3D scanner inventor


Reverse Engineering for SolidWorks Inventor

Reverse-engineer parts into digital 3D parametric models fast and easily with DezignWorks plug-in for SOLIDWORKS and Inventor.

DezignWorks plug-in for SOLIDWORKS and Inventor gives you a robust and powerful reverse-engineering toolset to quickly and efficiently create CAD from physical parts.

Businesses of all sizes, across all major industries trust DezignWorks for their most complex reverse-engineering projects.

DezignWorks is suite of robust reverse-engineering tools fully integrated into SOLIDWORKS and Autodesk Inventor. DezignWorks feature-based reverse engineering system helps create fully editable CAD models of physical parts and in the creation of model space when designing new parts. This process is critical when attempting to create models that can not only accurately represent a physical part as-is, but also have the ability to easily change a parts’ geometry.

DezignWorks Unlimited offers you a complete suite of tools to use your FARO or Romer ScanArm directly in SolidWorks or Autodesk Inventor to scan and probe everything from prismatic shapes to complex surfaces, enabling you to complete the most difficult Reverse engineering tasks

  • Best Choice for ScanArms / Laser Trackers / TrackArms
  • Scan Directly in SOLIDWORKS / Inventor
  • Includes All Features from Mesh Modeler and Probing Packages

DezignWorks Mesh Modeler gives you a complete reverse-engineering toolset to import scan data from your 3D scanner and use it to quickly create geometric features and create complex non-prismatic surfaces.

  • Best Choice for Handheld 3D Scanners
  • Import Large Scan Data / Polygonal Mesh
  • Reverse-Engineering Toolset Created for Working with Scan Data

DezignWorks Probing enables your Probing Arm to accurately and quickly capture geometric features as well as probe scanning complex, non-prismatic features and surfaces.

  • Best Choice for Probing Only Devices
  • Probe Directly in SOLIDWORKS / Inventor
  • Reverse-Engineering Toolset for Probed Features

DezignWorks Unlimited allow you to use your FARO or Romer ScanArm directly in SOLIDWORKS and AutoDesk Inventor to capture complex, non-prismatic data and create surfaces efficiently and accurately.

  • Best Choice for ScanArms / Laser Trackers / TrackArms
  • Scan Directly in SOLIDWORKS / Inventor
  • Includes All Features from Mesh Modeler and Probing Packages

DezignWorks Mesh Modeler gives you a complete reverse-engineering toolset to import scan data from your 3D scanner and use it to quickly create geometric features and create complex non-prismatic surfaces.

  • Best Choice for Handheld 3D Scanners
  • Import Large Scan Data / Polygonal Mesh
  • Reverse-Engineering Toolset Created for Working with Scan Data

DezignWorks Probing enables your Probing Arm to accurately and quickly capture geometric features as well as probe scanning complex, non-prismatic features and surfaces.

  • Best Choice for Probing Only Devices
  • Probe Directly in SOLIDWORKS / Inventor
  • Reverse-Engineering Toolset for Probed Features

DezignWorks is a SOLIDWORKS Certified Gold Product which represents the highest level of integration with SOLIDWORKS software and requires an ongoing partnership with SOLIDWORKS.

DezignWorks is an AutoDesk Certified App which means we have demonstrated the highest level of quality, interoperability, and compatibility with Autodesk Inventor 2022 and future releases and updates.

Want to see what DezignWorks can do for you? Use this link to schedule a live web demo with a DezignWorks Application Engineer today!

SCHEDULE LIVE DEMO

Want to see what DezignWorks can do for you?
Use this link to schedule a live web demo with a DezignWorks Application Engineer today!

SCHEDULE LIVE DEMO

DezignWorks
116 Morlake Dr. Suite 104
Mooresville, NC 28117

DezignWorks | Unlimited

DezignWorks | Mesh Modeling

DezignWorks | Probing

Reverse Engineering

3D Scanning

3D CAD Modeling

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DezignWorks Support

Schedule LIVE Demo

15 Day FREE Trial

“Glory be to God”

DezignWorks
116 Morlake Dr. Suite 104
Mooresville, NC 28117

DezignWorks | Probing

DezignWorks | Mesh Modeling

DezignWorks | Unlimited

Reverse Engineering

3D Scanning

3D CAD Modeling

Quote Request

DezignWorks Support

Schedule LIVE Demo

15 Day FREE Trial

“Glory be to God!”

