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norckusa · 6 months

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Exploring Cutting-Edge Technologies in Custom Metal Part Manufacturing at Norck

Norck is a leading manufacturer in the custom metal part industry. With decades of experience under its belt, Norck has established itself as a trusted name in delivering high-quality custom metal parts to industries ranging from automotive and aerospace to medical devices and beyond.

But what sets them apart is their unwavering commitment to staying ahead of the curve when it comes to technological advancements.

At Norck, they understand embracing innovation is not just essential but also integral for survival.

They continuously push the envelope by investigating cutting-edge technologies that raise standards of quality, increase production, and ultimately provide their clients with unmatched outcomes.

Because it's so important to keep ahead of the curve in today's world, Norck is always looking for new technologies that could completely change the way metal parts are designed and made. Here, let's see some of the latest advancements in custom metal part manufacturing at Norck:

Additive Manufacturing (3D Printing)

At Norck, additive manufacturing is completely changing the Custom Metal Part production industry. Advanced technology makes it feasible to create elaborate and complicated designs that were previously unattainable with conventional manufacturing techniques.

At Norck, we make use of cutting-edge 3D printers made especially for producing metal parts. Numerous materials, including titanium, Aluminum, stainless steel, and even precious metals like gold and silver, are used in these machines. Using computer-aided design (CAD) models to direct the printer, these materials are deposited layer by layer during the process.

3D printing has a wide range of uses in custom production. It makes it possible to produce highly customized, intricately geometrized components that would be costly or difficult to create using traditional methods. Unmatched flexibility and versatility are provided by 3D printing, whether it is used for producing one-of-a-kind products or prototyping new designs.

Reducing material waste by using what is required for the particular part being created is one of 3D printing's significant benefits. When using traditional subtractive manufacturing techniques, extra material is frequently thrown during machining operations, which raises prices and has an adverse effect on the environment.

Furthermore, quick project turnaround times and iterations are made possible by 3D printing. Without the expensive tooling changes or protracted setup times connected with traditional manufacturing procedures, design updates can be easily applied.

Additive manufacturing allows for the development of lightweight structures with improved strength-to-weight ratios while also saving costs and time. Weight reduction is crucial in industries like aerospace and automotive, and optimizing internal lattice structures in printed parts allows for weight reduction without sacrificing structural integrity.

Norck is employing additive manufacturing to produce customized metal parts, which makes sense given its ability to customize, reduce waste, and increase efficiency.

The adaptability of 3D printing is one of its main benefits. It can be used in a number of industries, including consumer goods, automotive, aerospace, and medical devices. For instance, experts in the aerospace industry are using 3D printing technology to create vital, lightweight parts for aircraft engines and structures.

Custom metal part production projects benefit from 3D printing's unequaled flexibility for modification and customization. Complex designs can be easily achieved with minimal effort compared to traditional subtractive machining methods.

Automation and Robotics

The manufacturing sector has transformed because of automation and robotics, particularly in precision manufacturing. We at Norck understand that automated systems are essential to our manufacturing procedures. Robotics is a cutting-edge technology that can help us boost productivity and streamline processes.

Automation and robotics increase productivity while also improving product quality. By removing human error from repetitive operations like welding and machining, we can guarantee reliable outcomes every time. Robots reliably produce goods that satisfy tight requirements and tolerances because they perfectly obey programmed instructions.

Automation also enables us to reduce labor costs and increase production. We decrease the requirement for a large workforce on repeated operations that could otherwise be time-consuming and tiresome for human workers by depending on robotic technology for some areas of manufacturing.

Due to their exceptional accuracy and consistency in performing repeated tasks, robots are a crucial part of precision production.

One of the significant advantages of automation and robotics is the improved efficiency they bring. By implementing automated systems, production cycles can be significantly shortened as robots can work tirelessly for extended periods without fatigue or breaks.

One of the primary benefits of automation and robots is increased efficiency. With automated systems in place, production cycles can be considerably reduced because robots can work continuously for long periods without getting tired or needing breaks. That leads to faster fulfilment of custom metal part requirements, which ultimately makes customers happier.

By utilizing cutting-edge technology like automation and robots, Norck Manufacturing Company Ltd. has been able to maintain its leadership in the production of precise and high-quality custom metal parts. As we continuously work to improve our production processes, we're dedicated to investigating new developments in this area.

Advanced Materials and Material Analysis at Norck

At Norck, we are constantly pushing the boundaries of metal part manufacturing by exploring new and advanced materials. Our ability to adapt enables us to meet the unique needs of a wide range of sectors. The procedure entails the layer-by-layer deposition of material according to digital patterns, producing intricate geometries that would be very expensive or almost impossible to create with conventional techniques.

