Non-contact measurement for today and tomorrow

August 31, 2010

Industries have come to expect precision measurement almost to the point of taking it for granted. Even as technology evolves toward lasers and away from traditional contact CMMs, precision measurement continues to include some element of contact. Even laser trackers are contact measurement systems. Most existing non-contact systems require sensors that only measure in close proximity to the surface of interest. Now technology has made large-scale, non-contact precision measurement possible with the advent of Laser Radar.   

Laser Radar precisely measures large-scale geometry without requiring photogrammetry dots, laser tracker spherically mounted retro-flectors, retro-reflectors or probes. Although the technology has been used by U.S. government agencies since 1993, it is now available in a commercial system that can be integrated more easily into remote automated manufacturing systems.

Who needs this non-contact benefit?

The aerospace and automotive industries have typically taken the lead in finding innovative solutions to measurement problems.  Auto industry leaders have incorporated Laser Radar non-contact measurement technology into their design centers for model digitization and reverse engineering. Aerospace firms such as Boeing are also early adopters of the coherent laser radar system, and even antenna manufacturers have improved the performance of their antennas by identifying, modifying and rechecking subtle surface irregularities.

Non-contact measurement speeds manufacturing, improves quality and lowers manufacturing costs. An Laser Radar instrument can be used to accurately align large parts during assembly. It can certify tooling and then monitor repeatability during production. It can be used to scan objects that were previously impossible to scan due to their size, inaccessibility, very complex geometry or delicate surfaces. It operates at the object’s location without a conditioned environment and without the need for expensive tooling. Offset calculations aren’t required because measurements are taken directly from the part surface. The system, whether used indoors or outside, can operate in any lighting and on any surface with a reflectivity of 1 percent or more.

Laser Radar can be used for many applications. It can rapidly sample metal, plastic and composite as-built surfaces and compare them directly to a CAD model. It can gather data over extremely large areas in a contiguous coordinate system and, because operators can accurately measure from key features or reference points as they go, relocating the system eliminates the need for complicated reassembly of data point clouds. For those who want to digitize models or hand lay-ups, data can be gathered in uniform scans with control of point density and area and then be exported directly to a wide variety of CAD packages.

Tool builders can locate and adjust tool positions and features in real time, driving the system to a specific point in space and measuring a part continuously until it is positioned at its nominal location. Operators can also measure tools and surfaces for wear, monitoring surfaces for tolerance and stability and documenting tools and die surfaces. For in-process applications, the system can support robotic positioning and then monitor conditions like orientation, gap, flushness and fit. In addition, it can be used to monitor tool and fixture stability during use without the need to manually collect datum information. A single machine can monitor several manufacturing work cells automatically without the need for operator intervention.

For quality professionals, Laser Radar can perform first-article inspections and be used for incoming, in-process and outgoing quality assurance. Because the instrument can scan a part surface directly, it’s well suited for measuring tight pockets, small holes and otherwise inaccessible areas. For routine maintenance, the system can perform static and dynamic inspections of aircraft, automotive and heavy equipment tooling assemblies. It can monitor deformation of building, tunnel and bridge structures and accurately measure surface fractures that can provide early warning to possible fatigue and structural failure—an especially useful capability after seismic activity.

How it works

The Laser Radar system operates using a sensor to direct a focused invisible infrared laser beam to a point and coherently process the reflected light. As the laser light travels to and from the target, it also travels through a reference path of calibrated optical fiber in an environmentally controlled module. The two paths are combined to determine the absolute range to the point. Huge laser-modulation bandwidth (100 GHz) makes precise measurement possible in a millisecond. The distance measurement is then combined with the positions of the two precision encoders to determine a point on a surface in space.

Looking ahead

Major manufacturers of aircraft, large automotive parts and heavy machines are integrating Laser Radar technology into their manufacturing processes because they don’t want to wait until parts fail dimensional inspection to take corrective action. By embedding the Laser Radar technology into critical processes, they expect to eliminate scrap and increase production speed in a broad range of manufacturing areas.

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Roadshow: Make Measurement Matter

August 27, 2010

Announcing The Make Measurement Matter Roadshow 2010!

15th September 2010

GTMA is Hosting a FREE Make Measurement Matter Roadshow at The Digital Lab at Warwick University.

30 of the top metrology companies in the UK will exhibit, including Nikon Metrology, and there will be extensive networking opportunities in a relaxed environment. These metrology companies are key participants in creating successful engineering solutions for all industry sectors now and for the future.

 Why attend?

  • Receive free access to 30 top metrology companies exhibiting up-to-date industry solutions.
  • Gain first-hand information from top Key Note Speakers
  • See brand new technology housed in this state-of-the-art building.
  • GTMA, by hosting the event, is providing a focal point for technology transfer for the science of measurement in manufacturing.
  • Register now online and receive FREE refreshments and buffet lunch.

The Make Measurement Matters format provides a unique opportunity for metrology professionals to discuss their measurement requirements with specialists from the UK’s premier metrology suppliers – gathered together under one roof for one day only – in addition to viewing the latest technical developments in terms of both products and applications.

Julia Moore, GTMA CEO, explains; “Modern manufacturing makes ever-increasing demands on the measurement capabilities of companies at all stages in the supply chain.  From the simplest gauges to the most complex electronic devices – measurement really does matter. 

 “Naturally, metrology is critical throughout the high-tech manufacturing arena, and the breadth of experience and range of products demonstrated at the roadshow will provide the solutions to many of the issues faced by manufacturing today.” 

The event has been designed to provide both exhibitors and visitors with extensive opportunities to network with others in the industry, while also keeping abreast of the latest developments in the field. 

