696

Material:  Carbon Pieces – 2nd Trial Method Used:  Etch Depth:  <.002 Laser Type:  20 watt Q-Switch Fiber Laser Focal Length Lens:  160mm Power: 100% Frequency: 20kHz Speed: 10 inches per second Passes: 9 Cycle Time: 57Read More…

697

Material:  aluminum Method Used:  etch Depth:  < 3mm Laser Type:  20 Watt Q-Switch Fiber Laser Focal Length Lens:  160mm Power: 100% Frequency: 20 kHz Speed: 10 inches per second Passes: 600 Cycle Time: 10 mins SamplesRead More…

698

Material:  Black Polypropylene Method Used:  Etch Depth:  <.001 Laser Type:  20 watt Q-Switch Fiber Laser Focal Length Lens:  160mm Power: 30 – 100% Frequency: 20kHz Speed: 26 – 60 inches per second Passes: 1 Cycle Time:Read More…

700

Material:  Steel Method Used:  etch Depth:  >.003 Laser Type:  20 Watt Q-Switch Fiber Laser Focal Length Lens:  160mm Power: 98% Frequency: 20 kHz Speed: 15 inches per second Passes: 20 Cycle Time: 1176 seconds Samples wereRead More…

701

Material:  Plastic Method Used:  etch Depth:  <.001 Laser Type:  20 Watt Q-Switch Fiber Laser Focal Length Lens:  160mm Power: 57% Frequency: 20 kHz Speed: 20 inches per second Passes: 1 Cycle Time: 9.98 seconds Samples wereRead More…

702

Material:  Copper Method Used:  etch Depth:  <.002 Laser Type:  20 Watt Q-Switch Fiber Laser Focal Length Lens:  160mm Power: 50%-98% Frequency: 20 kHz- 50 kHz Speed: 10 – 25 inches per second Passes: 2 Cycle Time:Read More…

705

Material:  Acrylic Method Used:  etch Depth:  <.002 Laser Type:  20 Watt CW Fiber Laser Focal Length Lens:  254mm Power: 40% Speed: 10 inches per second Passes: 2 Cycle Time: 50.5 seconds Samples were processed using aRead More…

683

Material:  aluminum Power:  50% Method Used:  etch Frequency:  35kHz Depth:  <.002 Speed:  25 inches per second Laser Type:  20 Watt Q-Switch Fiber Laser Passes: 1 Focal Length Lens:  160mm Cycle Time:  15.6 seconds Sample was processedRead More…

684

Sample was processed using a 20 watt Q-switched fiber laser through a 160mm F-theta lens.

685

Sample was processed using a 20 watt Q-switched fiber laser through a 160mm F-theta lens.

686

Material: Stainless steel and gold   Power: 95%   Method Used: etch   Frequency: 20 kHz   Depth: <.001   Speed: 10 inches per second   Laser Type: 20 Watt Q-Switch FiberRead More…

619

This part was marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The part was surface etched, to create contrasting marks. Material: Carbide Steel Method used: SurfaceRead More…

620

The part was marked using a 20 watt q-switched ytterbium fiber laser with 160mm focal length lens. The small and medium drill bits were surface annealed at approximately 17 watts of power,Read More…

625

This anodized aluminum tube was marked with a 20 watt q-switched ytterbium fiber laser at 9 watts with a frequency of 25kHz and 160mm focal length lens. The part was surfaced etchedRead More…

630

A laser etched aluminum tool Process Parameters: Material: Aluminum Power: 12 Watts Method used: Surface Etch Frequency: 25 kHz Depth: Surface Speed: 10 inch/sec Laser Type: Q-Switched Fiber Laser Focal Length Lens:Read More…

632

The part was laser marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. Process Parameters: Material: Aluminum Power: 12 Watts Method used: Surface Etch Frequency: 25 kHz Depth:Read More…

635

Process Parameters: Large Parts – Dark Coating, Light Etch Material: Steel Power: 17 Watt Method used: Etching Frequency: 80 kHz Depth: Surface Speed: 3 inchsec Laser Type: Q-Switched Fiber Laser Focal Length Lens:Read More…

636

Process Parameters: Small Parts – Dark Coating, Light Etch Material: Steel Power: 17 Watt Method used: Etching Frequency: 80 kHz Depth: Surface Speed: 3 inchsec Laser Type: Q-Switched Fiber Laser Focal LengthRead More…