At Norck, we recognize how crucial it is to use cutting-edge materials and carry out in-depth material analyses in order to guarantee the best possible quality when creating custom metal parts. Our team analyses numerous materials used in diverse industries using state-of-the-art methods and technologies.

Regarding personalized production, 3D Printing offers numerous advantages. It not only significantly reduces material waste but also permits more design freedom. Prototyping is accelerated, and lead times for manufacturing runs are decreased. At Norck, we are dedicated to providing our clients with affordable solutions without compromising on quality or performance, which is why we are utilizing this cutting-edge technology.

Spectroscopy is one technique that does this; it analyses and identifies the constituent parts of a sample by measuring the interaction between matter and electromagnetic radiation. It helps us determine whether the product has any impurities or meets specific requirements.

We also study the composition and structure of crystals using X-ray diffraction (XRD) technology. Analyzing the interaction between X-rays and samples can reveal a lot about their physical properties, such as density, phase composition, lattice parameters, and more.

In addition to these techniques, we also use scanning electron microscopy (SEM) to obtain detailed high-magnification images of surfaces. SEM allows us to examine microstructures and surface imperfections that may affect a product's overall performance.

We also use non-destructive testing techniques; including magnetic particle inspection (MPI), eddy current testing (ECT), and ultrasonic testing (UT), to further improve our material analysis skills. By applying these techniques, we can find errors or faults without endangering the components that are being tested.

At Norck, automation, and robotics are now essential elements of precise manufacturing. Our production processes are more smoothly integrated with automated systems, which maximize accuracy while reducing human error. Robots are necessary for jobs involving repeated actions or securely moving large objects.

Numerous advantages result from automation and robotics: faster cycle times lead to increased productivity; reduced skill or fatigue variability among operators improves consistency; personnel removal from hazardous environments increases workplace safety; and so on. At Norck, we take advantage of these developments to maximize productivity along the whole value chain.

Another thing that spurs innovation at Norck is the exploration of novel materials. Our team is always looking into new materials that have better strength-to-weight ratios, resistance to corrosion, and increased thermal conductivity—all essential aspects to consider when creating high-performance metal parts for a range of uses.

Computer-Aided Design (CAD) and Simulation

At Norck, the use of computer-aided design (CAD) and simulation is essential to the production of custom metal parts. Using CAD software, details can be precisely digitally represented, facilitating effective design and prototyping. When compared to manual approaches, the capacity to see and manipulate structures in a virtual environment results in time and resource savings.

Another effective technique that Norck uses to foresee and stop possible manufacturing problems is simulation. Through the use of production process simulation, engineers can detect defects or inefficiencies in the process early on and avert costly errors later on. It lessens the need for rework or revisions throughout production, in addition to helping to ensure the quality of the final product.

In addition to preventing errors, CAD and simulation speed up design iterations. With computer-aided design (CAD), designers may experiment and make quick adjustments without having to start from scratch every time. It results in a faster development cycle overall, enabling speedier turnaround times.

An excellent illustration of how CAD and simulation have improved Norck projects is a recent customer who required a complicated, custom metal part with exacting specifications. With the use of CAD tools and simulations to evaluate several production scenarios, Norck was able to carefully design the piece and optimize its geometry for maximum performance while maintaining manufacturability within the required parameters.

The utilization of CAD software facilitates effective design iteration, while simulation helps anticipate problems prior to their occurrence. These two factors have a substantial impact on accelerating project schedules at Norck. Because these state-of-the-art technologies stop errors early in the manufacturing process, they guarantee the efficient delivery of high-quality products.

Precision Machining and Finishing

Precision is essential in the fabrication of custom metal parts. At Norck, they are aware of how crucial precision machining techniques are to producing goods of the highest caliber. They may have excellent outcomes since they use the newest technology and innovative methods.

One of the critical methods used in precision machining is Computer Numerical Control (CNC) machining. CNC machines use computer programming to control the movement of tools, resulting in highly accurate cuts and shapes. This technology allows for complex designs to be executed with exceptional precision.

Electrical discharge machining is another method used to produce outcomes with great accuracy (EDM). Tight tolerances and fine details are made possible by this procedure, which removes material from a product using electrical sparks. When working with hard materials or generating intricate shapes that would be difficult to create using conventional methods, EDM is helpful.

Apart from these methods, sophisticated measurement apparatuses are employed to guarantee precision throughout the production procedure. Coordinate Measuring Machines (CMMs) are devices that measure completed items precisely using sensors and probes. That allows for extensive quality control inspections.