Click here for more information

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Mill Large Castings in Record Time with iSpace

August 26, 2010

METROLOGY MAKES OR BREAKS LARGE MACHINED CASTINGS 

“Overall, iSpace is an innovative large-volume inspection system that features multi-user and wireless operation and requires hardly any calibration or maintenance,” concludes Francky Demeester. “These unique features have a drastic impact on measurement productivity and consistency, making iSpace the preferred choice for a wide range of large-scale industrial measurement applications in automotive, aerospace and general industries.” Typical examples of applications are vehicle-body inspection, aircraft fuselage or component measurement, or large volume applications that require concurrent operator activity. 

 Industrial milling is the final step in the fabrication process of huge metal castings for power plants or large engines for ships or trains. Compared to traditional methods used to specify precise marking positions for milling, Nikon Metrology iGPS allows alignment and marking of voluminous castings to be performed 5 to 10 times faster. Fixed or portable Nikon Metrology iSpace configurations provide higher inspection consistency and productivity by transforming the production facility into a metrology-enabled area. Within the activated measurement volume, multiple users can simultaneously operate wireless iProbes to align and mark several castings simultaneously. 

For the final finishing of large castings, manufacturers often decide in favor of having parts milled by specialized milling companies. To ensure correctly machined castings, operators need to inspect the geometry of raw casting parts and apply marks that precisely indicate where milling or drilling is required. Metrology is a key element to make or break these voluminous machined parts, as incorrect milling specifications can lead to devaluation of high-value castings. Traditionally, parts are aligned and marked using horizontal-arm CMMs or immense, expensive surface plate marking tables, which typically require a lengthy and sturdy measurement procedure. As these tables are fixed installations, casting specimens need to be shipped to the measurement facility where they are measured sequentially, causing poor productivity and considerable overhead logistics.

 

According to Francky Demeester, VP Business Development at Nikon Metrology Continental Europe, Nikon Metrology iGPS easily clears the productivity bottlenecks of traditional metrology equipment.

 

“This innovative metrology solution is ideally suited to measure these voluminous castings on-site. Nikon Metrology iGPS consists of a modular array of laser transmitters attached to walls or positioned on tripods that activate a large-scale inspection volume. Anywhere within this volume, operators can flexibly determine the 3D coordinates of any casting surface point, and apply marks on the appropriate positions using wireless handheld iProbe devices. To accurately measure the position of the iProbe, the sensor is equipped with multiple receivers that are tracked by multiple iSpace transmitters. Working in a metrology environment where all acquired data refer to the same invisible reference axes system offers distinct productivity and consistency benefits.  Measurements indicate that on average, iSpace slashes the alignment and marking of a single casting from 6 hours to approximately 1 hour.” 

 

FAST WIRELESS MEASUREMENT AND MULTI-USER SUPPORT

 

Depending on the desired inspection volume, an iSpace configuration of 4 or 8 transmitters is required to provide full iGPS coverage for industrial applications. “When measuring a point with the wireless iProbe sensor, it captures the invisible laser signals from the surrounding iSpace transmitters,” explains Francky Demeester. “A central metrology server – which manages all acquired data using Nikon Metrology Surveyor software – calculates the probe-determined coordinates and transmits these data to a portable client-server that runs the measurement software. The operator uses a rugged PDA to visualize and operate the measurement software.  In an 8-transmitter iSpace configuration, iProbe reaches approximately 250 micron absolute measurement accuracy across the entire inspection volume.”

 

Francky Demeester further states that iGPS technology intrinsically supports simultaneous use of multiple iProbe sensors, whereas traditional metrology solutions only support sequential inspection. “This makes it possible to measure and mark multiple castings at the same time, effectively doubling or tripling the inspection productivity. The inspection volume of an 8-transmitter setup covers up to 1200 square meters, which easily fits 4 to 6 large castings. Productivity further increases with iProbe, which is integrated as a measurement tool in PowerINSPECT software that can be used both for part alignment and inspection. Unique alignment measurement plans can be pre-programmed for each part. Predetermined points can be programmed into a guided inspection plan or measured on the fly.”

 

  

An important advantage of the client-Server approach of the iSpace system is that different inspection plans and reports are automatically generated in a clear, consistent and transparent fashion. As a result, these reports can be interpreted by both production management as well as customers. With traditional systems, reports are often filled out manually by different persons, leading to inconsistencies or incomplete results. 

  

To support flexible part inspection, the styli of measurement devices are interchangeable with longer styli to access deep pockets. In addition, iProbe sensors are equipped with kinematic mounts that allow for quick and easy changeover between inspection stylus and part marking add-on. A marking head consists of a fine drill that precisely marks the metal through the paint layer. iProbe even supports integration with other specific instruments, such as ultrasonic sensors to locally measure the wall thickness or locate defects in the casting. 

 

Learn more about indoor iGPS technology

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Kautex speeds up fuel tank quality control by 30% with XC50-LS laser scanner

August 25, 2010

Top-100 automotive supplier Kautex relies on Nikon Metrology XC50-LS Cross Scanner on LK CMM to verify the production quality of composite fuel tanks. Kautex engineers set up and execute automatic measurement routines that speed up the serial inspection process for fuel tank by 30%. Incorporating three lasers in a cross pattern, the scanners capture the finest details of freeform surfaces and critical geometric features in one go. The insight gained by automatically digitizing fuel tanks and generating graphic Focus reports enables Kautex to tackle problems that were hard to solve in the past. 

High-pace production lines cranking out fuel tanks 

Tier-one supplier Kautex manufactures fuel tanks that meet tight environmental standards for Chrysler, Ford, GM, Honda, Toyota and other major car brands. To guarantee smooth assembly, the shape of fuel tanks must fall within strict geometric tolerances to match the allocated space envelop within the vehicle. To monitor the quality of all its fuel tank production lines in the US, Kautex installed the same metrology equipment in Avilla, Indiana and San Antonio, Texas. In multiple shifts, metrology professionals at both production plants run inspection on LK horizontal-arm CMMs equipped with XC laser scanners and tactile sensors 

Kautex runs laser scanning to efficiently capture the freeform surfaces and geometric features of fuel tanks.