639

This abrasive core material was laser etched. Process Parameters: Abrasive Core Material: Abrasive Core Power: 7 Watts Method used: Etching Frequency: 20 kHz Depth: Surface Speed: 10 inch/sec. Laser Type: Q-Switched FiberRead More…

640

Laser etching on carbide Process Parameters: Blacklite Wheel Material: Carbide Power: Etch: 9 Watts Engrave: 10 Watts Method used: Etching and Engraving Frequency: Etch: 30kHz Engrave: 35 kHz Depth: Surface Speed: Etch: 10Read More…

665

Laser engraving / burning wood model and or seriel numbers on Cabinet doors and drawer faces. 30 W @ 100% and 100-150 mm/sec. Various size cabinet doors were laser marked using the Fantom 30Read More…

673

A UID data matrix with 3mil data cell size was laser marked on polished stainless steel stock. The mark produced had excellent contrast. Total mark time was 0.5 seconds. A 20 Watt CW Fiber laser was used toRead More…

674

UID marking a two-dimensional data matrix with 3mil data cell size was marked on polished plate stainless steel stock. The mark produced had excellent contrast. Total marking time was 0.6 seconds. A 20 Watt CWRead More…

678

Material:  rubber Power:  50% Method Used:  Laser etching Frequency:  20khz Depth:  <.002 Speed:  20 inches per second Laser Type:  20 Watt Q-Switch Fiber Laser Passes: 1 Focal Length Lens:  160mm Cycle Time:  7.4 seconds Rubber sealRead More…

679

Material:  plastic Power:  40% Method Used:  etch Frequency:    Depth:  <.001 Speed:  20 inches per second Laser Type:  20 CW Fiber Laser Passes: 2 Focal Length Lens:  254mm Cycle Time:  3.5 seconds The plastic device seenRead More…

506

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The samples were etched to create brightly contrasting marks. Material: Brass Power: 18 wattsRead More…

507

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The samples were etched to create brightly contrasting marks. Material: Painted & Anodized AluminumRead More…

508

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The samples were etched to create brightly contrasting marks. Material: Painted & Anodized Aluminum Power:Read More…

509

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The samples were etched to create brightly contrasting marks. Material: Anodized Aluminum Power: 10Read More…

510

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The samples were etched to create brightly contrasting marks. Material: Aluminum Power: 20 wattsRead More…

511

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The samples were etched to create brightly contrasting marks. Material: Aluminum Power: 20 watts MethodRead More…

512

Laser marking of aluminum was accomplished using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The large and small tags were both surface etched to create aRead More…

515

Laser etched aluminum steel Material: Steel Power: 17 watts Method used: Etching Frequency: 25 kHz Depth: Surface Speed: 10 inch/sec. Laser Type: Q-Switched Fiber Laser Focal Length Lens: 160mm Cycle Time: 5.77Read More…

526

The parts were marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The parts were surface etched, to create contrasting marks. Various speeds and frequencies wereRead More…

527

The parts were marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The parts were surface etched, to create contrasting marks. Various speeds and frequencies wereRead More…

528

The parts were marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The parts were surface etched, to create contrasting marks. Various speeds and frequencies wereRead More…

535

The parts were marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface marked, to create bright contrast similar the sample part sentRead More…

536

The parts were marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface marked, to create bright contrast similar to the sample previouslyRead More…

540

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to create brightly contrasting marks.  

541

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to create brightly contrasting marks.  

542

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to create brightly contrasting marks.  

554

The parts were marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The carbide parts were surface etched, to create brightly contrasting white marks on theRead More…

558

The parts were marked using a 20 Watt Pulsed Fiber Laser using a 160 mm lens. The carbide mills were etched using 7 watts of power in 2.31 seconds in the largerRead More…

584

The carbide, oxide coated and stainless steel were marked with a surface etch, the stainless steel was marked with a dark mark as well. A light etch is produces the most contrastRead More…

603

The part was marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lens toRead More…

606

The part was marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lens toRead More…

612

This part was laser marked with a 20 watt q-switched ytterbium fiber laser with a 160 mm focal length lens. This sample was surface etched, creating a light mark on the surface of theRead More…

