システムクリエイト Product Lineup

Mitarepo is a series based on the concept of "Trying out things like this!" that introduces what can be done using various products. In recent years, the demand for metal 3D printers has been increasing, but when considering their introduction, one cannot make a judgment based solely on catalog specifications. To be honest, there are likely many who wonder, "How much accuracy and quality are actually needed on-site?" Therefore, this time, we thoroughly examined the capabilities of the metal 3D printer "Avimetal," which excels in balancing cost and performance! Using cube models placed at five locations on the build table, we analyzed positional accuracy, dimensional accuracy, and internal density through CT scans. The materials summarize real information that cannot be seen from nominal values, such as whether the angle of laser irradiation affects dimensions and the filling conditions revealed by CT images. Please take a look. *You can download the materials from the button below.

• 3D Printer
• Contract manufacturing
• stainless

Marsugo is a document that picks up the functions and features of various products and introduces the "amazing" aspects. Creality has released its first standalone 3D scanner, the "Sermoon P1"! Until now, using a 3D scanner involved various steps such as connecting to a PC, preparation, editing, and cleanup, which took a lot of time and effort before you could actually scan. The "Sermoon P1" solves those problems. Remarkably, the software is built into the scanner itself! This means there is no need to connect to a PC! It’s an excellent device that allows you to edit immediately after scanning. In the first document, we introduce how easy the process is from scanning to editing thanks to the adoption of a standalone format. In the second document, we explain the structure designed for efficiently performing large scans, so please take a look. *You can download the document using the button below.

• Other analytical and testing equipment

Marsugo is a document that picks up the functions and features of various products and introduces the "amazing" aspects. Creality has launched its first standalone 3D scanner, the "Sermoon P1"! Until now, using a 3D scanner involved various steps such as connecting to a PC, preparation, editing, and cleanup, which took a lot of time and effort before you could actually scan. The "Sermoon P1" solves those problems. Remarkably, the software is built into the scanner itself! Therefore, there is no need to connect to a PC! It’s an excellent device that allows you to edit immediately after scanning. In the first document, we introduce how easy the process is from scanning to editing thanks to the adoption of a standalone format. In the second document, we explain the structure designed for efficient large-scale scanning, so please take a look. *You can download the document using the button below.

• Data conversion software
• 3D measuring device

Small Fab refers to small-scale, decentralized microfactories. By setting up small labs in offices or research and development centers, it allows for rapid and low-cost prototyping and small-scale production using tools like CAD/CAM, 3D printers, CNC machines, and 3D scanners, without the need for factory-like facilities. It is a flexible and practical manufacturing system directly linked to solving on-site challenges. These 3D digital tools are rarely operated with just one product. This time, we will accelerate the development cycle by using the SLA 3D printer "Form 4" and the injection molding machine "M2-1." By using 3D printed models as molds, it becomes possible to quickly create prototypes from designed data. Unlike metal molds, this significantly reduces storage costs, production costs, and lead times.

• 3D Printer
• Injection Molding Machine

Marsgo is a document that picks up the functions and features of various products and introduces the "amazing!" aspects. In FFF-type 3D printers, the adhesion of the "first layer" can be considered a lifeline that determines the success or failure of the print. Issues such as warping and peeling that occur during printing are common challenges regardless of the print size, but their impact increases significantly with larger models. The feeling of loss when several days of effort go to waste is immeasurable. One of the major factors involved here is the "levelness of the table," and manual adjustments require both time and skill, which can undermine the inherent convenience of 3D printers. The "fate of the first layer," which can be seen as a risk, has been resolved in the "D1000 Pro HS" by automating the adjustments. With "4-axis independent leveling," where four independent motors correct the tilt, accurate setup can be completed in just a few minutes, even without skilled techniques. For more details on the specific mechanisms and adjustment methods, please check the document! *You can download the document using the button below.

