Improve LSR injection molding mold temperature and warpage with special-shaped oil circuit and mold

Due to rapid development of 3D printing technology, designers can use 3D metal printing to design more in line with requirements of oil circuit, which can be close to contour of product when designing, so as to solve dead angle and heat accumulation of product. The more complex geometric shape of product will be more obvious, and this type of waterway design is usually called Conformal…

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The Advantages of Conformal Cooling in Reducing Cycle Time

Evaluating the efficiency of injection moulding is dependent on its productivity and quality of component. The proximity of cooling channels decides the cooling efficiency. Even a slight variation in the distance between two cooling channels can cause uneven heat dissipation. This result in increased cycle time, sink marks, part warping, reduced tool life due to heat stress and internal part stresses.

Importance of Reduced Cycle Time

The pace of the injection moulding machine in your factory will decide how much profit your company will make. Cooling takes a significant portion of cycle time, which is why it also has major focus when trying to improve business operations.

Conformal cooling tooling has proven effective in reducing cycle time, by as much as 70% in some cases. Till a few years ago, conventional manufacturing techniques could create cooling channels but this usually limited freedom of design and upped the cost of manufacturing in many applications. However, using additive manufacturing (AM), or 3D printing, as it is popularly known, helps you to experiment with fewer limitations, and reduces cycle time effectively.

Using DMLS, it is possible to design and develop extremely complicated geometric shapes and complex functional components in the most cost-effective manner. In essence, direct metal laser sintering lets you insert cooling channels without drilling, thus making the design more feasible and functional.

Points to Consider when using Conformal Cooling Technique

There are four main principles that guide the functioning of conformal cooling method.

1. Wall Thickness

Cooling time exponentially increases with increase in thickness of walls of the component being manufactured using DMLS conformal cooling method. For instance, a component with a 1-mm thick wall takes around 5 seconds to cool down while a component with walls 5-mm thick may take as much as 40 to 75 seconds.

2. Thermal diffusion

Thermal diffusion is the ratio of thermal conductivity to heat capacity. This factor is vital because when thermal diffusion of a material is low, the longer it takes to dissipate heat.

3. Mould temperature

High mould temperatures allow lowering of pressure during the filling phase. This helps to get a better surface finish on components and can also increase cooling time multi-fold.

4. Pitch and Depth

The depth, size and spacing of cooling channels should cause the temperature to change across the mould surface by 5 to 10 degree Celsius. Increasing the number of cooling channels placed close together near the surface accelerates cooling and also maintains temperature uniformity.

Benefits of Conformal Cooling in Reducing Cycle Time

Conventional cooling methods often cause shrinkage on core side, creates gaps in the part with limited space and the channels in the core are likely to experience higher temperature exchange.

To remedy this, the best way is to use two thermal controllers, choosing a lower-conducting material for cavity and changing the distances between channels and cavity. This method works incredible well for numerous applications.

Here are the distinct benefits of using conformal cooling tooling for prototyping and manufacturing:

1. Less cycle time

Various studies have shown that conformal cooling can cut cycle time by as much as 70% as compared to traditional cooling channels.

2. Freedom of design

This technique helps designers to create smooth transitions and smaller diameter channels with elliptical or circular cross-sections. Conformal cooling helps to reach spaces not allowed with conventional cooling channels.

3. Better quality

With uniform temperature distribution through conformal cooling, it is possible to reduce risk of stress that can cause visual defects and deformation of design. This helps improve product quality noticeably.

Conclusion

Using conformal cooling technique, it is possible to not only reduce cycle time, but also improve product quality, create incredibly complex designs and control the functionality of components more effectively. Last, but not the least, conformal cooling eventually helps to improve your company’s profits.

October 5, 2024

Juuuust wanted to document that I felt really pretty today lol. I mean part of it is that I received three (3!!!) compliments from strangers over the course of the afternoon, but also like,,, I was wearing an outfit that felt like it was exactly what I want to look like. The image I was presenting to the world was aligned with how I see myself in my head (a little edgy, a little dainty, with a lightly vintage flair... like an old-timey naturalist!), and it feels really cool that my closet is moving towards that image, albeit slowly.

3D printing class went well! Should be able to get the mask done in one sitting. Also some of the makerspace staff know my name :')

Today I'm thankful that I felt really good in my outfit today. It makes me think that I'm not forcing myself to just conform to a pinterest board (even if it was curated by me), but that I'm actually discovering style elements that speak to who I am. And I think that has an effect on my overall ambience, too.

Need some pleated work trousers so bad oh my god.

Thrifted some yarn to crochet Katara's bracers but only had enough for one side :/ Frogged. Redesign soon (slip stitches are not a particularly economical use of yarn tbf).

Metal Additive Manufacturing: The Rise of Additive Manufacturing in the Metal Industry

Emerging Technology with Metal Additive Manufacturing Additive manufacturing (AM), commonly known as 3D printing, has experienced explosive growth in recent years. While initially used primarily for rapid prototyping of plastic parts, AM is now being widely adopted for production of functional metal components. Metals that can be 3D printed include stainless steel, titanium, nickel alloys, aluminum and copper alloys. Compared to traditional subtractive manufacturing methods, AM offers new design possibilities and advantages for the production of complex metal parts. Metal Additive Manufacturing Processes There are three main Metal Additive Manufacturing processes in use today: powder bed fusion, directed energy deposition, and binder jetting. Powder bed fusion systems mimic traditional 'layered manufacturing' by selectively fusing metal powder particles using a laser or electron beam. The most common systems are selective laser melting (SLM) and electron beam melting (EBM). In directed energy deposition, a laser or electron beam directs energy to fuse powder materials as they are deposited, allowing parts to be built outside of an enclosure. Binder jetting uses inkjet print head technology to deposit a liquid binding agent onto layers of powder, solidifying the final part through post-processing. Benefits for Complex Parts production Benefits of Metal Additive Manufacturing enables the economic production of complex parts that would be difficult or impossible to manufacture using conventional methods. Complex internal channels, optimized lattice structures and integrated features can all be built within a single part. This has significant benefits across various industries: - Aerospace: Weight reduction through topology optimization helps lower fuel costs. AM allows embedded features like cooling channels in jet engine components. - Medical: Implants can be better customized for individual patient anatomy. 3D printed orthopedic implants have complex porous structures that promote bone in-growth. - Automotive: Conformal cooling channels improve mold performance. AM enables net-shape production of parts with less assembly. - Energy: Turbine blades with lattice structures can withstand higher temperatures and pressures. AM facilitates single-piece constructions. New Design Opportunities Metal AM opens up entirely new possibilities for part and system design. Engineers can leverage topology optimization to remove non-critical material from designs without compromising strength or function. Internal structures like microlattices create tunable stiffness or customize heat/fluid transfer characteristics. Consolidation of multiple components into one 3D printed part reduces assembly time and costs. Designs can now take full advantage of digital blueprints without the limitations of traditional manufacturing constraints. Production Scaling and Quality While metal AM has made significant advances, further improvements are still needed for many production applications. Build speeds, part sizes and material options are increasing regularly as technology progresses. However, scaling AM from prototypes to mass production remains challenging due to long processing times and high equipment/material costs compared to conventional manufacturing. Quality assurance, consistency and repeatability are other ongoing focus areas. Establishing robust process control, standardization and certification will be important for qualifying AM parts in safety-critical applications.