But precise machining by itself isn't enough to produce superbly tailored metal parts. Precision finishing is equally significant. It is essential to ensure that the finished product is aesthetically acceptable, especially after all of the painstaking effort that goes into the machining process.

Norck uses a variety of techniques, such as grinding, polishing, sanding, and coating processes like powder coating or anodizing, since it understands the need for precise finishing. These processes improve the appearance and functionality of their distinctive metal components.

Norck invests heavily in the training of its professionals, who are skilled in utilizing these state-of-the-art mechanical systems while adhering to strict quality control protocols to create high-precision outputs through these processes consistently.

Every stage of the process at Norck, from designing with CAD software to carrying out complex cuts with accurate finishing touches, is focused on achieving perfection in the fabrication of custom metal parts by fusing cutting-edge technology with expert quality.

Sustainability and Environmental Considerations

Sustainability and environmental considerations are becoming increasingly important in the world of manufacturing. Norck is aware of this and has taken great care to reduce its influence on the environment.

Using sustainable practices throughout all of its manufacturing processes is one-way Norck does this? Every decision is made with the environment in mind, from recycling to energy conservation.

Norck guarantees that it not only satisfies industry standards but also goes above and beyond to protect the environment by implementing eco-friendly technologies and practices.

There are numerous benefits to these endeavors. To reduce expenses associated with material usage and disposal, Norck maximizes resources while minimizing waste. Not only does it help people increase their income, but it also makes everyone's future more viable.

Moreover, eco-friendly technologies typically yield higher-quality products since they are more precise and efficient. Reducing the quantity of rework or scrap materials generated during production further minimizes waste.

Furthermore, shoppers are choosing the companies they support more carefully when making purchases. By employing environmentally friendly practices, Norck enhances its reputation as a responsible manufacturer and attracts customers who share its values.

The implementation of sustainable manufacturing practices demonstrates Norck's commitment to environmental innovation and responsibility. We can anticipate even more developments in environmentally friendly solutions from businesses like Norck that work towards a greener future as technology continues to grow.

Training and Skill Development

Training and skill development are crucial aspects of operating new technologies in the field of custom metal part manufacturing. At Norck, they recognize that being abreast of the most recent developments is essential to preserving a competitive advantage in the market.

Norck has put in place a number of initiatives and programs for skill development to make sure their personnel is qualified to handle cutting-edge technologies. They offer thorough training courses that incorporate both practical and theoretical instruction. It enables staff members to get a complete grasp of how these advanced devices work and how to use them efficiently.

A key component of staying up to date with the rapidly changing trends in technology is continuous learning. Norck encourages its staff members to take advantage of possibilities for constant professional development, including online courses, seminars, and workshops. Employees may improve their abilities, keep current on industry best practices, and quickly adopt new technology by investing in continuous learning.

Technical proficiency is one of many things Norck values in its training program. By providing mentorship programs and leadership development opportunities, they also place a high priority on personal development. These courses not only give participants the technical know-how they need, but they also develop the strong leadership skills they need to encourage creativity in teams.

At every level of the company, Norck places a high priority on training and skill development to guarantee that its employees are competent in using new technology efficiently and effectively. This dedication eventually results in increased output, quality control, and customer happiness, all of which help a business keep a competitive edge in the marketplace.

Future Outlook and Innovations

Norck has an exciting and innovative future ahead of it as it keeps pushing the limits of custom metal part manufacture and technologies. The business is aware that in a field that is changing quickly, maintaining the cutting edge of technology is essential. That's why Norck places a high premium on continuing research and development.

Future technologies for the production of personalized metal parts have countless possibilities because of developments in materials science, automation, and digitalization. Norck hopes to produce intricate designs with accuracy and efficiency by employing state-of-the-art methods such as additive manufacturing (3D printing). It might completely transform production by optimizing supply chains, cutting waste, and boosting flexibility.

Norck acknowledges the significance of sustainable practices as a fundamental component of their forthcoming tactics. They seek to reduce their influence on the environment while maintaining high standards of quality in their products by embracing eco-friendly technologies and incorporating green initiatives across their operations.

Suiting oneself for upcoming industry possibilities and challenges necessitates ongoing improvement and adaptation. To provide its employees with the most up-to-date knowledge and skills necessary to use new technology successfully, Norck makes significant investments in training programs and skill development activities.

As the world continues to evolve, so does the field of custom metal part manufacturing. With advancements in technology happening at an unprecedented pace, companies like Norck need to stay ahead of the curve and embrace these innovations.