“Serial production of fuel tanks is a swift but complex process that cranks out a new specimen every 2 minutes or so. The advanced blow molding and cooling technology that is applied requires optimum dynamic pressure and temperature conditions,” says Don Morse, Quality Manager for Kautex in Avilla, Indiana. “These boundary conditions are of capital importance as well as the blow molding fixtures that shape multi-layer base material that is being air inflated. To meet the desired dimensions at the end of the cooling stage, we systematically verify the geometric quality of serial produced tanks.” 

Radically reducing inspection preparation time 

To prepare an inspection routine for a new fuel tank type, Kautex’ quality team sets up an inspection macro in Focus Scan software. Defining the dynamic motion and orientation of the XC50-LS scanner is quite straightforward. “Significant tolerance on scanner-to-part distance drastically reduces head indexing as well as the number of CMM movements,” says Michael Boltz, CMM Specialist for Kautex. “It is much easier to define scanner motion and orientation than to program the hundreds of touch sensor points for a tactile inspection job. Most of the time, we prepare inspection macros off-line, allocating CMMs exclusive for digitizing fuel tanks.” 

Laser scanning also reduces or eliminates the effort that is required to align fuel tanks on the CMM. As fuel tanks have 

Inspection macros are typically prepared off-line, allocating CMMs exclusive for digitizing fuel tanks.

sufficient weight and rigidity, there is no need to invest in complex clamping and fixation tools. Boltz explains that a fuel tank is presented for inspection by positioning it on vertical stands that support the tank in free-state condition. “We select the locations for the vertical supporting bars such that tanks only rest on their datum references. In general, this approach is sufficient to immediately start the automatic laser scanning routine. This is a major benefit compared to tactile inspection jobs, which require us to perform a tactile pre-alignment procedure first.” 

Geometric features captured quickly and in great detail 

Critical fuel tank features that require detailed verification are datum reference points as well as metal or plastic tube/hose connection pieces that are molded in into the tank surface. 3 lasers incorporated in a cross pattern enable the XC50-LS scanner to capture all 3D details of geometric features and freeform surfaces in a single scan. This compares favorably to line scanners that digitize features multiple times under different angles to capture all details
“The scanning routine for an entire fuel tank, covering freeform surfaces and geometric features, is completed in the order of 30-40 minutes,” says Boltz. “Laser scanning outperforms tactile point-by-point acquisition technology, both in speed and number of inspection points. A point cloud of a fuel tank consists of several millions of measurement points, which is further reduced by an innovative filtering algorithm. Currently, we run quality control with sampling rates of 1 in every 50 to 100 fuel tanks.”

Tackling problems that were hard to solve in the past 

Boltz explains that the inspection process at Kautex is embedded into the digital CAD-centric manufacturing process. An advantage of digitizing fuel tanks up-front is the flexibility to run analysis at any later time. After aligning the acquired point cloud with the nominal shape, Focus highlights geometry deviation between fuel tank and CAD or between 2 tanks. Automatic geometry comparison is performed either using global best fit or alignment on the basis of datum reference points. “At a single glance, we see where geometry tends to go out of range. We apply different fitting methods to easily distinguish between inaccurate fuel tank geometry and incorrect datum point levels. Quickly gaining relevant insight is critical for us in efficiently tuning the mechanical blow molding fixtures used in production. We share graphic reports with colleagues and customers, who interactively analyze them using the license-free Focus Viewer.” 

The use of different fitting methods enables us to easily retrieve incorrect datum point levels.

Nikon Metrology laser scanning is a success story,” concludes Morse. “The scanners help us save time in every step of the metrology process, including measurement preparation, execution and analysis. Overall, the digital inspection process that we have implemented speeds up metrology operations on average with 30%. Instead of entering discussions with Excel tables, we now share graphic Focus reports to drive technical consultation and efficient decision making. The insight that we gain from these reports enables us to tackle problems that could not be solved in the past, and increase our technical credibility towards customers.”

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PSA Peugeot Citroën quadruples scanning productivity with Laser Scanner

August 24, 2010

After upgrading optical metrology equipment with a handheld Nikon Metrology ModelMaker D (MMD) scanner for non-contact 3D measurement, PSA radically increased scanning productivity. Featuring a 100 mm laser stripe width and all-digital operation, the MMD enables PSA metrology engineers to complete detailed geometric scans of small to large vehicle body parts in record time. They can take the portable systems to any location or site, set it up and measure parts on the spot. The perfect interaction between localizer, scanner and software speeds up scanning throughput and decreases post-processing and analysis work. Laser scanning also enables PSA to systematically digitize body frames, doors, windshields and other parts, and use the acquired data to validate numerical calculations, ultimately contributing to fewer mechanical prototypes. 

A single system that is suitable for many metrology tasks 

Europe’s second-largest carmaker has a history with digitizing that dates back to 2001. Since then, PSA has gained significant experience in applying laser scanning to digitize the geometry of vehicle body parts of prototype or early production vehicles. “Dimensional accuracy is of prime importance in vehicle body assembly,” states PSA Poissy’s metrology department. “During the assembly process of a trunk lid, for example, the geometry of the lid slightly changes due to the mechanical interaction between frame, glass, trim, lock, etc. When we prototype vehicle body parts, we closely monitor geometry using the Nikon Metrology MMD to ensure assembled body elements will fit perfectly. The use of a wide variety of materials – including composites and plastics – sets specific manufacturing and measurement challenges, and increases the need for reliable and efficient metrology solutions.” 

ESP enables the operator to scan a shiny logo as well as the dark base surface all at once.