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Priya Pandey is a dynamic and passionate editor with over three years of expertise in content editing and proofreading. Holding a bachelor's degree in biotechnology, Priya has a knack for making the content engaging. Her diverse portfolio includes editing documents across different industries, including food and beverages, information and technology, healthcare, chemical and materials, etc. Priya's meticulous attention to detail and commitment to excellence make her an invaluable asset in the world of content creation and refinement.

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Ceramic Mug 11oz - Field Spaniel, spaniels, Watercolor, realistic, art, Field Spaniel gifts Your favourite breed art print - head or body conformation - groomer gift - Other Breeds Available - dog breeder gift - regional specialty or national specialty prize gift idea Artwork by Ivy Fox Illustration Follow Ivy Fox Illustration on social media https://m.facebook.com/IvyFox.illustration/ https://www.instagram.com/ivyfox.illustration/ Find your dog breed: Personalized Pet Portraits: https://ivyfoxillustrates.etsy.com/ My website: https://ivyfoxillustration.com/ Art Prints Merch Original PaintingsWarm-up with a nice cuppa out of this customized ceramic coffee mug. Personalize it with cool designs, photos or logos to make that "aaahhh!" moment even better. It’s BPA and Lead-free, microwave & dishwasher-safe, and made of white, durable ceramic in an 11-ounce size. Thanks to the advanced printing tech, your designs come to life with incredibly vivid colors – the perfect gift for coffee, tea, and chocolate lovers. .: White ceramic .: 11 oz (0.33 l) .: Rounded corners .: C-handle .: Lead and BPA-freeContact Email: IvyFoxIllustration@ gmail(dot)com ———— Tags and other miscellaneous info: ———— Ivy Fox Illustration Ivy Fox dog art Museum of the Dog American Kennel Club Showsight - Where Champions Are Celebrated American Dog Fancier InfoDog Best In Show The Canine Chronicle AKC Gazette best pet portrait artist watercolor fine art unique art Akc meet the breeds Westminster kennel club dog show national dog show crufts grooming intergroom superzoo petquest groom expo dog sports well bred dogs purebred preservation breeders ethical breeders breeder of merit akc grand champion Ch – Champion of Record – earned by gaining 15 points in conformation wins. Points awarded is determined by the number of other entries the winning dog defeats. A dog must win at least two majors (by winning at two different shows under two different judges where there are enough entries defeated to equal 3-5 points by the AKC point system. OTCh – Obedience Trial Champion To earn an obedience title, the dog must have a passing score of 50% of possible points or better, and an overall passing score at three different competitions under three different judges. CD – Companion Dog (First Level Obedience Competition, basic obedience exercises) CDX – Companion Dog Excellent (Intermediate Level Obedience Competition, more advanced obedience work) UD – Utility Dog (Advanced Level Obedience Competition, difficult obedience work, including hand signals) UDX – The highest obedience degree AKC presently awards TRACKING TD – Tracking Dog TDX – Tracking Dog Excellent VST – Variable Surface Tracking HERDING HIC – Herding Instinct Certificate HT – Herding Tested PT – PreTrial Tested HS – Herding Started HI – Herding Intermediate HX – Herding Excellent HCh – Herding Champion AGILITY NA – Novice Agility OA – Open Agility AX – Agility Excellent MX – Master Agility Excellent NAJ – Novice Agility Jumper OAJ – Open Agility Jumper EAJ – Excellent Agility Jumper AKC Unofficial Titles CGC – Canine Good Citizen ROM – Register of Merit – A dog or bitch must earn a number of points specified by the DPCA rules, and also meet the numbers of champion and major pointed progeny required by DPCA. The requirements for bitches are less than the requirements for the dogs because males have the opportunity to produce a far larger number of offspring. ROMC – Canadian ROM ROM/C – designates that the dog has earned an American and a Canadian ROM. TT – Temperament Tested TC – Temperament Certified AOE – Award of Excellence-A dog must meet qualifications in conformation, obedience, and also be OFA´d to earn this award. New competitions are being added and rules for competitions change, for the most up to date rules and regulations, check with the AKC and the DPCA. Miscellaneous American titles often seen on pedigrees and in advertising. BIS – Best in Show at an All-Breed Show in conformation. BISS – Best in Show Specialty (where only dogs of the same breed are competing in conformation) BOB – Best of Breed BOS – Best Opposite Sex BOW – Best of Winners (best between Winners Dog and Winners Bitch in breed conformation class competition) WD – Winners Dog – the winning dog overall of the regular classes of his sex. WB – Winners Bitch – the winning bitch overall of the regular classes of her sex. RWD/RWB – Runner up to the winners dog and bitch, if the winner becomes ineligible for the award then the runner up will receive the points awarded from that show. Special – A dog that is already a Champion that is competing for Best of Breed only. A Champion cannot compete in the classes where points are earned (because a Champion has already earned them!) RTD – Registered Therapy Dog TD I- Dog has passed Therapy Dog International´s testing HEALTH CERTIFICATIONS OVC – Ontario Veterinary College OVC Hip Certification – A dog may be preliminary screened at a younger age, but will not receive a certification unless the dog is at least 18 months old. It was told to me by a tech in the radiology department of OVC that they consider hips to either be bad, in which case they are rated on a scale from 0 – 4, with 4 being the worse, or they are “good” in which case the animal will receive a certification number (if 18 months or older. Therefore they do not follow the U.S. rating system which includes “FAIR”, Good, Excellent”. Their exact words were “the hips are either GOOD or they are NOT. OFA – Orthopedic Foundation for Animals OFA Hip Certifications – dogs within a specified range of normal hip x-rays are certified OFA-Excellent, Good, or Fair OFA – Elbow Certification – Certified by OFA for normal elbows on x-ray, only one grade recognized as normal. Check with OFA for proper procedures and positioning for hip and elbow x-rays. A dog may be preliminary screened at a younger age, but will not receive a certification unless the dog is at least 24 months old. OFA is also now doing certifications for other canine health concerns such as normal thyroid levels, check with OFA for accurate data and rules concerning these. CERF – Canine Eye Registry Foundation-dog is certified to have normal eyes. Re-certification must be done annually. vWD – Von Willebrands Disease free-meaning the dog has been tested and found free of vWD, a bleeding disorder, vWD free ratings also are often given with a percentage listed. For the best information on Von Willebrand´s Disease, contact Dr Jean Dodds, who is the leading research specialist in blood disorders. Dog show prize idea