• 3D Printer
• Stepping motor
• shaft

This document is a series that proposes solutions to various challenges faced in production sites. We will introduce the challenges of digitizing large wooden molds that are not progressing, along with their solutions. [Document Overview] Are you feeling challenged by the increasing inventory in the management of large wooden molds? As the amount of storage increases, the need for space and management effort also grows, and the burden of annual inventory handling accumulates. Although there are standards for storage periods under the Subcontract Act, there are often cases in the field where it is difficult to make judgments due to the possibility of "future reorders." As a result, "irreplaceable molds" pile up, and the invisible management costs become a factor that pressures the profits of the site. In this context, attention is being drawn to the operation of digitizing molds through 3D scanning and remaking them when needed. While it was previously considered to have a high barrier to entry, it is now possible to consider switching to digitization with a budget comparable to the "storage costs of maintaining physical items." This document not only introduces products that are optimal for digitization but also explains the comparison with current storage costs and guidelines for investment recovery. Please use it as a reference for your decision-making regarding implementation. *You can download the document using the button above.

• others
• 3D Printer
• Other CAD related software

Marsgo is a document that highlights the impressive features and characteristics of various products. Dual extrusion utilizes two nozzles to create complex shapes using water-soluble supports, and it can also automatically switch nozzles to continue printing when material runs out. This expands the range of 3D printing using the FFF method even further. However, many may have experienced that during dual extrusion, the material that melts from the standby nozzle can dirty the surface of the model. After spending time creating a model, unintended colors of resin may mix in, or dripped resin may clump and adhere, compromising the quality of the finish. To solve these unique problems associated with dual extrusion, the "nozzle shutter function" has been incorporated into the D1000 Pro HS. By physically blocking the standby nozzle, it achieves high-quality prints without contamination or dirt. The document thoroughly explains the benefits of the "nozzle shutter function" and its detailed mechanism. We encourage you to read it. *You can download the document using the button below.

• 3D Printer
• nozzle

Mitarepo is a series based on the concept of "Trying out things like this!" that introduces what can be done using various products. The greatest strength of metal 3D printers is their ability to create "complex shapes" that were impossible with traditional machining. For example, designs that incorporate 3D water channels running internally to enhance the cooling efficiency of molds can be realized. However, because such complex shapes can be achieved, it also raises concerns such as: "Are the invisible internal cavities truly connected as designed?" "Is there any powder clogging or distortion of shape?" With that in mind, this time we created a model mimicking an injection molding mold and conducted thorough verification using CT scans to check the "invisible internal state." Are the water channels inside accurately reproduced? The results of this verification, along with a series of processes, are compiled in the materials. Please take a look. *You can download the materials using the button below.

• 3D Printer
• Contract manufacturing
• stainless

Mitarepo is a series based on the concept of "Trying out things like this!" where we introduce what can be done using various products. In the prototype stage of product development, 3D printed models have become an indispensable presence for shape verification. However, with commonly used printing methods like filament and resin printing, there are inevitably issues with surface support... right? So this time, we conducted a thorough investigation into the differences between support-free printing and resin models! "What kind of quality can we expect from the models?" "Aren't powder printing methods expensive?" We will address these points of interest by presenting actual images of model surfaces and realistic costs. *You can download the materials from the button below.

• 3D Printer
• Contract manufacturing
• Other contract services

In the home appliance industry, it is important to accurately verify whether the shape and dimensions of a product are realized as designed during the design review. Especially as design becomes more complex and diverse, there is a need to quickly and accurately assess the differences between 3D data and the actual product. The HandySCAN 3D EVO series facilitates comparison with CAD data and contributes to the efficiency of design reviews. 【Usage Scenarios】 - Design reviews of home appliances - Verification of prototype shapes - Shape confirmation before mold production 【Benefits of Implementation】 - Early detection of design modifications - Rapid confirmation of consistency between design and actual product - Reduction of product development time