615

This part was marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The part was surface etched, to create contrasting marks. Material: Carbide Steel Method used: SurfaceRead More…

617

This part was marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The part was surface etched, to create contrasting marks. Material: Carbide Steel Method used: SurfaceRead More…

618

This part was marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The part was surface etched, to create contrasting marks. Material: Carbide Steel Method used: SurfaceRead More…

382

The gun parts were marked using a 20-Watt Q-Switched Fiber Laser with a 160-mm lens. The parts were marked with 3 different types of Bushmaster logos.  Two anodized aluminum magazine inserts wereRead More…

383

The gun parts were marked using a 20-Watt Q-Switched Fiber Laser with a 160-mm lens. The parts were marked with 3 different types of Bushmaster logos.  Two anodized aluminum magazine inserts wereRead More…

384

The gun parts were marked using a 20-Watt Q-Switched Fiber Laser with a 160-mm lens. The parts were marked with 3 different types of Bushmaster logos.  Two anodized aluminum magazine inserts wereRead More…

385

The gun parts were marked using a 20-Watt Q-Switched Fiber Laser with a 160-mm lens. The parts were marked with 3 different types of Bushmaster logos.  Two anodized aluminum magazine inserts wereRead More…

386

The gun parts were marked using a 20-Watt Q-Switched Fiber Laser with a 160-mm lens. The parts were marked with 3 different types of Bushmaster logos. The parts were marked for contrast usingRead More…

387

The gun parts were marked using a 20-Watt Q-Switched Fiber Laser with a 160-mm lens. The parts were marked with 3 different types of Bushmaster logos.  The parts were marked for contrast usingRead More…

404

The samples were marked with a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. They were surface etched, to create brightly contrasting marks. The parts were marked atRead More…

405

The samples were marked with a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. They were surface etched, to create brightly contrasting marks. The parts were marked atRead More…

406

The samples were marked with a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. They were surface etched, to create brightly contrasting marks. The parts were marked atRead More…

419

The sample was marked with a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lens to part.Read More…

424

The part was marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The aluminum was surface etched to produce a nice contrast just like the sampleRead More…

432

This part was marked using a 20 watt q-switched ytterbium fiber laser with a 160 mm focal length lense. The sample was surface etched, to create the light marks on the part. Samples were markedRead More…

434

Both samples were marked using a Fiber Laser Marking system with laser at 9 Watts and frequency of 25kHz. Sample 1 – Aluminum was marked at a rate of 50 inches perRead More…

437

This part was marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lens toRead More…

438

This part was marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lens to part.Read More…

441

The samples were marked with two different fonts to provide a “contrast” versus “cycle time” comparison. In addition, per the customer’s request, the two samples were marked on the contoured surfaces withoutRead More…

453

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched and anneal to create a contrasting mark. Material: SteelRead More…

458

The carbide was marked with a surface etch. A light etch is produces the most contrast when marking on carbide. The cycle time for marking on the part was only 0.83 seconds.Read More…

491

The part was marked with a cycle time of 6.6 seconds, using a 10 watt Fiber Laser Marking System.  

492

The part was marked with a cycle time of 6.6 seconds, using a 10 watt Fiber Laser Marking System.

196

The part was marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lens toRead More…

197

This part was marked with a 20 watt q-switched ytterbium fiber laser with a 160 mm focal length lens. This sample surface etched, creating marks of substantial depth on the surface of theRead More…

199

This part was marked with a 20 watt q-switched ytterbium fiber laser with a 160 mm focal length lens. This sample surface etched, creating marks of substantial depth on the surface of theRead More…

202

Material: Stainless Steel Power: 8 Watt Method used: Etching Frequency: 35 kHz Depth: Surface Speed: 20 inchsec Laser Type: Q-Switched Fiber Laser Focal Length Lens: 160mm (170mm WD) Cycle Time: 4.45 SecondsRead More…

203

Material: Anodized Aluminum Power: 9 Watt Method used: Etching Frequency: 30 kHz Depth: Surface Speed: 20 inchsec Laser Type: Q-Switched Fiber Laser Focal Length Lens: 160mm (170mm WD) Cycle Time: 2.47 Seconds SampleRead More…