Metal Additive Manufacturing Market is Estimated to Witness High Growth Owing to Reduced Production Costs

Metal additive manufacturing, also known as 3D metal printing, enables the fabrication of complex metal components using a digital file and successive layering of material under computer control. Manufacturers can produce intricate components with conformal cooling passages, lattice structures, and optimized designs that provide weight savings. As additive manufacturing reduces waste by building only the desired part geometry, it helps lower production costs compared to traditional subtractive methods such as milling and machining. The metal additive manufacturing market encompasses technologies such as direct metal laser sintering, electron beam melting, and binder jetting, among others. Manufacturers across industries adopt these technologies to produce prototypes and end-use products. Due to the potential for mass individualization and supply chain resilience, metal 3D printing demand is growing across automotive, aerospace, healthcare, and industrial equipment verticals.

Global metal additive manufacturing market is estimated to be valued at USD 5.85 Bn in 2024 and is expected to reach USD 14.37 Bn by 2031, exhibiting a compound annual growth rate (CAGR) of 13.7% from 2024 to 2031.

Key Takeaways Key players operating in the metal additive manufacturing market are GE Additive, 3D Systems, Desktop Metal, EOS GmbH, Renishaw, SLM Solutions, Stratasys, Markforged, Velo3D, DMG Mori, HP Inc., TRUMPF, ExOne (a Desktop Metal company), Materialise, Formlabs, Norsk Titanium, Optomec, Prima Additive, XJet, and VulcanForms. These players focus on expanding their production capacities and service offerings to tap growing metal 3D printing demand. Key opportunities in the Metal Additive Manufacturing Market Trends  include leveraging additive manufacturing to produce jigs, fixtures, and tooling for customized production. The technology enables on-demand manufacturing, reducing inventory costs. Further, 3D metal printing facilitates the direct production of end-use implants, prosthetics, and medical devices to improve patient outcomes. Geographically, the metal additive manufacturing market witnesses high growth in North America and Europe due to early technology adoption. However, Asia Pacific is emerging as an attractive market with huge potential, led by government initiatives driving advanced manufacturing. As the technology matures, global metal 3D printing adoption will continue increasing across industries. Market Drivers Reduced production costs with additive manufacturing compared to traditional methods is a key market driver. 3D printing eliminates the need for expensive tooling and reduces waste. It facilitates mass customization by producing different parts using the same production method. Furthermore, additive manufacturing enables the production of complex parts with optimised lightweight designs that provide performance and efficiency benefits. Metal Additive Manufacturing Market Size and Trends technology helps improve design flexibility, reduce lead times, and support supply chain resilience. All these advantages are fueling increased investment in metal 3D printing globally.

PEST Analysis Political: Metal additive manufacturing faces regulations regarding product quality and safety. Regulators aim to establish standards without stifling innovation. Economic: Metal 3D printing reduces waste and improves design flexibility compared to traditional manufacturing. It allows on-demand production and reduces lengthy supply chains. Social: Additive manufacturing increases access to custom-tailored solutions in industries like healthcare, consumer products, and education. It facilitates distributed manufacturing closer to end users. Technological: Advancements in metal powder composition, laser melting techniques, and printer capabilities continue increasing build size and throughput. Computer-aided design tools are optimizing machine parameters for new material formulations. Europe Europe is a major regional market, where aerospace and automotive sectors in Germany, Italy, and UK drive significant adoption of metal 3D printing technology, particularly for prototyping and low-volume production applications. Government support for advanced manufacturing research further boosts the regional market. Asia Pacific The Asia Pacific region is anticipated to witness the fastest growth over the forecast period due to rising focus on industrial modernization across industries in countries such as China, Japan, and South Korea. Establishment of local manufacturing facilities by global players also expands the regional market.

Get more insights on Metal Additive Manufacturing Market

Priya Pandey is a dynamic and passionate editor with over three years of expertise in content editing and proofreading. Holding a bachelor's degree in biotechnology, Priya has a knack for making the content engaging. Her diverse portfolio includes editing documents across different industries, including food and beverages, information and technology, healthcare, chemical and materials, etc. Priya's meticulous attention to detail and commitment to excellence make her an invaluable asset in the world of content creation and refinement.

(LinkedIn- https://www.linkedin.com/in/priya-pandey-8417a8173/)

Advances in Automotive Component Mold Design: Explore the Latest Developments

In the ever-evolving world of automotive manufacturing, advancements in auto part mold design are crucial for improving efficiency, precision, and overall production quality. The auto part mold plays a pivotal role in shaping the components used in vehicles, and continuous innovations in this area reflect broader trends in manufacturing technology. This article explores recent developments in auto part mold design and examines how these advancements are transforming the industry.

One of the key areas of advancement in auto part mold design is the integration of advanced materials. Traditional auto part molds were primarily made from steel, which, while durable, often had limitations in terms of weight and heat resistance. Modern auto part mold designs now incorporate high-performance alloys and composite materials, which offer improved durability and reduced weight. These materials enable manufacturers to create molds that can withstand higher temperatures and pressures, which is particularly important for producing complex and high-precision parts.

Another significant development in auto part mold design is the use of advanced simulation and modeling techniques. With the advent of computer-aided design (CAD) and finite element analysis (FEA), engineers can now simulate the behavior of auto part molds under various conditions before actual production begins. This approach allows for the optimization of mold design by identifying potential issues and making necessary adjustments in the virtual environment. As a result, manufacturers can reduce the time and cost associated with physical prototyping and ensure that the auto part mold meets the required specifications.