Physically the largest part that PSA metrology engineers scan using the handheld Nikon Metrology MMD is a body-in-white structure. Positioning the articulated measurement arm at one or two locations is sufficient to digitize a hood or the entire backside of a vehicle body, for example. Metrology engineers at PSA also use the Nikon Metrology MMD to scan interior trim parts, light units and various other parts. To deliver top-quality data for different surface types even under difficult lighting conditions, the Nikon Metrology MMD scanner features ESP (Enhanced Sensor Performance). ESP is an algorithm that automatically adapts camera and laser settings to accommodate varying surface shape, color and reflectivity. This helps PSA engineers accurately deal with sheet metal, composites and plastics – without having to apply spray or other preparation measures. With a laser line that counts as many as 1028 measurement points, the scanner reliably digitizes freeform surfaces as well as the edges of individual features. Another reason why PSA opted for a non-contact scanning solution is the ability to reliably digitize softer trim material, eliminating the risk of scratching fragile components or pressing flexible parts. On finished cars, the system serves as an optical gauge for flush & gap inspection between body panels. 

Reducing scanning throughput time and post-processing effort 

When scanning a vehicle body part, a PSA engineer operates the laser scanner while the scanned surface takes shape in 

The process of acquiring scan data to delivering optimized polygon mesh is managed by KUBE software.

real time on the laptop screen. The displayed information provides instant feedback regarding scanning speed, coverage and progress. Scanning takes place at a relentless pace, thanks to the scanner’s extra large laser stripe and fast digital signal processing. “The result of the scan is a cloud of hundreds of thousands or even millions of measured surface points,” explains a PSA scanner user. “After filtering the point cloud to eliminate excess points, we generate a polygon surface mesh and optimize it.  The entire process is smoothly managed by Nikon Metrology KUBE software.  The tight integration between scanner software and hardware not only streamlines the scanning process, but also cuts the remaining post-processing effort in half compared to the previous scanning solution.” 

According to PSA Poissy’s metrology department, the metrology team represents a centralized unit that runs measurements at PSA sites across France to support vehicle development from prototype to release. “Regardless of whether measurements are scheduled to take place in the PSA Poissy facilities, or at PSA sites in Rennes or Sochaux, for example, metrology engineers take the portable system with them and start scanning right away. This pragmatic approach offers maximum measurement flexibility and saves on logistics by reducing transportation of vehicle body (parts) to our metrology laboratory.” 

Scanning jobs performed four times faster than before 

PSA applies laser scanning to verify the shape of lighting units and their positioning onto the body.

Besides monitoring the geometric quality of vehicle body parts – Nikon Metrology laser scanning forms an essential step in verifying numerical calculations PSA performs as part of virtual simulation. Metrology engineers at PSA systematically use the Nikon Metrology MMD scanner to acquire digital 3D copies of structural components such as body frames, doors, windshields and other parts. This touch with reality increases simulation accuracy and helps reduce the number of lengthy and costly physical prototype cycles. “Overall, when using the all-digital Nikon Metrology laser scanner with its wide laser stripe, we are able to complete scanning jobs four times faster than before,” says the PSA scanner user. “Productivity improvements of this degree enable us to take on additional metrology assignments and yet increase the level of data quality, all within the current capability of our metrology team.” 



Click here to learn more about ModelMaker handheld laser scanners

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Measure Large-Scale Telecommunication Systems

August 23, 2010

Telecommunication is the transmission of messages or capture of data over significant distances. Parabolic antennae and space telescopes are examples of large-scale telecommunication systems that can be measured using Nikon Metrology solutions. 

Optics
Assembling advanced optics is subject to tight-tolerance inspection. Since the optical path of larger instruments is relatively long, Nikon Metrology’s Laser Radar is ideally suited to perform measurements on these systems. In many space-related applications, there is no other sensor capable of meeting the metrology requirements. Laser Radar operates with a graphical software interface supporting both manual and automatic use by a single operator. 
GPS satellite NASA

As part of an ongoing space telescope program, the Laser Radar measures mirror features and large mechanical structures holding sensitive flight hardware without touching the specimens. This metrology system automatically verifies optical component alignment because distance limits can be established for near and far focus by managing the focus of its measurement beam. Thanks to its ability to sample both specular and diffuse material surfaces, Laser Radar can determine mirror alignment directly.

For accurate inspection of smaller parts and assemblies, Nikon Metrology CMMs are deployed and equipped with tactile and laser sensors, such as the LC60Dx and XC65D.

Alternatively, individual parts can be measured using CNC video measuring systems, such as iNEXIV and NEXIV systems, and industrial or measuring microcopes.

Related products: Laser Radar, LK CMM, LC60Dx, XC65D, iNEXIV, NEXIVindustrial microscopes, measuring microscopes

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Portable CMM Takes Center Stage

August 20, 2010
This South Dakota production plant found a faster way to verify large production fixtures and manufactured parts of construction and agricultural equipment by positioning a portable optical CMM on the production floor and measuring points of choice right away using a wireless tactile probe.
K-Series’ inspection volume fits a complete skid steer vehicle with loader moved in upward position.

The wireless SpaceProbe and graphic operator assistance speed up inspection.

K-Series supports fast inspection of geometric features and surface points in and around skid steer loaders.

Visual feedback highlights measurement validity and displays where the next point is located.

Engineers at the Gehl South Dakota production plant in Madison found a faster way to verify large production fixtures and manufactured parts of construction and agricultural equipment. They simply position a portable K-Series Optical CMM from Nikon Metrology on the production floor, and measure points of choice right away using a wireless tactile SpaceProbe. This ergonomic metrology system enables Gehl to halve geometric verification time-spending on chassis and driver compartment, and yields deeper insight when troubleshooting equipment prototypes.
Farmers and construction workers value compact Gehl skid loaders, telescopic handlers, track loaders, excavators, all-wheel-steer loaders, articulated loaders and asphalt pavers for their ingenuity, innovation and reliability. At this production site in Madison, engineers manufacture skid and track steer loaders and telescopic handlers that have been designed at the company headquarters in Wisconsin. To monitor the production quality of this compact outdoor equipment, Gehl staff run geometric measurement right at the production line.