• 3D measuring device
• 3D CAD
• Other measurement and measuring equipment

In the automotive industry, it is essential to quickly and accurately verify whether the prototype matches the design specifications. This is particularly crucial for parts with complex shapes and curves, where precise measurements are indispensable. Traditional measurement methods have posed challenges due to their time-consuming and labor-intensive nature, leading to longer lead times for prototypes. The HandySCAN 3D EVO series allows for simultaneous inspection during scanning by pre-loading CAD data, contributing to a reduction in inspection time during the prototyping process. 【Use Cases】 - Prototype inspection of automotive parts - Shape measurement of molds and jigs - Verification of design data 【Benefits of Implementation】 - Reduction in inspection time - Acceleration of the prototyping cycle - Improvement in design quality

• 3D measuring device
• 3D CAD
• Other measurement and measuring equipment

In the construction industry, high precision inspections are required to ensure that structures are built according to design plans and that components are placed with accurate dimensions. Especially in complex shapes and large-scale structures, even slight errors can impact the overall quality. The "HandySCAN 3D EVO series" facilitates easy comparison with CAD data and enables rapid inspections on-site. This helps reduce rework and contributes to shortening construction periods. 【Use Cases】 - Dimensional inspections of structures at construction sites - Shape measurements of existing structures in renovation projects - Interference checks through comparisons between CAD data and actual dimensions 【Benefits of Implementation】 - Reduced inspection time through comparisons with CAD data - Improved quality through highly accurate measurements - Reduced rework through immediate decision-making on-site

• 3D measuring device
• 3D CAD
• Other measurement and measuring equipment

Mitarepo is a series that introduces what can be done using various products with the concept of "I tried doing this!" From Formlabs, the new "Tough 1000 V1" has arrived from the Tough series, known for its strength and rigidity! In addition to the strengths of the series, this material features toughness, including resistance to cracking and durability. This time, to verify the capabilities of the "Tough 1000 resin," we created three types of hinge shapes with varying thicknesses and conducted tests to examine the finish and toughness after completion! What is the finish like for the thin model? How much toughness does it have? To answer such questions, we will explain the differences due to thickness and the appearance when bent, along with actual photos in the materials. *You can download the materials using the button below.

• 3D Printer
• Material Evaluation Test
• plastic

There are various types of 3D scanners, and point accuracy and specifications are important factors at the time of introduction. However, practicality in inspection is not determined by these factors alone. What we would like to introduce this time is the "HandySCAN 3D EVO series." Based on high accuracy and volumetric precision, it enables on-site inspection decisions and improved work efficiency through a unique scanning flow using AR! In the materials, we provide a detailed explanation of the reasons for the high accuracy unique to HandySCAN 3D EVO, its advantages, and the actual measurement flow that allows for simultaneous inspection while scanning, so please take a look. *You can download the materials from the button below.

• 3D measuring device
• 3D CAD
• Other measurement and measuring equipment

There are various types of 3D scanners, and point accuracy and specifications are important factors at the time of introduction. However, practicality in inspections is not determined by those alone. What we would like to introduce this time is the "HandySCAN 3D EVO series." Based on high accuracy and volumetric precision, it enables on-site inspection decisions and improves work efficiency through a unique scanning flow using AR! In the materials, we provide a detailed explanation of the reasons for the high accuracy unique to HandySCAN 3D EVO, its advantages, and the actual measurement flow that allows for simultaneous inspection while scanning, so please take a look. *You can download the materials from the button below.

• 3D measuring device
• 3D CAD
• Other measurement and measuring equipment

Mitarepo is a series that introduces what can be done using various products with the concept of "I tried doing this!" Among the many 3D printing methods, the pellet-based 3D printer is noted for its wide variety of usable materials. It attracts attention for its ability to use materials that are not filamentized, as well as recycled materials created through resource reuse and waste reduction, which are not available elsewhere. This time, we focused on ABS, which is considered to have a high level of difficulty in molding among such recycled materials, and we actually performed molding using the large pellet-based 3D printer "CreatBot P800"! In the materials provided, we will answer questions such as, "Can we mold beautifully even with recycled materials?" and "What are the specific considerations for ABS pellet molding?" We will explain the preparations needed for ABS molding and the finishing of the model after completion, along with actual photos. *You can download the materials using the button below.