The evolution of manufacturing processes also contributes to advancements in auto part mold design. Techniques such as additive manufacturing, commonly known as 3D printing, have begun to play a role in mold creation. While additive manufacturing is still relatively new in the context of auto part molds, it offers the potential for rapid prototyping and the production of intricate mold geometries that were previously difficult to achieve with traditional methods. By leveraging 3D printing, manufacturers can explore innovative designs and create molds with complex features that enhance the functionality and efficiency of the final auto parts.

In addition to material and process innovations, advancements in cooling and heating technologies are making a significant impact on auto part mold design. Efficient temperature control within the mold is essential for achieving high-quality parts with small defects. Recent developments in mold cooling and heating systems, such as conformal cooling channels and precision temperature control mechanisms, help maintain good temperatures throughout the molding process. These technologies reduce cycle times, improve part quality, and extend the lifespan of the auto part mold.

Automation and robotics are also driving advancements in auto part mold design. Automated systems for mold handling, maintenance, and inspection contribute to greater consistency and reduced manual labor. For example, robotic arms can automate the loading and unloading of molds, ensuring precise alignment and fewer the risk of human error. Additionally, automated inspection systems can detect defects and inconsistencies in real time, allowing for immediate adjustments and reducing the likelihood of defective parts reaching the market. The integration of automation into auto part mold design helps streamline production processes and enhances overall efficiency.

Sustainability is another important consideration in modern auto part mold design. As the industry shifts toward more environmentally friendly practices, there is a growing emphasis on designing molds that reduce waste and energy consumption. Techniques such as the use of recycled materials in mold production and the implementation of energy-efficient processes are becoming increasingly prevalent. These advancements not only contribute to environmental conservation but also offer cost savings for manufacturers by reducing material and energy expenditures.

The role of data analytics and digital tools in auto part mold design cannot be overlooked. The collection and analysis of data from various stages of the molding process provide valuable insights that can drive further improvements in mold design and performance. Predictive maintenance, for example, uses data to anticipate potential issues with the mold before they advance to failures or downtime. By leveraging data analytics, manufacturers can make informed decisions about mold design, maintenance schedules, and process optimizations, professional to more reliable and efficient production.

Collaboration and knowledge sharing among industry professionals are also contributing to advancements in auto part mold design. Industry conferences, research publications, and collaborative projects provide platforms for sharing the latest findings, techniques, and ideal practices. These interactions foster innovation and enable manufacturers to stay abreast of emerging trends and technologies. By engaging with the broader community of auto part mold designers and manufacturers, companies can benefit from the collective expertise and drive further advancements in mold design.

In summary, advancements in auto part mold design are driven by a combination of material innovations, advanced simulation techniques, new manufacturing processes, improved cooling and heating technologies, automation, sustainability considerations, data analytics, and industry collaboration. Each of these factors plays a crucial role in enhancing the efficiency, precision, and overall quality of auto part molds. As the automotive industry continues to evolve, ongoing research and development in auto part mold design will remain essential for meeting the demands of modern manufacturing and ensuring the production of high-quality vehicle components.

Innovative Manufacturing Solutions for Industries

Tailored Component Production

Custom component manufacturing is the manufacture of parts with accordance to customers’ specification of designs and sizes. This method is crucial to industries which require certain parts which cannot be acquired in the market in a ready-made form. The processes of custom component manufacturing include; CNC precision machining, injection molding and metal 3D printing.

Efficient Mass Production with Injection Molding

The injection molding is a process of making parts by injecting material in a mold. Injection molding entails placing the material in a heated chamber melting it, then injecting it to a mold then cooling it to form the final product. It is often used in the production of large numbers of parts mainly because of its speed and versatility to produce various shapes and sizes of parts with close tolerances. The injection molding process involves several steps: include material preparation for the injection, cooling, and expulsion processes as well as the injection process. Initially, the material is melted by heating it.

When optimizing the injection molding process, the manufacturers can fabricate the desired components without the need for iterations preserving resource useage while providing high quality materials.

This technique is commonly used for plastics, but it is also borrowed in metal and glass production.

High-Accuracy Precision CNC Machining

Versatile Custom CNC Machining Solutions

Custom CNC manufacturing can be defined as the process of creating parts through the application of the CNC techniques as per the customers’ needs. Due to the open architecture, options for design and material selection in Custom CNC machining are virtually, limitless, therefore ideal for all types of applications. Customers make orders of the CNC machined parts over the internet with the help of online CNC machining services. It helps in the manufacturing process through a way that enables users to upload designs, materials, and get a quote.

By opting for online CNC machining, businesses can get all the possible options of machining without necessarily invest in the equipment.

It enables manufacturers to develop parts or items that are quite different from standard products in the market.

On Demand Sheet Metal Fabrication

As a business fabrication of sheet metal on-demand allows businesses to order new parts in sheet metal when they require it. It is most suitable for organizations, which need particular parts, but can hardly afford to invest in production facilities. The general use of sheet metal fabrication means that the various parts can be produced in large quantities and at a very short notice which make the acceleration of orders very easy. Thus, on demand sheet metal fabrication helps businesses to minimize their inventories’ costs and obtain the parts of the best quality.

Metal 3D Printing Services

Metal 3D Printing Services are defined as the delivery of metallic components through the utilization of AM. Metal 3D Printing Services is especially suitable for creating models, parts, and small batches of the product. Metals through the use of the 3D printing services enable complex geometrical structures and minimal wastage compared to the conventional manufacturing strategies.

Custom metal 3D printing enables innovation and the creation of efficient and high-performance parts among companies of various industries.

This undergoing is achieved through electrolytic deposition carrying out in batches to form the final product.

On-Demand Manufacturing

Computer numerical control machining of sheet metal for automated generation of hardware manufacturing services meets the requirements of individual customers in the hardware manufacturing industry. Demand CNC machining of sheet metal fabrication for hardware manufacturing industry helps to ensure that all formed parts conform to provided quality standards.

Thus, the use of on demand CNC machining sheet metal fabrication in manufacturing hardware products would improve the pace at which businesses produce and meet market needs.

This promotes the ordering of exact components on a case by case basis, hence is time saving and costs less in storage of inventories.