Nanotechnology is one possible future technology that might significantly affect the sector. Manufacturers can produce components with properties like improved conductivity or strength by modifying materials at the molecular level.

Another intriguing field that is making waves across industries is machine learning and artificial intelligence (AI). That is also true for the custom metal parts sector, where these state-of-the-art technologies allow for real-time data review, area identification for improvement, and even proactive maintenance predictions prior to any problems developing. AI-powered solutions hold a great deal of promise to optimize successfully.

With an eye toward the future, Norck is dedicated to maintaining the high standards of quality associated with its brand while pushing the envelope via innovation.

With a vision focused on innovation, sustainability, and skill development, Norck is well-positioned to lead the way into a thrilling future in manufacturing. By encouraging these partnerships, people can draw on outside knowledge and offer insightful commentary based on their own experiences.

Conclusion

Norck's use of these technologies has kept it at the forefront of the metal parts manufacturing business. You can put your faith in them to carry out your instructions since they are knowledgeable, trustworthy, and committed to excellence. If you're searching for a partner who can produce customized, high-quality products and who is receptive to new ideas, Norck is a perfect choice. Find out how their cutting-edge technologies and expertise may help you bring your ideas to life.

#Custom Metal Part Manufacturing #Custom Part Manufacturing #Plastic 3D printing #Custom Component Manufacturing #Advanced 3D Printing

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brasscncturnedparts · 4 months

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Brass CNC Turned Parts and Components Manufacturer in India

GK Metals is Jamnagar, India based manufacturer, supplier and exporter of high-quality customized brass CNC turned parts, brass CNC turned components and brass CNC machining parts with great precision & accuracy. Our CNC turned parts are made from brass, copper, bronze and stainless steel materials.

#brass cnc turned parts #brass cnc turned components #brass cnc machining parts #customized brass cnc turned parts #brass cnc turned parts manufacturers #brass cnc turned components manufacturers #brass #brass parts #brass components #gk metals

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custommanufacturing · 2 years

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https://promarkmfg.ca

Get the Right Job Done with Custom Metal Parts Manufacturing Services!

Unable to find a trustworthy custom metal parts manufacturing service? Promark Tool & Manufacturing can solve your problem! They understand what is required for different product designs. Visit the website or talk to the company representative to get a quote today.

#Custom metal parts manufacturing

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ogisengineering · 2 years

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#bending services sydney #custom metal fabrication #sydney public art fabrication #metal engineering #welding services #linished stainless steel"#OGIS ENGINEERING PTY LTD is located in MILPERRA #NEW SOUTH WALES #Australia and is part of the Other Fabricated Metal Product Manufacturing Industry. OGIS ENGINEERING PTY LTD has 15 employees a t this loca

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wainwrightjakobshammerlock · 8 months

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What I think disability aids made by Borderlands gun manufacturers would be like. CW for mentions of systemic ableism and weight loss.

Atlas: Sleek and fancy, but also expensive as hell and prone to accidents. Sort of like IRL fancy prostheses or wheelchairs - they seem cool but are actually kinda sucky and very pricey. Don't expect the average Promethean to afford one. Though in this case, it's because they're often loaded with purely experimental tech that was probably shipped too early.

Hyperion: They make a few prosthetic and implant models and that's it. Pretty much all their stuff is aimed at their own employees trying to get "ahead" and not actual disabled people, so give up trying to find one fitting your particular needs. At least they're pretty fucking sturdy (but not against hacking). And no, they haven't thought of adopting those exoskeletons their engineers use for other needs.

Maliwan: Similar to above, but aimed at their general customer base instead. These guys are hipsters who try marrying form and function, and in many cases that means augs of some sort. I wouldn't really call them transhumanist though, that implies respecting bodily autonomy, human rights and not being ableist; these guys would sell arms with tracking chips and neural interfaces that fry your brainstem if you don't pay the subscription fee. And then tell you to lose weight with the new fad diet their marketing department cooked up. The hoverchairs and flavored chewelry are pretty great, tho.

Dahl: They wouldn't. They claim to be reliable but they're actually the biggest cowards in the Six Galaxies. If one of their soldiers loses a leg or something that's grounds for being (dis)honorably discharged. What exoskeletons or other devices they make are purely for war. Plus, the one Dahl employee we see having a prosthesis (Helena Pierce) doesn't seem to have a Dahl brand one. Aside from weird metal rank implants and funky gun-inspired fidget cubes they don't do much in this department.