• 3D Printer
• Material Evaluation Test
• plastic

Mitarepo is a series based on the concept of "Trying out things like this!" that introduces what can be done using various products. When selecting a machining center, what is important is not only the initial cost but also whether it can be used stably after installation. This time, we examined the spindle rotation accuracy (runout) and the axis's repeat positioning accuracy, which affect machining quality and stable operation. Regarding points of concern such as, "The price is attractive, but what about the accuracy?" and "How much machining quality can we actually expect?" we will introduce the actual measurement process and results. *You can download the materials from the button below.

• Machining Center
• Milling
• Tap

Mitarepo is a series that introduces what can be done using various products with the concept of "I tried doing this!" The Form series of SLA 3D printers from Formlabs, which has received support for its ability to create high-resolution models, has been updated from V1 to V2 with the resin material "Tough 2000 Resin," which has ABS-like strength! "What is the actual finish of the model like?" "I'm curious if it can be used as a practical item..." To respond to such inquiries, we conducted an evaluation to verify the capabilities of Tough 2000 Resin V2. First, we focused on "warping," which is key to print quality. We printed a model with a thin thickness and a large area that is prone to warping using the Form4L, and checked the state before and after secondary curing and after support removal. Additionally, we performed tapping on the printed block with pilot holes and checked how much tightening torque it could withstand with two types: direct tapping and helicoil inserts. *You can download the materials from the button below.

• Tap
• 3D Printer
• Material Evaluation Test

In the automotive prototyping industry, a rapid response to design changes and the production of high-quality parts are required. Particularly in prototyping using metal 3D printers, deformation due to residual stress poses challenges, which can lead to rework and increased costs. Amphyon simulates the factors of deformation in metal fabrication, specifically "residual stress," allowing for the detection of deformation amounts and fabrication errors in advance. This reduces the number of trial and error instances in prototyping and mitigates material costs and machine operating costs. Amphyon contributes to quality improvement and cost reduction in automotive prototyping. [Usage Scenarios] - Manufacturing prototypes using metal 3D printers - Optimizing the prototyping process due to design changes - Rapid production of high-quality parts [Effects of Implementation] - Shortened prototyping period - Reduced material costs - Decreased fabrication errors - Realization of near-net-shape manufacturing

• simulator
• Stress Analysis
• 3D Printer

In the field of home appliance design, 3D scanning is essential for accurately capturing the shape and design of products. Particularly for complex shapes and glossy products, obtaining scan data can be cumbersome. AESUB eliminates the need for post-processing after scanning, thereby reducing time and effort in the design process and supporting efficient design work. 【Use Cases】 - Scanning prototype models of home appliances - Creating 3D data for design reviews - Reverse engineering 【Benefits of Implementation】 - Time savings through the reduction of post-processing steps - Increased efficiency in scanning tasks through marker application - Adaptability to various workpieces

• paint
• Coating Agent
• Other consumables

In educational institutions, 3D scanning materials require ease of use and safety. AESUB naturally sublimates after application, eliminating the need for post-processing such as wiping or cleaning. This allows students to experience 3D scanning more smoothly and focus on their learning. 【Usage Scenarios】 - 3D scanning materials - 3D model creation practice - 3D data conversion of physical objects 【Benefits of Implementation】 - Reduces post-processing effort - Can be used as a safe educational material - Provides a smooth learning experience