Specialized Component Manufacturing for Hardware

Component manufacturing as a business in the hardware manufacturing industry involves the manufacture of parts needed for the construction of the finished hardware item. This may comprise techniques like Computer Numerical Control (CNC) machining, injection moulding and sheet metal working. Component manufacturing for hardware manufacturing industry presupposes that all elements must be made according to required functionality.

Efficient Urethane Casting for Hardware

Urethane casting for hardware manufacturing industry therefore describes a fast growing process of making flexible and durable parts through a casting process in which liquid urethane is formed into molds. This is suitable for prototype production and short run production since it allows for great accuracy. Urethane casting for the hardware manufacturing industry has many advantages like short cycle time and cheap and reusable moulds. Thus, applying urethane casting for hardware manufacturing industry can lead to the realization of high quality parts, which conforms with the needed design and performance standards.

Precision Urethane Casting for Defense

Durable Urethane Casting for Energy Applications

Urethane casting for energy industry entail the manufacture of parts targeted at the energy sector including oil and gas sector, renewable energy, and electrical power industry. It is most appropriate in making parts for use in conditions that are sever and consist of high stresses and strains. Urethane casting for energy industry has the advantage as it enables creation of multiple shapes and designs in energy production that are highly durable. The application of the urethane casting for energy industry can make companies produce high quality and durable parts to improve the performance of the energy systems.

Conclusion

Finally, it has been ascertained that the concepts of industry-specific manufacturing solutions are vital for dealing with the execution demands and issues depending upon the field of the industry. Some of the common strategies for production engineering include, custom CNC machining, precision injection molding and advanced urethane casting, these can guarantee high quality parts that fulfill the specific requirements of a business.

FAQS

What is urethane casting used for in different industries?

Urethane casting the process of pouring the liquid urethane into molds, to create lightweight and very strong, flexible parts. It is suitable for Hardware manufacturing industries and preferably for prototype and low volume production Industries.

What does “on-demand CNC machining” mean?

On-demand CNC machining means the method of manufacturing a number of parts for products that is not produced in large quantities and is made only if there is an order for such part.

How does custom metal parts manufacturing differ from standard metal fabrication?

The procurement of custom metal parts manufacturing entails the creation of metal parts for distinctive dimensional and performance characteristics through processes such as CNC machining and metal 3D printing.

What is the Prototype Creation Process Like for an Injection Mold Company?

Are you planning to set up a workstation to develop products from scratch? Prototype creation and plastic injection processes are essential to any manufacturing process. Most Plastic Injection Mold Company follows a standard prototype creation process to create these products.

Injection models are easy to fabricate and can contribute to making dozens of sample parts. More accessible to produce and cheaper, they are used by designers and engineers to check their ideas and designs.

The Proper Process To Create an Injection Mold Prototype

Design

A detailed and efficient design is the first step in making a good prototype. It states the requirements, possible implementation, and the raw materials required.

With the evolving technology, several injunction processes exist for tasks of varying complexity. For high-precision tasks, companies prefer methods like Stereolithography (SLA). Whereas, CNC is used for simpler designs.

Mold Fabrication

Mold fabrication is the primary step in the prototype product development. This checks for potential design flaws and product issues before finalizing the design. Designing molds using aluminum and steel is expensive and costs more resources.

The preferred process nowadays is 3D printing the mold, which engineers and designers often use. The significant advantage of using a 3D printer for fabrication is the ease of making complex designs at a cheaper cost.

Injection

This process involves injecting molten plastic or the desired material into a mold. This mold is shaped like your final product and helps in the mass production of these tools. The raw materials are cheap, and the design errors are minimized.

As a Plastic Mold Supplier, it is the company’s responsibility to ensure that the molds and products provided to the costume are of good quality. In case of issues during prototype creation and deployment, the model is reviewed, and a new design is created to achieve the results.

Cooling

Since the plastic mold you have added is molten, it needs to be cooled down first. The cooling fluid is pumped into the mold to draw the heat away from the molded part. There are different methods that you can follow to achieve this.

The more popular choices are traditional cooling and conformal cooling. Traditional cooling involves drilling and milling. It is best suited for simpler designs. Conformal cooling introduces cooling channels that follow the geometry of complex design prototypes.

Ejection and Final touches

This is the final step in the prototype creation process. This involves taking out the mold after cooling. We check if it is suited for production based on its integrity and design. Once the prototype is solidified and ejected, it forms the product.

These products and models also undergo spray paint masking before they finally reach the customers. As a company, the final processing and product delivery, an outdoor payment terminal, is one of the options that you can use while paying.

Final Words

Prototype creation using the Injection Mold Process has boosted the production and integrity of models and products. With several options depending on the requirements or reference of the product, the manufacturing process has evolved.

Knowing about this product helps you design and streamline the process to get the product fast and in the best shape possible.Visit us.

Week 8: The augmented reality of filters

#MDA20009

Last week, we discussed the usage of body modification, and one of the things that were briefly touched upon was digital filters. In this week's blog post, I'll be expanding on that, and talk about filters in detail, as well as their relationship with augmented reality.

Reality, but... Different

Augmented Reality as a concept has existed since the 1960s. The first ever recorded instance of this technology emerged in 1968, when "the father of computer graphics", Harvard computer scientist Ivan Sutherland, developed an AR head-mounted display system (Javornik 2016).

Since then, scientists and developers alike have been trying to create an augmented reality system that could be used for practical purposes in everyday life. The first step towards this goal came in 2008, when German marketing agencies designed a printed magazine ad for a model of a BMW Mini. When held in front of a digital camera, a 3d model of the car would appear on the screen (Thi 2022).

The early 2010s saw an explosion of brands trying to incorporate augmented reality into their business model. From Toys-to-life games such as Skylanders and Disney Infinity, to virtual changing rooms, where consumers can "try on" products from the confines of their home.

One of my favourite applications of AR is to explore culturally significant locations from history. While learning about a place via reading books or watching videos is cool on its own, exploring the nooks and crannies of the Roman colosseum in its golden days, or taking a walk along the great pyramids of Egypt, all by pointing your phone at the ground, are experiences that you really can't get anywhere else (except maybe videogames, which, coincidentally, is the topic of next week's blog post 😉).

However, the most widespread application of augmented reality, by FAR, is digital filters.

The age of filters

Originally introduced in 2015, AR filters became an overnight sensation, forever embedding Snapchat into the public consciousness as "that app with the silly and cute filters". Since then, filters have evolved into an essential part of any social media platform, and it's extremely hard to find someone who has never at least tried one before.