“Quality control involves the inspection of selected geometric features and surface points on steel parts after being stamped, drilled, and painted,” explains Joseph Palmiotto, the quality assurance manager for Gehl in Madison. “We not only monitor finished parts, but also verify mechanical fixtures used for part production and assembly of chassis and driver compartment, for example. To more efficiently execute metrology tasks on components of various sizes, we moved from an articulated measuring arm with a limited reach to a Nikon Metrology K-Series system that covers a considerably larger measuring volume early last year.”

Read the rest of this article in Fabricating & Metalworking magazine

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Meet the Expert: Optical Products

August 19, 2010

Jay Elepano is the Product Marketing Manager of optical products for Nikon Metrology.  After spending almost seven of his 12 years in metrology at Mitutoyo, he joined Nikon Metrology in 2007.  Jay has a BSME from Marquette University and an MBA from the University of St. Thomas, where he focused on international business management, finance, and operations. 

In addition, Jay is vice-chair on the board of directors for ECHO Minnesota, a non-profit community outreach organization serving English-as-a-second-language communities in Minnesota, where he currently resides.

Jay is the proud husband to Julie Elepano, who is a marketing manager for 3M.  Together they enjoy music, golf, wine, and watching sporting events.  They root for the same teams, except for football, where Jay is an avid Vikings fan and Julie is a loyal Packer fan.

Jay is extremely proud to be representing the Nikon brand and aspires to be a valuable asset for the corporation for many years to come.

Read one of Jay’s featured articles about optical metrology

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iGPS – Large Scale Assembly

August 18, 2010

The successful use of 3-D technology in working with large objects in a manufacturing environment often has less to do with “measuring” and more to do with the location and alignment of parts and fixtures. A case in point is the recent implementation of GPS technology into 3-D measurement.

Mention the term “GPS” to the average person and most will associate it with small earth orbiters that can provide surveillance or driving directions. However, an exciting new system known as Indoor GPS is now being used by many manufacturers to perform large-scale measuring and alignment tasks. Indoor GPS doesn’t use satellites; instead, it works by installing an array of infrared laser-pulse transmitters around the object to be measured. These objects are generally large manufactured items such as parts and assemblies for aircraft, automobiles or ships.

Sensors pick up the signals from the transmitters, and calculate angle and position based on the timing of the arriving light pulses. An amplifier converts the analog signals into digital pulses, and a receiver converts the pulses into angle data. Indoor GPS network software processes the angle data into highly accurate position information and then makes this information available to the client network, whether on the shop floor or off-site. Because the number of transmitters that can be used is practically unlimited, the size and shape of the work area can be fully defined by the user. For large assemblies, more transmitters means that measurement, inspection and alignment can be performed accurately and without having to move or reset equipment. This flexibility is the  key to the utility of this technology.

Click here for more details on indoor iGPS technology

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PartnerTech bolsters fast-turn NPI build capability with X-ray technology

August 17, 2010

PartnerTech, one of Europe’s leading contract manufacturing companies, selected a Nikon Metrology X-ray inspection system to test high-complexity boards featuring BGAs and CSPs. The company installed the inspection system at its 2,700 square meter UK manufacturing facility at Poole in Dorset. The new kit will further improve PartnerTech’s apability to provide customers with fast-turn builds of highly complex electronic and mechatronic products featuring devices such as BGAs and CSPs.

Need for automatic X-ray inspection using angled views

The Nikon Metrology inspection system provides the highest resolution and magnification possible within a compact X-ray system for quality control, research and failure analysis. The machine has the ability to inspect substrates at steep angles of up to 75 degrees and is designed for 100% BGA and µBGA, multi-layer board and PCB solder joint inspection, with quick analysis of BGA ball wetting, attachments, cracks and delaminations.  “We do a lot of rapid new product introductions (NPI) for customers at the Poole facility, and many of the products feature unusual devices and geometries that cannot be visually inspected,” says Rex Waygood, Technical Manager at PartnerTech’s Poole facility.
X-ray inspection of electronic components

“We therefore needed a system that would be able to perform automatic X-ray inspection (AXI) using angled views and test fine-pitch devices as well as BGAs and CSPs. Most importantly, we needed a system that would give us complete confidence that boards, particularly products that we have not built before, would be assembled correctly the first time.”

X-ray fits well in full range of product lifecycle services

PartnerTech in Poole offers its customers the full range of product lifecycle services, including product design/development, prototyping, NPI, test solutions, PCB assembly (PCBA), full-system build, logistics, distribution and after sales. The company works in partnership with OEMs across medical, aerospace & defence, industrial and telecom markets.

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Messier-Dowty selects Nikon Metrology CMMs to inspect landing gears

August 16, 2010

When Messier-Dowty was selected to produce the nose and main landing gear for the new Boeing 787 Dreamliner, the UK aerospace manufacturer initiated the use of model-based definition throughout the design, manufacturing engineering, production and inspection processes at its operations in Gloucester, UK, and Bidos, France. It is the first major program for which Messier-Dowty has used model-based definition.

Three-dimensional CAD models had been used in the company’s design, and manufacturing engineering departments for more than a decade to develop and validate design definition, functionality, finite element analysis and manufacturing processes. However, the programming of coordinate measuring machines (CMMs) to inspect components after machining had been carried out traditionally using 2D toleranced drawings derived from 3D data. This was because there was no geometric dimensioning and tolerancing (GD&T) information attached to the electronic model.

Now, using Dassault Systems’ Catia V5, 3D CAD models for the Dreamliner landing gear components are annotated using a Catia workbench named FT&A (functional tolerancing and annotation). The FT&A workbench provides and helps control the application of GD&T – definitions that are attached to the 3D model, and enables the electronic 3D model to contain the comprehensive product definition.

Downstream, specific manufacturing engineering, production and inspection applications are being implemented to realize the significant benefits available with model-based definition. A sister product to CATIA in the Dassault portfolio, Smarteam (PDM), manages all the product data throughout the entire process.