• paint
• Coating Agent
• Other consumables

In reverse engineering within the manufacturing industry, existing products or parts are often 3D scanned to create CAD data. During this process, glossy or transparent workpieces are difficult to scan, making surface treatment with spray essential. However, traditional powder sprays require considerable effort for removal after scanning, which can reduce work efficiency. AESUB contributes to the efficiency of reverse engineering as it eliminates the need for post-scanning removal work. 【Application Scenarios】 - 3D digitization of existing products - Duplication of damaged parts - Mold design 【Benefits of Implementation】 - Reduction of post-processing steps - Shortening of work time - Cost reduction

• paint
• Coating Agent
• Other consumables

In the aerospace industry, accurate dimensional measurement and quality control of parts are essential for shape inspection. Complex shapes and shiny workpieces can potentially reduce the accuracy of 3D scanning. AESUB addresses these challenges and sublimates naturally without the need for post-processing. 【Application Scenarios】 - Shape inspection of aircraft components - Quality control of space-related equipment - Dimensional measurement of prototype parts 【Benefits of Implementation】 - Time savings by reducing post-processing steps - Improved scanning accuracy - Enhanced work efficiency

• paint
• Coating Agent
• Other consumables

In the automotive industry's quality control, accurate 3D scanning is essential. Particularly in measuring the dimensions of body parts and inspecting the shapes of interior components, the surface condition of the scanned objects greatly affects the accuracy of the scan. Glossy parts and black components are difficult to scan and require appropriate preprocessing. AESUB addresses these challenges and sublimates naturally after scanning, eliminating the need for post-processing. 【Application Scenarios】 - Dimension measurement of body parts - Shape inspection of interior components - Scanning of prototype parts 【Benefits of Implementation】 - Reduction of post-processing steps - Improvement in scanning accuracy - Shortening of work time

• paint
• Coating Agent
• Other consumables

In experimental research fields, rapid prototyping is required. In particular, when comparing samples with different material properties in a short period, injection molding is one effective method. However, traditional large injection molding machines may not be suitable for research purposes due to space and operability issues. The tabletop small injection molding machine 'Moiron KH-1775D' is ideal for laboratory use due to its simple operability and compact design. 【Usage Scenarios】 - Prototyping in material development - Production of small quantities of diverse samples - Educational use in laboratories 【Benefits of Introduction】 - Enables rapid prototyping - Compatible with a variety of materials - Space-saving design

• Injection Molding Machine
• Engineering Plastics
• plastic

Educational institutions require teaching materials that enable students to acquire practical knowledge and skills in manufacturing. In particular, plastic molding technology plays a crucial role in modern manufacturing, and learning its fundamentals is essential for expanding students' future possibilities. However, traditional injection molding machines have faced challenges due to their complex operation and difficulties in ensuring safety. The tabletop small injection molding machine 'Moiron KH-1775D' balances simple operability and safety, making it ideal for use in educational settings. [Usage Scenarios] - Teaching materials for industrial high schools and engineering departments at universities - Manufacturing experience workshops - Collaboration with programming education [Effects of Introduction] - Realization of practical manufacturing education - Improvement of students' creativity and problem-solving skills - Injection molding experience in a safe environment - Support for the creation of diverse teaching materials

• Injection Molding Machine
• Engineering Plastics
• plastic

In experimental research fields, rapid prototyping is essential. Particularly in the creation of samples for evaluating material properties and in the manufacturing of components for experimental apparatus, high precision and flexibility are crucial. The Mill-Key Pro 5040 accommodates various materials and offers high customization, making it possible to process according to research needs. 【Usage Scenarios】 - Creation of experimental samples - Manufacturing of research jigs - Production of prototype parts 【Benefits of Implementation】 - Increased efficiency in experiments - Reduced prototyping time - Accelerated research

• 3D Printer

In educational institutions, it is essential to nurture students' creativity and help them acquire practical manufacturing skills. In particular, 3D modeling and processing technologies are important elements in developing the human resources that will support the future. The Mill-Key Pro 5040 is ideal for use in educational settings as it allows for easy hands-on experience with metal and resin processing. 【Usage Scenarios】 - Technology classes in schools - University laboratories - Vocational training schools - Workshops that foster creativity 【Benefits of Implementation】 - Acquisition of practical manufacturing skills - Improvement of students' creativity and problem-solving abilities - Hands-on experience in a safe environment - Enhanced learning outcomes through use as teaching materials