Even though filters started out as something fun and harmless, it wasn't long until some people realized that they can be used to modify and filter out certain unwanted characteristics from pictures.

And thus, everyone decided to start looking exactly like each other...

While that was an exaggeration, it is still true that beautification filters completely changed the landscape of selfies worldwide. funny animal filters were replaced with ones that could make your face thinner, lips redder and eyes wider, all in an attempt to obtain the "ideal look".

Personally, I've never been a big fan of beautification filters. While it can be flattering to look at an "ideal" version of yourself, it can create and reinforce negative ideas that one may have about their own body, especially their facial features. When you can attain a conventionally attractive look with just a click of a button, it is almost impossible to not somewhat doubt your real level of attractiveness.

Constant exposure to Snapchat beautifying effects can also lead users to internalize societal messages that prioritize certain features as more desirable, pure, and beautiful. this can result in users detesting their own features and feeling pressured to conform to a specific image of perception, which may not align with their authentic selves (Barker 2020).

References

Barker, J 2020, ‘Making-up on mobile: The pretty filters and ugly implications of Snapchat’, Fashion, Style & Popular Culture, vol. 7, no. 2, pp. 207–221.

Javornik, A 2016, ‘The Mainstreaming of Augmented Reality: A Brief History’, Harvard Business Review, viewed 7 March 2024, <https://hbr.org/2016/10/the-mainstreaming-of-augmented-reality-a-brief-history>.

Thi, S 2022, ‘2008 - First AR ad | Atomic Digital Design’, atomicdigital.design, viewed 7 March 2024, <https://atomicdigital.design/blog-post/augmented-reality-and-the-future-of-advertising>.

Scope and Application of Selective Laser Sintering 3D Printing

Selective laser sintering is one of the most innovative and efficient techniques in 3D printing. It finds tons of applications in numerous industries. According to a report published by MordorIntelligence.com, the global 3D printing market was valued at US$ 13.7 billion in 2020. The report predicts the market to grow at a CAGR of 29.48% and reach an estimated value of US$ 63.46 billion by 2026. Selective laser 3D sintering is an innovative, new technique in additive manufacturing.

Also known as SLS 3D printing, this AM technique provides a quicker way for product design and development. This technique is efficient for creating highly-detailed 3D models and has been a boost in design, production and performance. It has provided a new avenue for materials, construction systems and architectural forms.

Scope and Application of SLS 3D Printing in 2021

The selective laser 3D sintering technique is in immense demand in the 3D printing industry. Some of the top applications and potential uses of SLS 3D printing are in the following industries:

Tooling Production

Selective laser 3D sintering technique is excellent for tool-crafting. It can create variety of tools, including fixtures, jigs, etc.

Rapid Prototyping

The SLS 3D printing technique is widely used in swift product conceptualizing. It is ideal for making proof of concept, early concept modelling, for crafting functional prototypes and for creating practical models for design evaluation.

Rapid Manufacturing / Quick On Demand Manufacturing

Selective laser 3D printing technique is also being increasingly used to rapidly manufacture items in various industries. This “on demand” production need often arises in production design and development which makes SLS 3D printing an ideal tool for rapid manufacturing.

Product Testing

The SLS 3D printing method is designed to create product concepts which pass the strictest quality and evaluation criteria. The product models creates using selective laser sintering are also ideal for environment testing, for instance when testing the effects of heat and cold on a potential product.

Parts Manufacturing

The SLS printing technique is also able to craft robust models, using a variety of different materials, and has found applications in manufacturing several functional components used in the automotive and aerospace industries.

Short Productions Runs

SLS printing works incredibly efficient for production runs that require manufacturing products in considerably smaller quantities. For instance, a company may want to release limited editions or launch varying models according to individual countries. It can also be used for creating samples and even personalized gift items.

Prosthetics

The SLS 3D printing technique has already been used to create prosthetics and orthodontic parts that function perfectly. Additionally, the technique also helps to create cranial implants thanks to its incredible precision in crafting 3D models.

Patterns

Selective laser sintering is also incredibly precise in creating mould inserts, foundry patterns and for casting without the need for expensive tooling.

Conclusion

Selective laser 3D sintering technique is one of the most efficient and effective 3D printing methods. The SLS 3D printing method finds excellent applications in several industries, including healthcare, aerospace, automotive, defence and numerous commercial ones too. Thus, it holds incredible potential in the near future.

Phenolic Resin Market: A Multifaceted Gem for Chemical Industry Professionals

The global phenolic resin market is a shining example of resilience and adaptability in the chemical industry. Valued at USD 11.7 billion in 2021, it's projected to reach a cool USD 14.4 billion by 2026, driven by a steady 4.3% CAGR. This growth isn't just happenstance; it's fueled by a potent cocktail of factors that make phenolic resins a true gem for chemical professionals.

Unveiling the Allure of Phenolic Resins:

Phenolic resins aren't your average Joe. They boast a unique blend of properties that make them the envy of the chemical world:

Heat Resistant Hero: Think scorching temperatures. Phenolic resins shrug them off with ease, making them ideal for automotive parts and electrical components that need to withstand the heat.

Molding Master: Need a resin that can be shaped into intricate forms? Phenolic resins are your go-to. They readily conform to your desired design, making them perfect for construction materials and insulation panels.

Strength in Numbers: Don't underestimate the brawn of phenolic resins. They possess impressive mechanical strength, making them the backbone of durable adhesives, wood panels, and foundry binders.

Smoke Signals of Safety: When things get hot, phenolic resins keep their cool. They emit minimal smoke, ensuring safety in applications like aircraft interiors and fire-resistant materials.

Polymer Playmate: Phenolic resins are team players. They blend seamlessly with other polymers, expanding their application possibilities and boosting their versatility.

Riding the Wave of Growth:

The allure of phenolic resins extends beyond their intrinsic properties. They're riding a wave of growth fueled by several megatrends:

Automotive Boom: The quest for fuel-efficient and lightweight vehicles is music to the ears of phenolic resin manufacturers. These resins enable lighter cars through their use in adhesives, reducing weight and emissions.

APAC's Ascendancy: The Asia-Pacific region, with its booming construction and automotive sectors, is becoming a hotbed for phenolic resins. China, India, and Indonesia are leading the charge, creating a vast and dynamic market.

Seizing the Opportunity:

Despite these headwinds, the future of phenolic resins is bright. Here's how chemical professionals can capitalize on this potential:

Innovation Incubator: Develop novel phenolic resin formulations that address specific industry needs and comply with environmental regulations. Think flame-retardant resins for construction or bio-based resins for sustainable solutions.

