2D Datamatrix Codes

Filed under: Laser Engraving, Parts Marking, Uncategorized, metal plate embossing, nd:YAG Lasers — Tags: , , , , , — admin @ 4:09 pm

2 D Datamatrix Codes, what’s so special about them, and how are they better than the “standard” ones?

We are all familiar with 1 Dimensional barcodes, more commonly known as linear barcodes. It is simply a machine readable form of data, and is commonly used on products to allow automated registry when scanned at checkout systems. Linear barcodes have a maximum capacity of about 20 to 25 numeric characters, and the information contained within them helps retailers keep tracks of the number of items in store. It also hinders shoplifting (since it is harder to switch the price tags of higher to lower priced items).

The Linear 1D Barcode

As the name suggests, 2D barcodes can encode information in 2 dimensions. These can be a series of linear barcodes stacked on top of each other (as shown in the image below).

The stacked linear barcodes


Or the more popular form, a 2D matrix, which holds dots in an array that is much more compact than the stacked 1D barcodes. This array consists of black and white “cells” or modules arranged in either a square or rectangular pattern. As the information is held in more than 1 dimension, a different reader would be required to decode the information. However, they can hold a lot more information when compared to the traditional linear barcodes, and even if the code is partially damaged, it can still be read (unlike the 1D, linear barcodes).

The MaxiCode Label

UPS make good use of its large storage capabilities in their sorting offices. The MaxiCode Label holds all of the relevant destination information ready to be scanned by the couriers.

The 2D Datamatrix code

The 2D datamatrix code is the most common type of 2D matrix code. Its small size makes it the preferred choice by most manufacturing industries. 50 character codes can fit within a 2 to 3 mm² area, and read with a contrast as low as 20%! (Some silicon electronics applications have laser etched codes as small as 300 micrometers!)

A four segment Datamatrix.

Data Matrix symbols are made up of modules arranged within a perimeter finder and timing pattern, which can encode up to 3,116 characters from the entire ASCII character set, with extensions (all of the numbers, letters (uppercase and lowercase) and symbols on your keyboard).

I thought barcodes and 2D codes could only be used in retail applications?

Quite the contrary, the applications can be as varied as the applications. For example, if you were to use the 2D codes on identification plates around a production plant. The code could simply contain all of the readable text and numbers on the plate. In this instance, the 2D code could be used for quick logging or updating records using a 2D scanner. Sometimes it is not possible to include all of the information onto the plate, so the further information can be encoded into the 2D code. However, in some instances the information needs to be secure, and not visible unless scanned. The 2D code can be encrypted with a PIN number, that must be entered before the information can be read.

Many industries are moving towards Datamatrix codes to improve traceability, the pharmaceutical and aeroscpace industries are the quickest adopters due to the high quality control standards and the emergence of black markets with counterfeit parts. Datamatrix codes can hold the components details, manufacturer ID, part number, and a unique serial number.

The applications for datamatrix codes do not end there. The ability to decode any alphanumeric information means that website addresses can be stored within the codes, linking the reader / decoder to specific website addresses or intranets with internal, classified information. Most of the latest mobile phones have cameras within them, which (with the use of a free downloaded application) can be used to decode 2D datamatrix codes. This allows the user to scan the code, and access the relevant website via their mobile. This opens up the possibilities for “further reading” of artifacts in museums, artist details in galleries, or the genealogy of plants in botanical gardens.

metal engraving

Filed under: Laser Engraving, Parts Marking, Uncategorized, metal plate embossing, nd:YAG Lasers — Tags: , , , , , , , , , , , , , , , — admin @ 1:52 pm

Metal engraving is a process in which a design is incised on a piece of metal using an engraving tool. This form of decorating metal has been around for five thousand years. The tools are pressed into the metal to cutting it and forming the desired design. The harder one pushes the engraving tool into the metal, the wider the mark. The correlation between dipping depth and engraving width is determined by the top angle of the tool.
Engraving tools are made out of hard steel that cuts the design onto metal surfaces such as steel plates or copper. Engraving tools are available in a variety of sizes and shapes for making different lines and marks. The three most commonly used tools are called the chisel, the graving tool (also called bulino), and the burin (also called ciapolla).
The chisel is not used for cutting, but is hammered. This does not remove any of the metal, but depresses it. A pliable support is placed underneath to prevent the metal from breaking or buckling.
Gravers are halved carbide round rods with a cutting edge. The graving tool has a wood handle making it easier to control the depth of the cut made with this sharp steel tool.
The burin is also a sharp steel tool, but comes in different shapes (lined, rounded and flat) to produce different effects.

The two most popular kinds of engraving decoration are damascening and niello.
Damascening is metal inlay in which a fine metal plate is inserted into a grove that has been made in a differently colored metal, and then is beaten in.
Niello is a mixture of silver, tin, lead, and copper that has been fused. This heated mixture is used to filled an engraving in a precious metal. After the mixture cools, the face plate is polished to bring out the semi-opaque design.
Engraving produces a unique quality of mark characterized by steady, clean edges. These lines and marks are produced by specific tools designed just for that purpose. This is a very specialized form of art with many types of materials and designs that takes years to master.