3D Scanners for Reverse Engineering

Hi everyone! This is Top 3D Shop, and in the following review, we will talk about reverse engineering, the considerations when choosing 3D equipment for it, and related case studies.

Read on to learn more.

 

What is reverse engineering?

Source: 3daeroscan. com

Reverse engineering, also known as back engineering, is the process of creating a project of parts or products with no drawings or documentation. By creating a digital CAD model using 3D scanning, these parts can be modified and optimized to extend their lifetime or add new functions. This method is used in many industries, including the production of military equipment or spacecraft.

With the growing popularity of 3D printing, reverse engineering is gaining ever-increasing attention. This is due to the fact that the reproduction of an object or design using digital modeling and 3D printing is more accessible to ordinary users than other production processes.

The ICON company uses a variety of 3D scanners to reverse engineer vintage car parts.

Source: 3dreveng.com

The process of reverse engineering involves three tasks: obtaining a sufficiently accurate digital impression of a part, converting the resulting image into a solid 3D model in specialized software, and subsequent digital processing of the model to eliminate artifacts, convert the format, and make some modifications so that the model design is suitable for the product launch.

Therefore, it is necessary to choose the right 3D scanner to obtain the primary data that best suits the existing task. For example, it is completely pointless to scan a piece of jewelry with a time-of-flight scanner for large objects, and vice versa: the very high accuracy of a desktop or handheld scanner is redundant when scanning, for instance, a sea vessel.

NeoMetrix Technologies uses the Creaform HandySCAN 700 3D scanner for reverse engineering and metrological control of various objects.

  

Stages of reverse engineering

Source: 3dcaptura.cz

1. Prepare the object for scanning, apply markers if necessary. Note that glossy surfaces impede the work of 3D scanners, and reflective or transparent ones are nearly impossible to scan without a matte finish, so spray a temporary matte powder on the object to improve scanning accuracy.

2. Use a 3D scanner to capture important areas of the part. You may need to orient and rescan your object several times if it has holes or deep grooves.

3. Adjust and optimize the resulting polygonal mesh. Some scanners create very large files, making it difficult to post-process and print an object. Remove artifacts, check the surface stitch.

4. Import the mesh into CAD software equipped with reverse engineering tools.

5. Convert polygons to solids. 

6. If necessary, add new objects to the resulting 3D model or delete unnecessary ones.

7. Use 3D printers or CNC machines to produce a new part according to the created model.

Reverse engineering of automotive parts with a Creaform 3D scanner using the VXmodel and Autodesk Inventor software

  

Case studies

Reverse engineering of an impeller

Source: 3d-scantech. com

An equipment manufacturer needed to optimize the production of impellers and eliminate manufacturing variances. It proved impossible to obtain accurate data of a part with holes, dead angles, and geometrically complex surfaces by traditional means. The impeller has narrow gaps between the vanes, which prevents measurement with a probe, so it was decided to employ 3D laser scanning and process the results using reverse engineering methods for comparison with the original digital model.

Source: 3d-scantech.com

3D scanning was performed by means of the ScanTech PRINCE high-precision 3D scanner with red and blue laser scanning modes. The device has a resolution of 0.020 mm and can quickly switch between modes. It is capable of scanning deep holes with a single red laser line and capturing the smallest details. In addition, the scanner is insensitive to ambient light. 

Source: 3d-scantech.com

A full detailed model of the impeller housing with vanes was obtained using the 3D scanner.

Source: 3d-scantech.com

A complete digital model was created for analysis.

  

Creating an audio speaker cart using reverse engineering

Source: shining3d.com

To participate in a sports and dance event called Colorguard, a captain had to do something for her team. She decided to create a cart for a heavy speaker that girls use to play music during training and performance. The speaker was to be easily removed from the cart if necessary. Besides, one of its handles needed restoration.