Target the Titans: Align your offerings with the booming automotive and construction sectors in APAC. Develop lightweighting solutions for cars and durable materials for infrastructure projects.

Streamline the Symphony: Optimize production processes and forge strong relationships with suppliers to mitigate the impact of volatile raw material costs.

Collaboration is Key: Partner with other industry players to develop advanced applications for phenolic resins, like self-healing composites or 3D printing materials.

Inquire  Before Buying : 

By embracing these strategies and capitalizing on the unique properties and growth potential of phenolic resins, chemical professionals can carve out a niche in this dynamic and rewarding market. Remember, the future is bright for those who can adapt, innovate, and collaborate in the ever-evolving world of chemicals.

3D Printing Services

Improve your business strategy and speed up your innovation by using our online 3D printing service. Benefit from the expertise of 3D printing professionals and start manufacturing high-quality products thanks to our cutting edge 3D printing technologies. Create your 3D design in any CAD software you want. We handle over many different file formats to answer all your 3D printing needs. 3D printers produce your prototypes and end-use parts with the highest attention to quality by our professional operators - 3D Printing in Toronto.

Explore completely different additive manufacturing processes and technologies to assist you to search out the best one for your workflow. 3D printed composite tooling and machining fixtures are often cheaper and sooner to provide conformally cooled inserts for injection molds can dramatically reduce cycle instances. 3D printing has long been used to shortly create prototypes for visible aids, assembly mockups, and presentation models. 3D printing was as soon as a fantastical dream that has turned out to be a reality. It is now an established expertise set for important expansion and growth - 3D Printing Service.

 In the early days of 3D printing, we were all excited about reproduction variations of architectural marvels and popular cartoon characters. Mostly, to show these prints in decor or nifty little toys and knick-knacks. Optimize your existing designs, explore a new additive manufacturing project, and push the boundaries of design with Nova Product Development Services Ltd. Get advice and expertise of design, process integration, and production to find your 3D printing competitive advantage.

Create plastic functional parts, metal 3D printed industrial parts, and visual prototypes with resin materials for a smooth surface finish. 3D printing applications are numerous and all sectors can benefit from its advantages for their proof of concept, prototyping, production or tooling processes. For more information, please visit our site https://www.novaproduct.com/

Ceramic Mug 11oz - Cardigan Welsh Corgi, corgis, herding dogs, mismark, white, Watercolor, cardigan corgi gifts Your favourite breed art print - head or body conformation - groomer gift - Other Breeds Available - dog breeder gift - regional specialty or national specialty prize gift idea Artwork by Ivy Fox Illustration Follow Ivy Fox Illustration on social media https://m.facebook.com/IvyFox.illustration/ https://www.instagram.com/ivyfox.illustration/ Find your dog breed: Personalized Pet Portraits: https://ivyfoxillustrates.etsy.com/ My website: https://ivyfoxillustration.com/ Art Prints Merch Original PaintingsWarm-up with a nice cuppa out of this customized ceramic coffee mug. Personalize it with cool designs, photos or logos to make that "aaahhh!" moment even better. It’s BPA and Lead-free, microwave & dishwasher-safe, and made of white, durable ceramic in an 11-ounce size. Thanks to the advanced printing tech, your designs come to life with incredibly vivid colors – the perfect gift for coffee, tea, and chocolate lovers. .: White ceramic .: 11 oz (0.33 l) .: Rounded corners .: C-handle .: Lead and BPA-freeContact Email: IvyFoxIllustration@ gmail(dot)com ———— Tags and other miscellaneous info: ———— Ivy Fox Illustration Ivy Fox dog art Museum of the Dog American Kennel Club Showsight - Where Champions Are Celebrated American Dog Fancier InfoDog Best In Show The Canine Chronicle AKC Gazette best pet portrait artist watercolor fine art unique art Akc meet the breeds Westminster kennel club dog show national dog show crufts grooming intergroom superzoo petquest groom expo dog sports well bred dogs purebred preservation breeders ethical breeders breeder of merit akc grand champion Ch – Champion of Record – earned by gaining 15 points in conformation wins. Points awarded is determined by the number of other entries the winning dog defeats. A dog must win at least two majors (by winning at two different shows under two different judges where there are enough entries defeated to equal 3-5 points by the AKC point system. OTCh – Obedience Trial Champion To earn an obedience title, the dog must have a passing score of 50% of possible points or better, and an overall passing score at three different competitions under three different judges. CD – Companion Dog (First Level Obedience Competition, basic obedience exercises) CDX – Companion Dog Excellent (Intermediate Level Obedience Competition, more advanced obedience work) UD – Utility Dog (Advanced Level Obedience Competition, difficult obedience work, including hand signals) UDX – The highest obedience degree AKC presently awards TRACKING TD – Tracking Dog TDX – Tracking Dog Excellent VST – Variable Surface Tracking HERDING HIC – Herding Instinct Certificate HT – Herding Tested PT – PreTrial Tested HS – Herding Started HI – Herding Intermediate HX – Herding Excellent HCh – Herding Champion AGILITY NA – Novice Agility OA – Open Agility AX – Agility Excellent MX – Master Agility Excellent NAJ – Novice Agility Jumper OAJ – Open Agility Jumper EAJ – Excellent Agility Jumper AKC Unofficial Titles CGC – Canine Good Citizen ROM – Register of Merit – A dog or bitch must earn a number of points specified by the DPCA rules, and also meet the numbers of champion and major pointed progeny required by DPCA. The requirements for bitches are less than the requirements for the dogs because males have the opportunity to produce a far larger number of offspring. ROMC – Canadian ROM ROM/C – designates that the dog has earned an American and a Canadian ROM. TT – Temperament Tested TC – Temperament Certified AOE – Award of Excellence-A dog must meet qualifications in conformation, obedience, and also be OFA´d to earn this award. New competitions are being added and rules for competitions change, for the most up to date rules and regulations, check with the AKC and the DPCA. Miscellaneous American titles often seen on pedigrees and in advertising. BIS – Best in Show at an All-Breed Show in conformation. BISS – Best in Show Specialty (where only dogs of the same breed are competing in conformation) BOB – Best of Breed BOS – Best Opposite Sex BOW – Best of Winners (best between Winners Dog and Winners Bitch in breed conformation class competition) WD – Winners Dog – the winning dog overall of the regular classes of his sex. WB – Winners Bitch – the winning bitch overall of the regular classes of her sex. RWD/RWB – Runner up to the winners dog and bitch, if the winner becomes ineligible for the award then the runner up will receive the points awarded from that show. Special – A dog that is already a Champion that is competing for Best of Breed only. A Champion cannot compete in the classes where points are earned (because a Champion has already earned them!) RTD – Registered Therapy Dog TD I- Dog has passed Therapy Dog International´s testing HEALTH CERTIFICATIONS OVC – Ontario Veterinary College OVC Hip Certification – A dog may be preliminary screened at a younger age, but will not receive a certification unless the dog is at least 18 months old. It was told to me by a tech in the radiology department of OVC that they consider hips to either be bad, in which case they are rated on a scale from 0 – 4, with 4 being the worse, or they are “good” in which case the animal will receive a certification number (if 18 months or older. Therefore they do not follow the U.S. rating system which includes “FAIR”, Good, Excellent”. Their exact words were “the hips are either GOOD or they are NOT. OFA – Orthopedic Foundation for Animals OFA Hip Certifications – dogs within a specified range of normal hip x-rays are certified OFA-Excellent, Good, or Fair OFA – Elbow Certification – Certified by OFA for normal elbows on x-ray, only one grade recognized as normal. Check with OFA for proper procedures and positioning for hip and elbow x-rays. A dog may be preliminary screened at a younger age, but will not receive a certification unless the dog is at least 24 months old. OFA is also now doing certifications for other canine health concerns such as normal thyroid levels, check with OFA for accurate data and rules concerning these. CERF – Canine Eye Registry Foundation-dog is certified to have normal eyes. Re-certification must be done annually. vWD – Von Willebrands Disease free-meaning the dog has been tested and found free of vWD, a bleeding disorder, vWD free ratings also are often given with a percentage listed. For the best information on Von Willebrand´s Disease, contact Dr Jean Dodds, who is the leading research specialist in blood disorders. Dog show prize idea