CMM manufacturer and software developer, Nikon Metrology, was chosen by Messier-Dowty as its metrology partner to underpin inspection of the Boeing 787 landing gear components throughout the manufacturing process. Two Nikon Metrology LK Evolution CMMs with a 2-meter bridge and 4-meter X-axis were installed. The turnkey contract involves training of the Messier-Dowty inspection team as part of a full, on-going service and support package.

Principal engineer Pete Willis, responsible for the development of model-based definition inspection at Messier-Dowty’s Gloucester facility, advised that he and his overseas counterparts have standardized on Delmia Inspect – also Dassault software – to create DMIS standard measuring programs off-line for the CMMs. Delmia will output DMIS programs that interface with Nikon Metrology CAMIO CMM software to allow users seamless use of this programming, simulation and verification solution.

Mr. Willis says that the system aims to satisfy three key issues related to model-based definition inspection. The first is to avoid any translation of CAD authority data to preserve the integrity of the design definition. Secondly, the solution reads the FT&A attached to the model and thus minimizes operator input during the development of CMM programs, improving the accuracy and integrity of the inspection process.

Lastly, the system provides a rules-based solution to standardize the methodology of the inspection process. The predefined rules relate the feature type, tolerance and feature size to determine the appropriate probing strategy for the specific feature, leading to a high degree of measuring consistency.

Analog scanning has been included on the new CMMs to collect large amounts of data efficiently on the manufactured components in fast cycle times, leading to a greater understanding of the characteristics of the production processes.

“We did not want to just buy another CMM,” stated Mr. Willis. “Our business is making landing gear, and we were looking for a metrology solution provider that would work with us to further improve our products.

“After an extensive evaluation of the leading suppliers, we opted for Nikon Metrology, as it demonstrated a commitment to tailoring a metrology package that dovetailed with our requirements.”

In this connection, he cited various aspects of the project. First, Nikon Metrology extended its LK Evolution machine range to accommodate Messier-Dowty’s requirements for a large bridge CMM. Both new CMMs, each with a large measuring volume, will enable Messier-Dowty to load a major structural component, such as a machined titanium truck beam or any one of the smaller components, at one end of the machine while inspection is in progress at the other. Alternatively, the 4 meter X-axis will allow an entire Airbus 340 main fitting, for example, to be inspected without the need for repositioning. Similarly, larger machined landing gear forgings could be inspected with ease.

Another Nikon Metrology innovation, the development and introduction of which has been supported and accelerated by Messier-Dowty, is automatic sensor management. Instead of wasting between 10 and 25 minutes calibrating a series of probes before each new job, an automated system has been developed which will calibrate all the probe configurations held within the racks during a single weekly routine, which will then be used throughout the following week. The unattended calibration process is initiated as an ‘out of hours’ timed event, typically during Sunday afternoon so that the machines are ready and operational at the start of the Monday shift.

A 20-station Renishaw rack is being fitted to each machine and Mr. Willis is in the process of rationalizing the probe head / stylus combinations so that a maximum number of inspection functions can be performed by a core suite of probes. One of the capabilities being built into the two Nikon Metrology CMMs is remote system monitoring. Apart from giving a management overview of machine usage, this will also hold real-time data on the remaining service life of all probes, ensuring that one nearing the end of its useful life is not deployed for a new measuring routine.

Other Nikon Metrology developments, already in the pipeline but speeded by Messier-Dowty’s leading-edge requirements, included the interfacing of Delmia Inspect with Nikon Metrology CAMIO software. Mr. Willis also recognizes that Nikon Metrology  software is in the vanguard of integrating other third party software, which may be of use to Messier-Dowty, such as the products from statistical analysis and reporting software company, Q-DAS.

Nikon Metrology is able to provide total solutions for 3D digitization, inspection and reverse engineering, should these be required in the future by Messier-Dowty.

Mr. Willis concluded, “Migration from 2D drawings to a 3D model-based definition manufacturing and inspection environment is the most significant and challenging development that I have seen during my 30-year career in aerospace engineering”.

“We are now focused on developing our processes to exploit the model-based definition environment and are looking forward to reaping the productivity benefits and exceeding our customers expectations for quality, performance and cost.

About Messier-Dowty

Messier-Dowty, a SAFRAN group company, has entered the detailed design phase of the Boeing 787 landing gears. The design activity is concentrated at the company’s Seattle office and staffed with engineers from Seattle and from Messier-Dowty sites in Toronto, Canada, as well as from the UK and France.

The first sets of 787 landing gears will be used for Boeing’s aircraft systems rig. Subsequent sets will be used for development testing in-house at Messier-Dowty, undergoing a complete program of testing through to certification, followed by gears for flight-testing at Boeing.  Production for the 787 will take place at Messier-Dowty’s various manufacturing facilities around the world.
 

 

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Posted by peppercom

Learn to Shoot Like a Pro at Nikon School

August 13, 2010

Nikon School will inspire your digital SLR photographic efforts, whatever your level of experience. For more than 30 years Nikon School has been helping photography enthusiasts master new techniques and improve their picture-taking skills by providing clear, direct information on a wide range of technical and creative topics.

These one-day seminars are offered all over the country, and begin as early as September.

Click here to see the latest Nikon digital SLR cameras.

Watch the Nikon School video:

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Posted by Metrology Solutions Provider

Laser Scanner speeds up body geometry verification at Volvo Cars Gent

August 12, 2010

The innovative Nikon Metrology Cross Scanner is used at Volvo Cars Gent to further accelerate the design-through-manufacturing process for its brand new Volvo XC60 crossover vehicle. By digitizing physical sheet metal and plastic body parts and virtually assembling vehicle bodies in software, Volvo engineers completed pre-production geometry verification nearly twice as fast! 3D laser scanning technology, point cloud processing and virtual assembly shortened physical evaluation of prototypes and eliminates the need for costly specialized verification tooling.