The speaker has three identical handles attached with screws. To replace the broken handle with a new one, the EinScan-SP was used to scan one of the remaining handles. Since the handle was very dark, it was dusted with a thin layer of baby powder so that the scanner could correctly recognize the surface. The EinScan-SP has the function of automatically stitching images when the object is rotated on the turntable and in different positions of the object. The program selects certain points from several scans and connects them. This allows users to scan not only the sides but also the top and bottom of the object.

Source: shining3d.com

To clean up the resulting image from artifacts and eliminate any damage on the handle, the Deform: Smooth tool in the free Autodesk Meshmixer utility was used. Using the Edit: Erase and Fill tools, the existing manufacturer's logo was removed, with the event logo added. Meshmixer was also used to make sure the screw holes were cylindrical. Processing the resulting STL file in Meshlab simplified the model and reduced the file size from 26 to 2.4 Mb. 

Source: shining3d.com

The handle was printed using the Afinia H+1 3D printer with a TPU extruder and NinjaTek's Cheetah flexible filament. For greater rigidity, 80% filling was used. The resulting handle turned out both durable and pleasant to touch.

Source: shining3d.com

After examination, it was decided to use the speaker mount holes as attachment points to the cart. Measurements with a caliper would have taken plenty of time, it was more efficient to use the Shining 3D EinScan Pro 2X Plus portable 3D scanner. Markers were applied for better surface capture.

Source: shining3d.com

Although the EinScan Pro 2X Plus comes with the Solid Edge software (a complete CAD package with reverse engineering capabilities), it was decided to use Autodesk Fusion 360 because the user was more comfortable with it.

Source: shining3d.com

The resulting 3D model was too large to be printed in one piece, so it was split into two parts. It was printed with black PLA. 

Source: shining3d.com

The print path was optimized to increase the strength of the cylinder and walls. 

Source: shining3d.com

The cart handle was made of acetone-welded ABS plastic, and a piece of chipboard was used to make the base plate.

  

Reverse engineering of stamping dies

Source: metrology. news

Gestamp is an international company engaged in the design, development, and hot stamping manufacture of metal automotive parts for major carmakers. In modern production, there occurs a situation when changes are made to a CAD-designed die directly in production. Manufacturers often forget to reflect such changes in the documentation/original model. As a result, when a die is replaced on account of wear or damage, engineers have to make undocumented changes anew, which leads to errors and an increase in flaws.

Source: metrology.news

This situation can be fixed with the use of reverse engineering. After a die is set and configured, it is scanned and all the changes are recorded in the digital model. The resulting file, which fully corresponds to the scanned surface including the smallest details, is used for reverse engineering of the die. Changes identified using this method are incorporated into the original 3D model of the die. 

Source: metrology. news

Gestamp specialists work with the Creaform HandySCAN 3D scanners, appreciating their accuracy, convenience, and compatibility with reverse engineering software.

  

Footwear design using reverse engineering

Source: rangevision.com

RangeVision specialists investigated the possibility to speed up reverse engineering of objects with a large number of surfaces that change their curvature in accordance with mathematical laws. They used the sole of sports shoes as a test surface with such properties.

Source: rangevision.com

For this, they performed a 3D scan of the sole's geometry using the RangeVision Spectrum high-resolution 3D scanner (adjusted for object sizes from 30 cm to 1 m) and a rotary table. In 25 minutes, the device completed two groups of 8 scans, which were automatically linked into one model by the scanner software. Post-processing in the RangeVision ScanCenter program and obtaining a 3D model in . stl format took another 35 minutes.

Source: rangevision.com

Reverse engineering of the sole was carried out in Geomagic Studio using the NURBS method. First of all, artifacts and digital noise were removed, a coordinate system was created, unnecessary details were cut off, and the boundaries were smoothed.

Source: rangevision.com

After applying the NURBS method to the resulting surface, the final 3D model was created. Reverse engineering using NURBS took 4 hours. The entire task was completed within one working day.

  

Scanning of different objects, DE-Engineering

Source: rangevision.com

The DE-Engineering company fulfills orders on high-precision 3D digitizing and reverse engineering of various objects, from aircraft to jewelry. The founder Dmitry Epstein maintains a video blog on YouTube, in which he publishes the most interesting works. DE-Engineering uses the RangeVision PRO and Gom Atos 3D scanners.