Additive Manufacturing & 3D Printing are interchangeable terms as they both describe the same process. It’s a technology where 3D parts are produced layer by layer from a material.

Additive manufacturing Process

The Additive manufacturing Process involves uploading your Computer-Aided-Design (CAD) designs directly to 3D Printer to deposit material, layer upon layer, in precise geometric shapes creating the desired Metal 3D model.

Metal Additive Manufacturing

Metal Additive Manufacturing or Metal 3D Printing is Production of 3D Parts layer by layer from a metal Material.

The print head moves horizontally and vertically and puts a new layer of build material with every pass making it possible to manufacture objects using a variety of materials.

The Metal Additive Manufacturing Technique is also involves using 3D object scanners to scan the object and direct 3D Printer to deposit material, layer upon layer creating the metal 3D Model.

This technology makes it possible for manufacturers to produce complex metal parts without any design constraints of traditional manufacturing. There are numerous benefits of 3D printing over Traditional Manufacturing namely no design constraints and complex parts can be corrected and printed quickly.

Metal Additive Manufacturing Materials

The most common Metal Additive Manufacturing Materials are namely Aluminum Alloy - AISi10Mg, Super/ Nickel Alloy - Inconel 718, PH1, GP1 and CX, Inconel 625 and HX, Stainless Steel - SS316L, Titanium - Ti6AI4V and Ti6AI4V ELI, Cobalt Chrome- MP1, Maraging Steel- MS1, Copper- CU etc.

Metal Additive Manufacturing Applications

There are numerous Metal Additive Manufacturing Applications as Additive Manufacturing is ideal for production of Low Volume and speciality Parts. We can design Functional Metal Prototypes, spare and obsolete Parts, Surgical and Dental Implants, Jewellery and decorative Arts and custom Tools quickly.

Metal Additive Manufacturing Advantages

There are numerous Metal Additive Manufacturing Advantages namely

• Design Flexibility - Use Smarter Design Geometries

• Quick Evaluation of Designs

• Create Complex Parts to deliver Maximum Performance

• Eliminate Tooling and Fixture Costs

• Rapid Product Development

• Low Raw Material Wastage

• Simplify Supply Chain using On Demand Tooling

Benefits of Metal Additive Manufacturing (Metal 3D - Printing) in Aerospace, Space, Defense, Automotive, Tooling, Oil & Gas Industry

We are outlining the benefit of Metal Additive Manufacturing across various Industries

• Create Complex Parts to deliver Maximum Performance

• Use Smarter Design Geometries

• Eliminate Tooling and Fixture Costs

• Increase Durability and Lifecycle of Parts

Benefits of Metal Additive Manufacturing in Defense Industry

• Rapid Product Development

• Reduce Part Weight by Producing optimised components

• Low Raw Material Wastage

• Produce Custom Spares and Components

Benefits of Metal Additive Manufacturing in Automotive Industry

• Design of 3D Printed Scale Models

• Prototype Validation in Pre - Manufacturing Stage

• Produce Samples and Tools at Low Cost

• Produce Custom and Lightweight Parts

Benefits of Metal Additive Manufacturing in Oil & Gas Industry

• Design Flexibility & Faster Product Development

• Economic Low Volume Production

• Faster Re-Manufacturing of High Value Components

• Simplyfy Supply Chain using On Demand Tooling

Veer-O-Metals is one of the leading Metal Additive Manufacturing company In India offering complete Metal 3D Printing Solution across Industries namely Aerospace, Space, Defense, Automotive, Heat Sink, Oil and Gas, Product Development, Conformal Cooling, Medical, Digital Inventory etc.

Veer-O-Metals (VOM) was established in 1965 and has augmented cutting edge manufacturing technology in the field of metal additive manufacturing which is an automatic process of manufacturing objects (Parts, Prototypes, tools & even assemblies) directly from their CAD models without any cutter, tools and jigs & fixtures.

As an organization VOM holds equal responsibility in meeting the industry standards, which keep us abreast of all the mandatory certifications, needed for a healthy sustenance. VOM has obtained the below certifications to meet the standards.

• AS 9100D: Certified ISO 9001

• ISO-45001:2018

• EN 15085 LL-C (Certification)

• ISO 14001: 2015

• Certified IATF 16949: 2016

• ISO 27001: 2013

You can call us at +91- 9739991967 or contact us at [email protected] or visit www.veerometals.com for all you Additive Manufacturing requirements.