential for improving productivity. Inappropriate NC programs can lead to increased machining time and premature tool wear. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. This significantly improves machining efficiency, reduces material waste, and accelerates the time to market for parts. 【Usage Scenarios】 * Multi-axis machining (3-axis, 4-axis, 5-axis) 【Benefits of Implementation】 * Reduction in machining time * Extension of tool life * Reduction of material waste

In the precision machinery industry, the miniaturization and high precision of products are advancing, making the optimization of NC programs crucial. Particularly in micro-machining, there is a demand for reduced processing time, extended tool life, and high machining accuracy. Inappropriate NC programs can lead to machining defects and premature tool wear, potentially resulting in decreased productivity. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. It optimizes NC programs output from CAM systems, improves machining efficiency, reduces material waste, and accelerates the time to market for parts. 【Usage Scenarios】 - Manufacturing of micro-machined parts - Manufacturing of parts requiring high precision machining - Manufacturing of complex-shaped parts through multi-axis machining 【Benefits of Implementation】 - Reduction of processing time - Extension of tool life - Improvement of machining accuracy - Reduction of material waste

In the electronics industry, there is a simultaneous demand for miniaturization and high performance of products. Therefore, optimizing NC programs to reduce processing time, minimize material waste, and enable rapid market introduction of components is crucial. The Vericut Optimizer addresses these challenges. 【Usage Scenarios】 * Precision machining of small electronic components * Manufacturing of complex-shaped parts through multi-axis machining * Efficiency improvement of NC programs in prototyping and mass production 【Benefits of Implementation】 * Reduction in processing time * Decrease in material costs * Shortening of product market introduction time

In the shipbuilding industry, there is a demand for the efficiency of NC programs in the processing of large structures. Particularly in the processing of large components, reducing processing time, minimizing material waste, and improving accuracy are crucial. The Vericut Optimizer optimizes NC programs without using Vericut, addressing these challenges. 【Usage Scenarios】 - Processing of large hull blocks - Machining of complex-shaped components - Efficiency improvements through multi-axis machining 【Benefits of Implementation】 - Reduction in processing time - Minimization of material waste - Acceleration of time-to-market for components

In the heavy industry sector, the long-term reliability and safety of products are the top priorities. To manufacture products that can withstand harsh environments, it is necessary to balance processing accuracy and durability. Optimizing NC programs contributes to reducing processing time, extending tool life, and improving product quality, ultimately leading to enhanced product durability. The Vericut Optimizer addresses these challenges without changing the existing CAM environment. 【Use Cases】 - Machining of parts subjected to high loads - Manufacturing of products that can withstand long-term use - Machining of parts that require strict quality standards 【Benefits of Implementation】 - Cost reduction through shorter processing times - Cost reduction through extended tool life - Improvement in product quality - Reduction in defective products

In the watch manufacturing industry, there is a demand for the efficient production of high-quality products. Particularly for watch components where design is emphasized, machining precision and surface finishing are crucial. The optimization of NC programs is essential for enhancing these elements. The Vericut Optimizer is an NC program optimization solution that can operate independently without using Vericut. It supports the reduction of machining time, the minimization of material waste, and the realization of high-quality products in the watch manufacturing field. 【Usage Scenarios】 - Machining of high-precision watch components - Manufacturing of complex-shaped parts - Efficiency improvement through multi-axis machining 【Benefits of Implementation】 - Reduction of machining time - Minimization of material waste - Realization of high-quality products

In the aerospace industry, high-quality components and efficient manufacturing processes are essential. In particular, parts related to aircraft safety require high precision and reliability. The Vericut Icam post-processor optimizes data conversion between CAM systems and CNC machines, improving machining accuracy. This contributes to the reduction of defective products, cost savings, and shorter delivery times. 【Usage Scenarios】 - Manufacturing of aircraft components - Machining of complex-shaped parts - Production of parts requiring high precision 【Benefits of Implementation】 - Improved machining accuracy - Reduction of defective products - Decreased manufacturing costs - Shortened delivery times