Source: rangevision.com

3D scanning of large objects, such as the frame of a helicopter or an airplane, has some peculiarities: to save time, markers are glued with strips of masking tape, and scanning is carried out from several points to facilitate stitching of the model.

Source: rangevision.com

For the armoring of two Citroen Jumpy vehicles, DE-Engineering specialists performed 3D scanning of the body and created an accurate model, according to which the metal plates were manufactured. The high precision of reverse engineering made it possible to install the armor without any additional fit. The whole process took seven days — two days for scanning and five days for processing.

Source: rangevision.com

DE-Engineering tries to use point cloud processing instead of polygons, which is more convenient from the point of view of model simplification. This allows maximizing the detail of an object in complex geometry areas and reducing it in simple ones. Processing is performed with the Catia software. Replaceable lenses are used to scan jewelry.

 

3D scanning in reverse engineering of a complex-shaped part, Top 3D Shop

A client contacted Top 3D Shop with a request to restore a broken plastic part of a complex shape. 

The part was created by 3D scanning with the RangeVision Pro, reverse engineering, and 3D printing.

Step 1. The length of the part is about 30 cm, so it was impractical to use medium-precision handheld scanners and solutions for large objects. Desktop scanners with a multi-axis table were not suited either, because the object did not fit in length into the half-open scanner camera. Thus, stationary optical or high-precision handheld scanners seemed to be the only options.

Step 2. The object has a geometry of medium complexity. For good scanning of such parts, a scanner accuracy of 40–60+ microns is required.

In the images: solid models of the object with the restored integrity

Step 3. The higher the accuracy of a 3D scanner and the more features it has, the more expensive it is. The customer's budget did not allow the use of GOM, Solutionix, or Scantech scanners, so Top 3D Shop employed the RangeVision Pro, which scans such small objects with an accuracy of 40 microns. Based on the data obtained from 3D scanning, reverse engineering was performed, and the part was prepared for printing.

  

How to choose a 3D scanner for reverse engineering

First of all, it is necessary to define the size of the scanned objects — this affects the choice of scanning technology and the type of scanner (desktop, handheld, or floor-standing):

  • For objects larger than 10 m in any of the coordinate axes, 3D scanners with the usual laser triangulation or structured light technologies are not suitable. Scanning such objects even with a handheld scanner will take a lot of time, and the accuracy of data decreases. This problem is partially solved by photogrammetry. Therefore, for very large objects (airplanes, ships, buildings), it is most effective to use time-of-flight (ToF) scanners.
  • For objects larger than 50 cm but less than 3 m, it is recommended to use handheld scanners — optical or laser ones.
  • For objects from 10 to 50 cm, stationary desktop or portable floor-standing 3D scanners suit best (both optical and laser). Optical desktop and floor-standing scanners are more affordable than laser ones. Some handheld laser scanners can be used for tasks requiring high scanning speed.
  • Desktop high-precision optical scanners are best for small objects. Scanners of this type can be divided into two groups: dental and versatile. 

Dental scanners feature immensely high precision, high resolution, and rotary tables with the ability to attach an occluder and impression stands.

Versatile scanners are usually equipped with a multi-axis rotary table, or the scanner itself is fixed on axes with several degrees of freedom. This design allows for autonomous scanning of most of the object's surface. These scanners have a good scanning depth to correctly capture grooves.

For objects with a size of 10–50 cm, laser handheld scanners are better suited if at least one of the following conditions is met:

  • 3D scanning is planned to be used very often;
  • the object to be scanned cannot be transported to the workshop; for example, it is a non-removable part of a massive mechanism, or transportation is impossible for other reasons;
  • there is not enough room to place a stationary scanner;
  • the surface of an object is difficult to scan with optics — it is black or highly reflective.

After defining the size of scanned objects, it is important to find out the required scanning accuracy and the measurement tolerance and see whether a metrological scanner is needed.

Reverse engineering of car parts at Jay Leno's Garage using the Faro Quantum ScanArm HD 3D laser scanner and the Stratasys Dimension 1200es 3D printer

  

Software for modeling and reverse engineering

Software for creating polygon models

Source: all3dp.com

To create point clouds and polygon models, it is usual to employ the proprietary software of a 3D scanner. Some 3D scanning and reverse engineering software products can also work directly with the most popular scanners.