BODY ASSEMBLY ON THE CRITICAL VEHICLE DEVELOPMENT PATH

Volvo Cars built up a solid reputation in terms of vehicle safety, environment and design. Recently, the Swedish car maker released the brand new Volvo XC60, which is stirring up the crossover vehicle segment. The design and manufacture of this innovative vehicle body required the coordination of many different groups. Sheet metal stamping and welding, in combination with the use of new materials and joining technologies, set ever-tougher geometric challenges. Process and product tolerances, as well as material and equipment behavior, can influence body geometry, when shifting from the vehicle body CAD model to the physical nominal model, and finally to the mass-produced car. The position of edges, holes and other geometric features plays an essential role in correctly assembling the different body parts of a passenger vehicle.  Belgium-based Volvo Cars Gent and Nikon Metrology participated in a project that aimed to streamline the pre-production phases by simplifying the geometric body verification process. Both companies joined forces to develop a new geometric verification method for vehicle bodies, which builds on a digital inspection process using 3D scanning and virtual assembly. This method provides better insight and effectiveness compared to traditional body tuning, which involves extensive tactile inspection, physical part conflict analysis and complex verification tooling.

GROUND-BREAKING 3D LASER CROSS-SCANNER TECHNOLOGY

In close collaboration with Volvo Cars, Nikon Metrology optimized its existing cross scanner to match the performance level required to drive the new geometric verification method. We jointly integrated the laser scanner for use on horizontal-arm CMMs, and increased the scanner’s field-of-view depth. The increased scanning standoff distance range offers higher measuring flexibility and better access to clamped body components. The cross scanner incorporates 3 laser beam / digital camera sets, each shifted 120 degrees in position. This allows the laser scanner to capture slots, sleeves, holes and other features in a single scan. Although inherently designed for scanning geometric features, the cross scanner is also suitable for digitizing 3D surfaces and edges. The positions of features and edges are imperative to correctly mate parts and assemble car bodies.  The development work also impacted laser optics technology and digital data processing. The cross scanner design has been enhanced to flexibly deal with all material types and colors without the use of spray. Now, reflective sheet metal as well as painted surfaces can be captured quickly and reliably. Laser scanning generates point cloud data at high scan rates, which by far outperform tactile point-by-point acquisition technology. Furthermore, it is much easier to define the linear and polygon scanner travel paths than to specify individual touch sensor points for a tactile inspection job.

FASTER AND BETTER VOLVO XC60 BODY GEOMETRY VERIFICATION

In the pre-production stage at Volvo Cars, metrology engineers scan sheet metal and castings (steel and aluminum) as well as composite and plastic body parts. After acquiring data at approximately 20 micron accuracy, they filter the resulting point cloud, and analyze geometry against nominal CAD data. Volvo Cars relies on digital graphic reports to evaluate the parts, and streamline supplier interaction with regard to adjusting molding and stamping equipment. Digital component verification only requires standard holding fixtures, whereas traditional inspection methods demand costly dedicated positioning and fixation tooling.  After digitizing individual parts, engineers align and virtually assemble sheet metal, interior, exterior and chassis components in software in order to build a complete virtual vehicle body. Even before body parts are physically assembled, the new geometric verification approach already gives information about potential part fitting issues. To run specialized investigations, virtual body assembly models are loaded into dedicated software for reverse engineering, variation analysis, and spring-back prediction, for example. Analysis between scanned and numerical vehicle body models enables engineers to efficiently tune component geometry to fall within the assembly processing window.

VERIFYING SURFACES AND FEATURES USING HANDHELD LASER SCANNERS

The collaboration project with Volvo Cars also contributed to the development of K-Scan, a handheld laser scanner with a single laser stripe for in-situ inspection. An optical CMM continuously tracks the scanner so that the operator can freely walk around and take scans in an area that spans the entire vehicle. Volvo engineers use K-Scan to verify flush & gap, body deformation and static/dynamic geometry on prototype or early production vehicles. Color-coded visual inspection reports illustrate how flush & gap evolves along complete spines in between hood and front fender, for example. Optical handheld verfication is used in special applications  where manual methods fall short, or in case an urgent issue comes up that needs fast troubleshooting.  In summary, the new process reduces times for matching loops, and realizes an important cost reduction for test materials and screwed body, nominal blue bucks and dedicated fixtures. Virtual verification on the basis of 3D scanning is a major step forward. This project received the Henry Ford Technology Award in Detroit. 3D scanning covers reverse engineering of clay models, virtual geometry verification of vehicle body structures, and geometric feedback data collection on finished cars.

REDUCTION IN NUMBER OF GEOMETRY ITERATION LOOPS

When preparing production rollout for the Volvo C30, the virtual body geometry method was applied and evaluated for the first time. In parallel, traditional tactile verification methods were performed to set benchmarks in terms of inspection precision and throughput. When ramping up Volvo XC60 production, the company actually managed to reduce geometry iteration loops and the lead-time of individual loops. Fewer physical evaluation prototypes also reduce material scrap and decrease expenditure of complex verification tooling, such as body-in-white cubing.  3D scanning technologies are already well accepted at Volvo Cars where they are used in different stages of the car manufacturing process. Non-contact metrology is systematically applied in the early design stages when engineering styling by digitizing clay models. In pre-production, engineering digitizes body parts and body-in-white structures to optimize part manufacturing and assembly. After kicking off serial production, specific aspects of car components or full cars are scanned to serve as SPC samples for quality monitoring and product audit purposes. For the future, laser scanning is seen as a key enabler of in-line quality control.  The successful project was partially funded by IWT, a Belgian institution supported by the Flemish Government that encourages technological innovation projects, and managed by Flanders’ DRIVE, an innovation and collaboration platform for the Flemish vehicle industry.