In the automotive industry, there is a demand for the efficient manufacturing of high-quality parts. The precision and efficiency of CNC machining are directly linked to product quality and productivity. The Icam post-processor enables smooth integration between existing CAD/CAM systems and CNC machines, maximizing the efficiency and accuracy of the manufacturing process. This reduces cumbersome tasks and enhances productivity. 【Usage Scenarios】 - CNC machining of automotive parts - Reduction of machining time - Streamlining of process management 【Effects of Implementation】 - Optimization of machining time - Reduction of defective products - Improvement of productivity

In the mold industry, the precision and reliability of CNC machining are crucial for quality assurance. Since molds require high precision, even slight errors can significantly impact product quality. The Vericut Icam post-processor maximizes the efficiency and accuracy of the machining process through smooth integration with existing CAD systems and CNC machines, helping to address challenges in quality assurance. 【Usage Scenarios】 - Verification of NC programs in mold machining - Quality confirmation through machining simulation - Optimization of machining time 【Benefits of Implementation】 - Reduction of machining defects - Stabilization of quality - Cost reduction

In the medical device industry, the safety and reliability of products are the top priorities. In CNC machining, precise processing according to design is required, and even slight errors are not tolerated. Inaccurate machining can lead to product malfunctions and risks to patients. The Vericut Icam post-processor improves the accuracy of CNC machining and ensures the safety of medical devices. 【Application Scenarios】 - Manufacturing of medical devices such as implants and surgical instruments that require high precision - Machining of medical parts with complex shapes - Reducing risks associated with errors in CNC programs 【Benefits of Implementation】 - Improved product quality due to enhanced machining accuracy - Reduction of rework and reprocessing due to errors - Ensuring patient safety

In the energy industry, high precision and efficiency are required in the manufacturing of components that support critical infrastructure such as power generation equipment and transmission networks. Particularly for components used in harsh environments, the accuracy of processing affects the reliability of the products. The Vericut Icam post-processor addresses these challenges through the optimization of CNC machining. 【Application Scenarios】 - Manufacturing of turbine blades, pump components, valves, etc. - Precision machining using CNC machine tools - Quality control and cost reduction 【Benefits of Implementation】 - Reduction in processing time - Decrease in defective products - Improvement in productivity

In the machine tool industry, the compatibility between various CAM systems and CNC machines is a crucial factor that influences the efficiency and precision of the machining process. Due to the challenges of data conversion between different systems and the need for customization to match the characteristics of CNC machines, the introduction of an optimal post-processor is required. The Vericut Icam post-processor addresses these challenges and enables the optimization of CNC machining. 【Usage Scenarios】 - Companies using various CAM systems and CNC machines - Companies wanting to perform optimal code conversion for each type of CNC machine - Companies aiming to improve machining accuracy by utilizing digital twins 【Benefits of Implementation】 - Smooth integration between CAM systems and CNC machines - Improved machining accuracy through customization tailored to the characteristics of CNC machines - Machining simulation and optimization using digital twins

In the semiconductor manufacturing industry, high precision and efficiency in microfabrication are required to enhance product quality and improve yield. Particularly in the processing of parts with complex shapes and fine structures, the accuracy of NC programs is crucial. Inaccurate programs can lead to defective products and increased processing time. The Vericut Icam post-processor enables smooth integration with existing CAD systems and CNC machines, maximizing the efficiency and accuracy of the manufacturing process. This reduces cumbersome tasks and improves productivity. 【Usage Scenarios】 - Manufacturing of microfabricated parts - Processing of complex-shaped parts - Multi-axis machining 【Effects of Implementation】 - Reduction in processing time - Decrease in defective products - Improvement in productivity