  

Software for converting polygon models into solid ones

Geomagic Essentials

Source: einscan.com

Geomagic Essentials is a program that extracts all the necessary elements of a scanned part for direct use in a CAD package. This software is designed to work with scans made by the Shining 3D EinScan Pro 2X (a joint product of 3D Systems and Shining 3D), which automatically processes and transfers the received data to the CAD environment. The application can be used both for metrological control and reverse engineering of parts and assemblies. The proprietary algorithms of mesh alignment and restoration, a wide range of options for fitting elements, the capability of creating cross sections, and high performance when working with large amounts of data can significantly reduce the work time of specialists.

Employing Geomagic Essentials to reverse engineer fan blades by user Gregory George

Geomagic Design X

Source: 3dsystems.com

Geomagic Design X is versatile professional reverse engineering software that combines traditional CAD functionality with 3D scan data processing. Design X allows creating functional, editable solid models compatible with CAD software. The proprietary algorithms for accurate surface fit to 3D scans, mesh editing, and point cloud processing enable the design of components that perfectly integrate with existing parts. The easy-to-use mesh repair tools provide fast hole filling, smoothing, optimization, and comparison with the original model.

Reverse engineering of a compressor at Artec 3D using 3D scanning and the Geomagic Design X software

Autodesk Meshmixer

Source: all3dp.com

Autodesk Meshmixer is completely free software popular with 3D printing professionals. Meshmixer is designed for working with polygonal meshes rather than for parametric modeling and has a large set of tools for this. The functions of automatic analysis and correction are very convenient for processing 3D scans. The program is also capable of preparing a model for 3D printing, including supports. Meshmixer is simple and easy to use, with many tutorials available online.

The first video by AutoDesk to demonstrate the capabilities of Meshmixer

  

Software for working with solid models

SolidWorks

Source: blog. trimech.com

SolidWorks is a 3D design and reverse engineering program. Apart from traditional CAD/CAM functions, the software includes specialized tools for designing sheet metal parts, welds, and dies. A huge library of components and parts, improved realistic rendering, the capability of design check and structure analysis make SolidWorks one of the most powerful 3D engineering software products available.

The first video from the series of SolidWorks software tutorials: reverse engineering and 3D scan processing

Solid Edge

Source: youtu.be

Solid Edge is an easy-to-learn toolset that covers all phases of product development: CAD design and rendering, modeling, reverse engineering, data management, and more. Siemens also provides training resources, access to the Solid Edge community, and ongoing software updates. If certain conditions are met, Solid Edge Premium can be used free of charge for one year.

Demonstration of the capabilities of Solid Edge 2021 from Siemens Software

Autodesk Fusion 360

Source: all3dp.com

The Autodesk Fusion 360 software and all of its modules are free for students, educators, hobbyists, and small businesses. The program is designed primarily for working with solid objects and is equipped with functional plug-ins.

Reverse engineering of a plastic housing at Dream3D using the HDI 3D scanner and the Autodesk Fusion 360 software

   

Legal issues of reverse engineering 

Source: scantech.com

The dark side of reverse engineering is intellectual property forgery and theft. The growing availability of the technology can give an advantage to unscrupulous manufacturers when legislation lags behind modern requirements. This means that prototypes that took developers a lot of time and money can be counterfeited with impunity using 3D scanning and printing technologies.

The ease of copying product designs forces large companies to experiment with ways to protect their intellectual rights — for example, by creating product defects that appear only in unauthorized production, or by embedding authentication barcodes directly into manufactured products.

Full 3D scanning and reverse engineering of a car body using the Creaform Go!SCAN SPARK 3D scanner.

   

Conclusion

Source: ductim-x.com

The future of reverse engineering lies in even greater process automation. Manufacturers are increasingly employing the power of artificial intelligence and cloud technologies in scanning and post-processing to enable inexperienced clients to carry out their work autonomously. This can be useful for specialists in a variety of fields, from doctors scanning body parts to workers on construction sites. 3D scanners keep on penetrating the consumer market and may eventually become as commonplace as cameras on smartphones (some of them are already equipped with a ToF sensor).