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Posted by peppercom

Warp-speed paint job for Joe Gibbs Racing #20 NASCAR

August 11, 2010

OK – so this doesn’t exactly relate to metrology, but Nikon Metrology is a proud sponsor of Joe Gibbs Racing, and I thought this video was really cool.

If you like the video, please rate it above.  Thanks!

Click here to watch the video on YouTube.

The No. 20 GameStop Toyota is wrapped in Harry Potter Lego video game colors for the NASCAR race in Chicago. This is a one-time only paint scheme.

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Posted by Metrology Solutions Provider

CARAT-Duchatelet armors VIP vehicles using 3D scanning

August 10, 2010

 

CARAT-Duchatelet integrates the highest level of security and luxury into prestige vehicles.

As the world leader in armored prestige vehicles, CARAT-Duchatelet counts sheiks, kings, presidents, CEOs and other wealthy VIPs among its customers. Before stretching and armoring luxury vehicles, CARAT-Duchatelet engineers remove seats and trim, and scan the entire vehicle body using Nikon Metrology K-Scan MMD. The geometric 3D scan acquired by this portable metrology solution forms the basis for drastic vehicle modifications and detailed craftsmanship. The portable Nikon Metrology K-Scan MMD enables them to ergonomically capture vehicle interior and exterior in one pass.

Adding security and luxury to prestige vehicles

Far away from mass and series production, CARAT-Duchatelet integrates the highest level of security and luxury into prestige sedans, limousines and off-road vehicles. Currently, over 40 Heads-of-State from Africa, Europe, the Middle East, Far East and former Soviet Republics are chauffered in CARAT-Duchatelet vehicles. To armor the VIP vehicles, CARAT-Duchatelet engineers and craftsmen stretch vehicles both in length and height, and create personalized luxury interiors. Today, the Belgian company is recognized as the world leader in armor integration and the manufacture of specialty vehicles in the automotive industry. 

At CARAT-Duchatelet, the armor development and integration process starts with crafting armor component shapes in wood. Since wood is easy to manipulate, engineers quickly gain a rough idea of how new armoring will fit into a particular vehicle brand or type. This is where reverse engineering comes into play. “Using Nikon Metrology K-Scan MMD, we scan the entire vehicle body; one time with the wooden parts attached and one time without,” says Eric Appelmans, R&D engineer at CARAT-Duchatelet in Liège, Belgium. “This approach allows us to accurately digitize the vehicle body and generate digital CAD information. Detailed CAD data provides the insight we need to create an invisible bullet-tight cage by optimizing the design of steel plate and glass armor parts.”

Optical CMM provides unmatched scanning comfort
 
The setup of the Nikon Metrology K-Scan MMD system is fairly straightforward. The engineer positions the camera of the Optical CMM module next to the vehicle body. The three high-resolution CCD cameras of the Optical CMM dynamically track the precise location and orientation of the handheld 3D Nikon Metrology MMD laser scanner. “The absence of mechanical constraints creates a superior comfort level when scanning the surfaces of the body,” explains Eric Appelmans. “The scanner is equipped with a laser stripe of 100 mm, which enables us to acquire measurement points at a rate of tens of thousands per second. With Nikon Metrology K-Scan MMD, we easily and consistently reach the required measurement accuracy of 100 micron. But most important for us is the ergonomic handgrip of the scanner and the unmatched ease-of-use delivered by the system’s optical CMM technology.”

When scanning is ongoing, it is important for the user to see the point cloud develop on the computer screen in real-time. Nikon Metrology KUBE software manages the captured point cloud of the vehicle body, which typically consists of hundreds of thousands or even millions of accurate measurement points. To conveniently access all locations inside the car body, CARAT-Duchatelet engineers carefully select optical CMM positions that provide optimum coverage of the scan area. To compensate for any vehicle movement during measurement, the operator applies the Optical CMM’s unique dynamic reference feature. 3 to 6 small LEDs stuck to the car body and dynamically tracked by the Optical CMM ensure that all movement is compensated accurately. Using this information, the K-Scan MMD system is able to dynamically relocate the laser scanner position, avoiding leap-frogging or part realignment. K-Scan MMD also supports multiple standpoints for the Optical CMM. Data acquired from different Optical CMM locations refer to the same reference axes system and contribute to a single unified point cloud.

Point cloud data drives the CAD generation process

To reduce the amount of measurement data, CARAT-Duchatelet engineers apply curvature-based filtering algorithms to eliminate obsolete measurement data in flat plane surface areas. “After point filtering, we export the point cloud in IGES or ASCII format, and import the file in CATIA V5 software. On the basis of the point cloud data, we create a surface mesh and generate CAD surfaces. For us, the process of fitting freeform CAD surfaces through measurement points represents a mostly automatic procedure. For particular edges and roundings that are deemed critical, we manually fit surfaces and select the optimum level of smoothing. This flexibility enables us to take control of the CAD generation process and obtain high CAD definition quality.”

According to Eric Appelmans, scanning with K-Scan MMD provides better insight in a shorter time frame compared to taking manual touch probe measurements using an articulated measurement arm. “K-Scan MMD offers a comfort level and data acquisition rate that are simply beyond comparison. Our  approach of digitizing a complete car in one pass at the start of the project avoids many costly and time-consuming iterations later on the process. This enables us to design and develop all different vehicle modifications in the most effective way.” 

Reverse engineered steel armoring parts make up a bullet-tight cage around the interior of a vehicle body.

 Scanning streamlines all vehicle modification actions

Starting from the CAD data they generated, the R&D team of CARAT-Duchatelet specifies detailed requirements for steel and glass armoring and interior design. For radical vehicle modifications – such as vehicle extension and raised roof – a pre-scan may be executed to design adaptations to body, doors, hinges and windows, and driveline transmission. “The K-Scan MMD helps us a great deal in streamlining all our vehicle modification actions, providing top quality in the shortest time frame possible. With accurate and complete CAD data, we minimize the risk for development surprises that may introduce expensive rework and process delay.”

To read more on our website, click here.

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