• 3D Printer

In the prototype process of the mold industry, a quick response to design changes and high-precision machining are required. In particular, modifications during the prototype stage can not only affect the quality of the product but also lead to increased costs and time. The Mill-Key Pro 5040, despite its small size, addresses these challenges in prototyping by accommodating various materials and achieving high machining precision. Its dedicated CAM software allows for easy program creation even without specialized knowledge, contributing to a reduction in prototype lead time. 【Usage Scenarios】 - Prototype of mold design - Shape verification - Material compatibility assessment - Small lot production 【Benefits of Implementation】 - Reduced prototype lead time - Cost savings - Quick response to design changes - Creation of high-quality prototypes

• 3D Printer

Mitarepo is a series that introduces what can be done using various products with the concept of "I tried doing this!" Materials that can be used with FDM 3D printers are being developed in various types every day. However, compared to general molding materials, the current options are still limited. One of the reasons for this is the high difficulty level of shaping each material. There are quite a few materials that are difficult to shape with FDM due to the influence of resin properties and other factors. In this context, we have received POM filament from Polyplastics. This material is optimized for 3D printing and enables stable shaping with POM, which has been difficult to mold until now. In this document, we used the FDM 3D printer "CreatBot PEEK-250," which is equipped with excellent temperature control features, to challenge the actual shaping of POM! Can POM really be shaped? Under what conditions can it be shaped? For the results that you may be curious about, please check the document. *You can download the document from the button below.

• 3D Printer
• Engineering Plastics
• Material Evaluation Test

In the machine tool industry, issues such as machine damage due to programming errors and increased setup times are prevalent. Particularly in the processing of complex shapes and high-precision machining, a significant amount of time and cost is required for program verification. NC2Check addresses these challenges through G-code NC program simulation. By detecting interferences and collisions based on G-code and verifying movements similar to actual machines, it helps prevent accidents in advance and contributes to reducing setup times. 【Usage Scenarios】 * Processing of complex shapes * High-precision machining * Prototyping and small-scale production 【Benefits of Implementation】 * Reduced risk of machine damage * Shortened setup times * Increased efficiency in program verification

• 3D CAM
• simulator
• Other CAM related software

In the mold industry, the precision of molds, which affects product quality, is crucial. Particularly for molds that require complex shapes or high precision, even a slight mistake in the NC program can lead to product defects or rework. NC2Check helps prevent these issues by simulating G-code NC programs, supporting the production of high-precision molds. 【Usage Scenarios】 - High-precision mold production - Production of complex-shaped molds - Verification of NC programs 【Benefits of Implementation】 - Improved accuracy in mold production - Reduction of defective products - Decrease in rework labor hours

• 3D CAM
• simulator
• Other CAM related software

In the automotive industry, there is a demand for the efficient manufacturing of high-quality parts. Particularly in parts processing using CNC machine tools, the accuracy and safety of the programs are crucial. Errors in G-code or interference between tools, workpieces, and jigs can lead to defective parts or damage to machines, potentially reducing production efficiency. NC2Check prevents these issues by simulating G-code NC programs. 【Usage Scenarios】 * Verification of NC programs in prototype and mass production of automotive parts * Interference checks in the processing of complex-shaped parts * Reduction of processing time and cost 【Benefits of Implementation】 * Reduction of processing defects and improvement in quality * Decreased risk of damage to machinery * Increased productivity through process optimization