229

The steel gear was marked using a 20 Watt Q-Switched Fiber Laser with a 160 mm lens. Logo, human readable characters and their barcode, 2D matrix code were etched on the partRead More…

238

The ferotek parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to remove a layer of material and createRead More…

239

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to remove a layer of material and create aRead More…

240

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to remove a layer of material and create aRead More…

242

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to remove a layer of material and create aRead More…

245

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched to remove a layer of material and create aRead More…

246

Laser Marked Harley Davidson Motor Cycles Logo Laser etching was done on the chrome piece (gas tank cap) without going through the chrome. The Harley Davidson logo was marked on the top of theRead More…

253

The part was marked using a 20 watt q-switched ytterbium fiber laser with 160mm focal length lens. The parts were mark according to customer request. The serial number S1811Y-RP was etched ontoRead More…

254

The part was marked using a 20 watt q-switched ytterbium fiber laser with 160mm focal length lens. The parts were mark according to customer request. The alphanumeric mark IRGCO, was etched ontoRead More…

257

The parts were marked using a 10 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The parts were surface etched, to create brightly contrasting marks. The codes read wellRead More…

259

Laser marking of the aluminum casting was done using a 10Watt Fiber Laser Marking System. The two straight lines of text marked had a cycle time of 6.6 seconds. The part was marked using aRead More…

260

Laser marking of the machined rubber/aluminum tube was accompished using a 10 Watt Fiber Laser Marking System. The marking on the tube had a long cycle time of 8.91 seconds. The rubber was marked slower toRead More…

263

The part marked had a cycle time of 6.6 seconds. The part was marked using a 10 watt Fiber Laser Marking System.  

264

The part marked had a cycle time of 6.6 seconds. This part was marked with a 10 watt Fiber Laser Marking System.  

266

The brass gear marking had a cycle time 3.75 seconds. The part was marked using a 10 watt Fiber Laser Marking System.    

278

This part was laser marked with a 20 watt q-switched ytterbium fiber laser with a 160 mm focal length lens. This sample was surface etched, creating a light mark on the surface of theRead More…

288

The parts were marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etch, to create bright contrast. Process Parameters: Light Etch MarkRead More…

322

Process Parameters: Black Anodize Material: Black Anodize Power: 12 Watt Method used: Etch Frequency: 30 kHz Depth: Surface Speed: 15 inchsec Laser Type: Q-Switched Fiber Laser Focal Length Lens: 160mm Cycle Time:Read More…

323

Process Parameters: Black Anodize Material: Chrome Power: 10 Watt Method used: Etch Frequency: 35 kHz Depth: Surface Speed: 15 inchsec Laser Type: Q-Switched Fiber Laser Focal Length Lens: 160mm Cycle Time: 4.62 secondsRead More…

354

The paint was removed from the plastic parts using a 20 watt Fiber Laser Marking System. The text on the previously marked samples were duplicated as close a possible. The parts wereRead More…

362

All samples were marked with the 20 Watt Fiber Laser Marking system using a 160 mm lens. Characters 0.070” tall were marked on all samples. Annealing was used to create the marksRead More…

122

This bone screw sample was marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The 160mm focal length lens has a working distance of 176mm from lensRead More…

126

The part was laser marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The sample was etched with the information provided by customer. Medical Device Marking: Material: AluminumRead More…

128

This medical device was marked using a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The sample was etched with the information provided by customer. Medical Device Marking: Material: SteelRead More…

158

The parts were marked with a 20 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched and annealed to create a contrasting mark. Material: SteelRead More…

162

The aluminum was marked with a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The part was surface etched, to create a highly contrasting mark. The part wasRead More…

163

The aluminum was marked with a 20 watt q-switched ytterbium fiber laser with 160 mm focal length lens. The part was surface etched, to create a highly contrasting mark. The part wasRead More…

188

Stainless steel parts were marked with a 20-watt q-switched fiber laser with 160 mm focal length lens. The parts were deep engraved using 18 watts of power, a frequency of 20 kHzRead More…

189

The parts were marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched, to create a contrasting mark. The sample parts withRead More…

190

The parts were marked with a 10 watt q-switched ytterbium fiber laser and 160 mm focal length lens. The parts were surface etched, to create a contrasting mark. The parts were markedRead More…