 

Created the most accurate 3D scanner | Jewelry INFO

07/05/2019 03:53 Production

Ukrainian inventor Leonid Nazarenko and his son Denis create a high-precision 3D scanner for jewelers. It has no analogues in the world in terms of price and quality.

The story of two inventors began about four years ago when they wanted to get high-precision 3D models of small objects, such as coins or figurines. But faced with the fact that the laser scanners available on the market, firstly, are very expensive, and secondly, their accuracy left much to be desired.

The very idea of ​​the scanner was born when Denis Nazarenko was trying to make a model of the statue of Manjushri. “But scanners capable of capturing the smallest details of a model cost at least 17,000 euros and were out of reach for a small company. So we decided to create our own,” the Kickstarter presentation reads.

Who are Nazarenko

In a small office in the town of Vyshneve near Kyiv, father and son set about experimenting. The background allowed them to use deep knowledge from completely different engineering fields.

Leonid Nazarenko began his career at the Antonov plant, which built the world's largest An-225 aircraft. He created models of aircraft from childhood, and then taught schoolchildren to do the same. Leonid had a good understanding of metalworking and a wide range of knowledge in engineering disciplines.

Denis Nazarenko won various competitions in mathematics, physics and computer science. He has been working on software development for many years. And his most famous project is Start Menu X, a convenient alternative to the Windows Start menu, which has been used by many people around the world.

LED vs. Laser

Two engineers found that a laser projector creates a lot of scanning noise, which is detrimental to the quality of the 3D copy. And he has a worthy alternative. The light-emitting diode (LED) beam in combination with good lenses made it possible to achieve noticeably better results.

This photo shows how much noise the laser beam has compared to the LED beam:

Another bonus. This technology does not require expensive projectors and cameras.

Entrepreneurs decided to take their idea to Kickstarter through a partner who lived in Canada. Last spring, they managed to raise over $22,000 to produce their first model, the D3D-s desktop 3D scanner.

According to Denis Nazarenko, who was contacted by the journalist of Liga.Tech , together with his father, they collected and delivered about 10 scanners to investors who supported them with money on a crowdfunding site. A few pieces are still being finalized.

Fashion for second rings

According to Nazarenko, during this time they managed to find the exact niche for their devices - the American jewelry market. According to him, the tradition of wearing so-called shadow wedding bands is widespread in the States. These are additional rings that spouses order in addition to engagement rings, for example, for a wedding anniversary, and then both of them are worn on the same finger.

In such cases, jewelers need to scan the engagement ring and actually make a replica of it.

Antique ring scanned with D3D-s scanner by D3D-s on Sketchfab

Ukrainian inventors started receiving requests from jewelers and dentists. Such niche demand prompted Nazar and Denis to launch their second Kickstarter campaign - a 3D scanner specifically for jewelers. They launched it a week ago, at the end of June 2019, and have already collected the requested amount - $13,600 out of $15,000. The project was supported by eight people who wanted to get a jewelry scanner. The first supporters will get it for $4000-6000. And in retail, the device will already cost $8,000

“The D3D-s scanner is suitable for both self-employed jewelers and professional teams with experience using ultra-expensive scanners,” the developers note in the project description.

According to Denis Nazarenko, a 5 megapixel camera is installed in the scanner, which is much cheaper than a less accurate 1.2 megapixel camera designed for laser scanners.

Another innovation is mobility. The scanner also has six directions for movement. This allows you to scan figures of any complexity with a light beam. Scanning is fully automatic. You just need to specify the size and click the button.

“When we created the desktop scanner, we wanted to achieve a resolution that would allow us to scan a coin. As a result, adapting the scanner to the needs of jewelers was not a problem. We have added another axis of rotation and reduced the size of the scanner. We've also upgraded the optics and camera, as jewelers don't need color scanning. We also installed high-precision motors,” the developers of the device say.

The price of the device is much cheaper than analogues. The closest model is B9Scan 350 - will cost almost $15,000. At the same time, even the most expensive laser models (for $50,000) cannot provide such a distance between points as the Ukrainian development - 0.010 mm.