• 3D CAM
• simulator
• Other CAM related software

In the aerospace industry, high precision and safety are required in the manufacturing process. Particularly in the machining of parts with complex shapes, accurate verification of G-code programs is essential. Errors in the program, as well as interference between tools, workpieces, and fixtures, can lead to damage of expensive parts and, in the worst case, accidents. NC2Check faithfully reproduces G-code NC programs and detects interference and collisions in advance, thereby reducing these risks. 【Use Cases】 * Verification of G-code programs in the manufacturing of aerospace components * Ensuring safety in the machining of complex-shaped parts * Interference checks with fixtures and clamps 【Benefits of Implementation】 * Reduction of cost increases due to machining defects * Decreased risk of damage to machinery * Realization of a safe manufacturing process

• 3D CAM
• simulator
• Other CAM related software

In the furniture industry, there is a growing demand for diverse designs and high-quality products. For example, creating templates for complex cushion shapes by hand is time-consuming and labor-intensive, and the increased costs from repeated prototypes are also a challenge. ExactFlat allows for the direct creation of cushion template data from 3D models, reducing the number of prototypes and achieving an efficient manufacturing process. 【Usage Scenarios】 * Changing cushion designs * Manufacturing cushions of various shapes * Reducing the number of prototypes 【Benefits of Implementation】 * Shortening template creation time * Reducing material waste * Cost reduction

• Other CAD related software
• Data conversion software
• 3D CAD

In automotive interior design, it is important to balance aesthetics and functionality. In particular, complex-shaped parts such as seats and trim require precise pattern data. Creating patterns by hand is time-consuming and labor-intensive, and revisions can be cumbersome. ExactFlat allows for the direct creation of pattern data from 3D models, reducing the number of prototypes and shortening the design period. 【Use Cases】 - Seats - Trim - Dashboard 【Benefits of Implementation】 - Reduction in prototype costs - Shortened design period - Realization of high-quality interior design

• Other CAD related software
• Data conversion software
• 3D CAD

In the apparel industry, as the diversification of designs and the demand for shorter delivery times progress, efficient pattern making is required. In particular, creating patterns for complex-shaped garments and considering the characteristics of materials is a time-consuming and labor-intensive challenge. ExactFlat addresses these issues by directly creating pattern data from 3D models. 【Usage Scenarios】 - Pattern creation from 3D models - Pattern creation considering material characteristics - Reduction of prototype iterations 【Benefits of Implementation】 - Reduction of man-hours - Reduction of prototype costs - Realization of high-quality products

• Other CAD related software
• Data conversion software
• 3D CAD

In the automotive industry, it is important to efficiently design smooth curves to achieve a balance between aesthetics and functionality. Particularly in body design, which affects aerodynamic characteristics, and in interior design, which pursues visual beauty, the quality of curves significantly influences the value of the product. Traditional CAD software requires a lot of time and effort to express complex curves, limiting design freedom. xNURBS complements the functionality of Rhinoceros, enabling the generation of complex curves with just a few clicks. This allows designers to approach their designs with greater creative freedom and improves the efficiency of product development. 【Application Scenes】 - Automotive body design - Interior design - Parts design considering aerodynamic characteristics 【Effects of Implementation】 - Reduction in design time - Increased design freedom - Improvement in product quality

• Data conversion software
• Other CAD related software
• Engineering Plastics

In research and development experiments, testing and inspections are repeated. To enhance the accuracy of experiments and efficiently acquire data, it is necessary to quickly prepare jigs that are suitable for the purpose. However, traditional jig design often requires specialized knowledge and can be time-consuming. "EZ Jig for Rhino" enables jig design through intuitive operations without the need for expertise in 3D CAD. By collaborating with 3D printers, it allows for the rapid creation of necessary jigs when needed, contributing to the efficiency of experiments. 【Usage Scenarios】 - Design of experimental jigs - Fixtures for prototypes - Measuring jigs - Component fixation in research and development 【Benefits of Implementation】 - Reduction in jig design time - Shortening of prototype development time - Improvement in experimental accuracy - Acceleration of research and development