The Future of Laser Engraving

Filed under: Laser Engraving, Parts Marking, nd:YAG Lasers — Tags: , , , , , , , , , , — admin @ 10:37 am

The future of laser engraving is directly influenced by the variables of materials, the types of lasers and their capabilities.

What is Laser Engraving?

Laser engraving is a technique that uses a laser to etch/mark or to engrave the surface of other objects. These marks can vary in depth and can be used to create designs in or on objects or to imprint a message. The types of lasers used depend on the material being etched. The next generation and lasers of the future will advance three-dimensional techniques, integrate with existing design programs and see the development of better multi-engraving etchers and micro-machines. In addition, laser engraving techniques of the future will begin to develop and implement green methods and practices.

How Does a Laser Engrave or Etch a Material?

Basically, a laser beam (Light amplification by stimulated emission of radiation) is focused on a material which results in a modification of the surface and in the optical appearance of the material. The material being engraved determines the type of modification that will occur. For example, on paper, wood or cardboard the etching would occur as carbonization (burning) while the surface of a metal might be melted.

Different Types of Lasers, Their Uses and Future Applications

A few examples of how engraving lasers are currently being used include engraving/etching bar codes, 2D codes, photographs, identification tags, logos, glass doors, mirrors and to mark circuit boards and electronic equipment. Advancements in laser engraving technology to reduce material stress and vibrations are helping to expand and increase the potential for future marketable applications.

CO2 Lasers typically use low power sources to engrave plastics, paper, acrylic materials, wood, transparent objects and leather (Long wavelength applications) and use a Carbon Dioxide gas sealed chamber inside of the laser to create the laser photon stream. Generally, a CO2 laser is used for organic materials.

ND: YAG Lasers are small, affordable air cooled systems which are designed to engrave metallic materials and non organic materials. ND:YAG refers to the neodymium-doped yttrium aluminum garnet that is pumped with the use of a lamp or a diode to emit the photon stream.

Fibre Lasers, a derivative of the ND:YAG Laser (Pulse repetition rates-can emit longer pulses with lower pulse energy) commonly uses a ytterbium doped glass fiber to reflect the photons and can be used for ceramics, metals and non organic materials.

Green Practices and the Economy: Future Considerations for Laser Engraving Technology

Engraving lasers do not use ink, leave a permanent mark and are generally good for the environment.

The American Recovery and Reinvestment Act designed to jump start the economy with a focus on restoring and building American-made innovative science technologies may benefit and encourage laser engraving technological advancements. As a result, future laser engraving technologies that focus on energy conservation, utilization of green technologies and renewable resources may be eligible for tax incentives. Also, under this act, qualifying equipment purchases may be deducted during this tax year enabling businesses to purchase or lease qualifying laser etchers.

Considerations for the development of future engraving lasers might also focus on ease of use issues and on how to minimize vibrations and material stress along with processing speed, pulse repetition rates and the quality of results.

Future laser engravers will become more compact and portable, have multiple material engraving capabilities, use minimal resources and energy and have three dimensional engraving capabilities. In order to advance, the engraving lasers of the future will also need to be capable of engraving textured surfaces, irregular shapes and be able to do multiple stages of etching, engraving and carving.

Laser technology offers state-of-the-art solutions for direct parts marking

Filed under: Laser Engraving, Parts Marking — Tags: , , , , , , , , , — admin @ 12:26 pm

Direct parts marking is an essential part of virtually any manufacturing process today, allowing both manufacturers and end users to readily and accurately identify specific components to aid in repair and diagnostics, as well as in theft recovery and counterfeit prevention.

There are many options for direct parts marking, and lasers are one of the newest and most accurate methods on today’s market.  In the last decade, industries worldwide have embraced the convenience and security advantages of direct parts marking. The list of businesses and facilities using direct parts marking today includes government departments, military parts manufacturers, automotive and aeronautics manufacturers, pharmaceutical concerns, and a wide range of consumer goods manufacturers, and the number and variety of end products using these parts is staggering.

Laser marking allows products to be marked with clearly identifiable, highly precise tags or codes which are indelible, and also have the advantage of being engraved deep into the components’ surfaces if needed, affording another dimension of protection from theft or counterfeit. Both CO2 and nd:YAG lasers may be used in direct parts marking, based on the application process.

Employing highly focused, direct beams of energy, lasers can achieve levels of precision and accuracy unattainable with other methods of marking. Even the most highly detailed and intricate logos and corporate symbols can be replicated accurately using a laser marking system. Leading the way in industry standards, the nd:YAG and the CO2 laser systems use different wavelengths to ensure a wide range of applications suitable for your business’ needs.