Denis and Leonid can now produce 1-2 scanners per month in their office near Kyiv. They work together. Inventors realize that they need investments to establish a full-fledged production.

Therefore, now the inventors have begun to think about attracting investors. As Denis explains, the same American jewelers do not always trust what is written on the site. They need to see the scanner live at some exhibition. For this, inventors will also need additional funds.

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The most accurate 3D scanner was created in Vyshneve. US jewelers in line - Ukraine news, Gadgets

The story of two inventors began about four years ago when they wanted to get high-precision 3D models of small objects, such as coins or figurines. But faced with the fact that the laser scanners available on the market, firstly, are very expensive, and secondly, their accuracy left much to be desired.

The very idea of ​​the scanner was born when Denis Nazarenko was trying to make a model of the statue of Manjushri. “But scanners capable of capturing the smallest details of a model cost at least 17,000 euros and were out of reach for a small company. So we decided to create our own,” the Kickstarter presentation reads.

Who are Nazarenko

In a small office in the town of Vyshneve near Kyiv, father and son set about experimenting. The background allowed them to use deep knowledge from completely different engineering fields.

Leonid Nazarenko began his career at the Antonov plant, which built the world's largest An-225 aircraft. He created models of aircraft from childhood, and then taught schoolchildren to do the same. Leonid had a good understanding of metalworking and a wide range of knowledge in engineering disciplines.

Denis Nazarenko won various competitions in mathematics, physics and informatics. He has been working on software development for many years. And his most famous project is Start Menu X, a convenient alternative to the Windows Start menu, which has been used by many people around the world.

LED vs. Laser

Two engineers found that a laser projector creates a lot of scanning noise, which is detrimental to the quality of the 3D copy. And he has a worthy alternative. The light-emitting diode (LED) beam in combination with good lenses made it possible to achieve noticeably better results.

This photo shows how much noise the laser beam has compared to the LED beam:

Another bonus. This technology does not require expensive projectors and cameras.

Entrepreneurs decided to take their idea to Kickstarter through a partner who lived in Canada. Last spring, they raised over $22,000 to produce their first model, the D3D-s desktop 3D scanner.

According to Denis Nazarenko, who was contacted by the journalist of Liga.Tech , together with his father, they collected and delivered about 10 scanners to investors who supported them with money on a crowdfunding site during the year. A few pieces are still being finalized.

Fashion for second rings

According to Nazarenko, during this time they managed to find the exact niche for their devices - the American jewelry market. According to him, the tradition of wearing so-called shadow wedding bands is widespread in the States. These are additional rings that spouses order in addition to engagement rings, for example, for a wedding anniversary, and then both of them are worn on the same finger.

In such cases, jewelers need to scan the engagement ring and actually make a replica of it.

Antique ring scanned with D3D-s scanner by D3D-s on Sketchfab

Ukrainian inventors started receiving requests from jewelers and dentists. Such niche demand prompted Nazar and Denis to launch their second Kickstarter campaign - a 3D scanner specifically for jewelers. They launched it a week ago, at the end of June 2019, and have already collected the requested amount - $13,600 out of $15,000. The project was supported by eight people who wanted to get a jewelry scanner. The first supporters will get it for $4000-6000. And in retail, the device will already cost $8,000

“The D3D-s scanner is suitable for both self-employed jewelers and professional teams with experience using ultra-expensive scanners,” the developers note in the project description.

According to Denis Nazarenko, a 5 megapixel camera is installed in the scanner, which is much cheaper than a less accurate 1.2 megapixel camera designed for laser scanners.

Another innovation is mobility. The scanner also has six directions for movement. This allows you to scan figures of any complexity with a light beam. Scanning is fully automatic. You just need to specify the size and click the button.

“When we created the desktop scanner, we wanted to achieve a resolution that would allow us to scan a coin. As a result, adapting the scanner to the needs of jewelers was not a problem. We have added another axis of rotation and reduced the size of the scanner. We've also upgraded the optics and camera, as jewelers don't need color scanning. We also installed high-precision motors,” the developers of the device say.

The price of the device is much cheaper than analogues. The closest model is B9Scan 350 - will cost almost $15,000.


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