• Other CAD related software
• Inspection fixture
• Assembly Jig

In the machine tool industry, high-precision positioning is a crucial factor that affects product quality and production efficiency. In the case of small-batch production with many variations, the design process can take a long time. Delays in jig design and issues with precision can lead to decreased productivity and the occurrence of defective products. EZ Jig for Rhino allows for intuitive design of assembly jigs, fixtures, and more, simply by placing models, without relying on expertise in 3D CAD. 【Usage Scenarios】 - Inspection jigs and painting jigs - Design of jigs in the machining process - Rapid production of jigs utilizing 3D printers 【Benefits of Implementation】 - Reduction in jig design time - Cost savings in jig production - Achievement of high-precision positioning - Improvement in production efficiency

• Other CAD related software
• Inspection fixture
• Assembly Jig

In the toy industry, the prototyping stage requires rapid realization and modification of designs. Especially for toys that demand complex shapes and detailed expressions, the efficiency of prototyping is crucial. Traditional prototyping methods have been challenged by time and cost issues. QUICKSURFACE allows for direct modeling from 3D scan data, faithfully reproducing toy designs and shortening the prototyping period. 【Application Scenarios】 - Prototyping toys using 3D scanning - Redesigning based on the shapes of existing toys - Modeling complex-shaped toys 【Benefits of Implementation】 - Reduced prototyping time - Cost savings - Faithful reproduction of designs

• 3D measuring device
• Other CAD related software
• 3D CAD

In the automotive industry, reverse engineering requires accurately understanding the shapes of existing parts and reconstructing them as CAD data. This is especially important for parts with complex shapes or freeform surfaces, where precise data acquisition and efficient modeling are crucial. Inaccurate data or cumbersome tasks can lead to design delays and a decline in part quality. QUICKSURFACE utilizes 3D scan data to streamline the reverse engineering process. 【Use Cases】 - Shape measurement of existing parts - Creation of CAD data - Design modifications - Duplication of parts 【Benefits of Implementation】 - Direct modeling from 3D scan data - Efficient shape correction through mesh data editing features - Flexible design changes through history-based hybrid modeling

• 3D measuring device
• Other CAD related software
• 3D CAD

In the toy industry, the prototyping stage requires rapid realization and modification of designs. Particularly when dealing with complex shapes or organic designs, converting 3D scan data into CAD models is key to efficient prototyping. Mesh2Surface for Rhinoceros reduces the time required for prototyping and lowers design costs by converting 3D scanned mesh data into CAD models. 【Use Cases】 - Toy design prototyping - Shape modification of existing toys - Creation of data for 3D printers 【Benefits of Implementation】 - Shortened prototyping period - Reduced design costs - Flexible response to design changes

• 3D CAD

In the ship repair industry, obtaining accurate shape data is essential for replacing aging parts and repairing damaged areas. Particularly in the repair of parts with complex shapes, it is important to accurately understand the shape and create CAD data. Mesh2Surface facilitates the easy creation of CAD models from 3D scan data, contributing to the efficiency of repair work. 【Use Cases】 - Repairing damaged areas of the hull - Replacing aging parts - Duplicating parts without drawings 【Benefits of Implementation】 - Reduced repair time - Lower design costs - Increased efficiency in part manufacturing

• 3D CAD

In the furniture industry, rapid realization of customized designs is essential to meet the diverse needs of customers. In particular, accurate 3D data is indispensable for customizing based on existing furniture and creating complex-shaped parts. Manual measuring and modeling not only take time and cost but also tend to lead to precision issues. Mesh2Surface for Rhinoceros addresses these challenges by directly generating CAD models from 3D scan data. 【Usage Scenarios】 - Digitizing the shapes of existing furniture into 3D data for customized design - 3D scanning complex-shaped parts to create CAD data - Efficiently realizing one-of-a-kind furniture designs tailored to customer requests 【Benefits of Implementation】 - Reducing the production time for customized designs - Cutting design costs - Improving customer satisfaction

• 3D CAD