In the shipbuilding industry, the precision and efficiency of CNC machining are crucial for the manufacturing of large structures. Particularly in the processing of hulls and large components, accurate NC programs capable of handling complex shapes and large sizes are required. Inaccurate code can lead to defective parts and increased manufacturing time. The Vericut Icam post-processor enables smooth integration with existing CAD systems and CNC machines, maximizing the efficiency and accuracy of the manufacturing process. This reduces cumbersome tasks and enhances productivity. 【Usage Scenarios】 - CNC machining of large hull components - Machining of complex-shaped parts - Utilization of multi-axis machining machines 【Effects of Implementation】 - Reduction of machining time - Decrease in defective products - Improvement in productivity

In the precision machinery industry, there is a demand for high precision in products and a reduction in manufacturing lead times. Particularly in the machining of complex-shaped parts, the optimization of NC programs is essential for balancing quality and productivity. Inadequate NC programs can lead to increased machining time and a decrease in product accuracy. The Vericut Icam post-processor enables smooth integration with existing CAD systems and CNC machines, maximizing the efficiency and precision of the manufacturing process. This reduces cumbersome tasks and enhances productivity. 【Usage Scenarios】 - High-speed, high-precision machining of precision parts - Machining of complex-shaped parts - Small-batch production of various types 【Effects of Implementation】 - Reduction in machining time - Improvement in product accuracy - Reduction of in-process defects

In the robotics industry, efficient manufacturing through the collaboration of CNC machining and robots is required. Particularly in the processing of complex-shaped parts and in low-volume, high-variety production, the accuracy of CNC programs and smooth data integration with robots are crucial. Inadequate programming or data integration can lead to processing errors and delays in the workflow. The Vericut Icam post-processor enables seamless integration with existing CAD systems and CNC machines, maximizing the efficiency and accuracy of the manufacturing process. This reduces cumbersome tasks and enhances productivity. 【Usage Scenarios】 - Transporting and processing parts with robots - Data integration between CNC machines and robots - Automation of processes in low-volume, high-variety production 【Benefits of Implementation】 - Increased productivity through the collaboration of CNC machining and robots - Reduced processing time - Decreased errors

In the 3D printing industry, there is a demand for increased efficiency and quality improvement in the post-processing stage after printing. In particular, accurate code conversion and smooth data integration are crucial for the finishing of printed objects and collaboration with CNC machining. Inadequate data conversion can compromise product accuracy and lead to rework. The Vericut Icam post-processor optimizes the post-processing stage after 3D printing, maximizing the efficiency and precision of the manufacturing process. This reduces cumbersome tasks and enhances productivity. 【Usage Scenarios】 - Post-processing of products created with a 3D printer - Finishing processes through CNC machining - Integration between CAM systems and CNC machines 【Benefits of Implementation】 - Improved product accuracy through precise code conversion - Reduced process time through smooth data integration - Optimal machining tailored to the characteristics of CNC machines - Machining simulation using digital twins

In the aerospace industry, lightweight components and high reliability are required. In particular, improving machining accuracy is essential for enhancing aircraft fuel efficiency and ensuring safety. Even slight errors in CNC machining or tool damage can lead to a decline in component quality and increased costs. Vericut supports machining accuracy and lightweight design by simulating the entire CNC machining process. It derives the "correct" result in a single machining operation, reducing unnecessary material and rework. 【Use Cases】 - Manufacturing of aircraft components - Manufacturing of rocket components - Manufacturing of drone components 【Benefits of Implementation】 - Reduced machining time - Minimized material waste - Extended tool life - Stable supply of high-quality components

In the automotive industry, there is a demand for high-quality parts and efficient manufacturing processes. Particularly for parts related to safety, high machining precision is essential. However, machining defects and tool breakage can lead to losses in time and costs. Vericut ensures machining accuracy by simulating the entire CNC machining process, deriving the "correct" result in a single operation. 【Usage Scenarios】 * Prototyping and mass production of automotive parts * 5-axis machining, complex machining, multi-surface machining * Quality control, process improvement 【Benefits of Implementation】 * Improved machining precision * Reduction of defective products * Cost reduction