Torgue: Expect everything to be painted like a Hot Wheels toy and probably explode somehow - either on you or on your enemies. All the mobility aids have jets attached for either smacking ableists with great force or speeding through town. I think Torgue himself wears a hearing aid (from all the explosions) and it looks like a fucking microphone with car parts on it, complete with exhaust.

Jakobs: Steampunk baybeee!!! Of course, the subgenre of said steampunk depends on the quality of the aid. The most basic ones are IRL Victorian era metal arms: flat, spiky, inhuman, but still quite ornate. The ones custom-tooled for execs and their families (looking at you, Alistair Hammerlock) are more "sleek" steampunk, with fine chassis of signature Jakobs brass and filigree engravings. They also make genuine wood canes with organic rubber grips that will outlive you if you take proper care of them... which is definitely shown in their price tags. The Jakobs stim toy line is half weird gear contraptions, half competition with Dahl's fidget cubes.

Vladof: Heavy, clunky, dieselpunk style. But damn if they aren't effective. A standard Vladof boostchair could break through a wall and be completely unharmed. A Vladof AAC device looks like an electron tube supercomputer that you have to haul around in a cart. That's all I really have to say here.

Tediore: I have no idea.

#my post #borderlands #text post #headcanons #disability tag #50

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lubedoo · 1 month

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And here’s what @e-vay and I were talking about. From the Sonic the Hedgehog fandom, chapter 1 of my fanfic proposing an origin story for e-vay ‘s original character CC. Check out her blog for her awesome art and content!

Chapter 1 - Walter’s Widgets

“No, this won’t work… the gear pitch is misaligned to the functional plane!”

The camera aperture on the small robot’s spindly head focused in and out on the tiny interlocking mechanism as its grouchy furred boss pointed at the offending interface with thin metal pick. Its pincer-like hands reached for the device, but it was quickly snatched away. The robot retreated a few feet on its wheelbase at the sudden movement.

“It has to be at the correct angle or it will bind and fail prematurely!” He looked sternly at the two droids standing in front of him, the second a more squat construction containing a platform and several manipulators. “Assembler, you have the steady table and precision arms. Can’t you work with Gear Placer to match these up?”

Assembler responded in a series of low hums and groan-like noises, while Gear Placer rattled off high-pitched squeals and beeps.

“Wait, whoa… one at a time.” The old woodchuck removed his glasses and grasped the bridge of his nose. “I can understand both of you but not when you talk over each other. Didn’t the interface chips I installed help with translating your machine languages?”

Gear Placer reached a pincer inside an opening in its head and plucked out a small circuit board, which clearly had been overtaxed. The melted wires and burn marks were testament to its overuse and failure. Assembler groaned about its being in a similar condition, but was unable to remove it given its location.

The woodchuck sighed as he examined the ruined electronics. “I suppose that’s what I get for cobbling you all together from different control boards and drivers. I never expected my Widget business to be so complex.”

Walter Woodchuck had built WW Widgets into a local phenomenon. It started as a hobby business, building little devices for himself and his friends in his garage workshop. But word spread about his clever and unique designs, and suddenly customers were sending in requests from as far as Reclusivia. It provided him with a nice retirement income and kept him busy for sure, but he knew he needed help if he was to keep building these devices to his exacting standards.

And Walter was by no means a “people person.” He tried hiring a few Mobian assistants but none lasted very long. He was very particular in how he wanted things done, and few of his hired help was willing (or able) to keep up with his demands. Even his nephew William could only last for short stints in the WW manufacturing area before needing a periodic “sabbatical.”

So Walter decided with the size and scope of his business to move out of the tiny garage and into a “Fabratory” he had built towards the back corner of his property. It was a moderately sized but impressive facility that functioned as a device development lab, a manufacturing floor, a warehouse, and a store front. The store was more of an Automat, with remote payment devices and clear-doored cubbies where his customers could pay for and retrieve their items. It was very rare that any of them met with or even saw Walter… and he liked it that way. There was even a small living space so he could spend as much time as he wanted in his own little world. He would send one of the robots for supplies as needed, and the store owners in town knew Walter was good for payment.

But as with Walter and the outside world, communication among his robots was severely lacking. He built them as the need arose, from Circuit Solderer to Chip Mounter and Metal Stamper to Test Aligner. Their names were childish but functional, as Walter didn’t see the need to personalize his creations, only to have them do their job as they were told. And since they were constructed over time, the parts available to build them varied as did their internal machine languages, resulting in a maddening (to Walter) Production Line of Babel. The robots understood everything Walter told them but little of what the others twittered and beeped. They were still effective in producing wonderful Widgets, but frequently also manufactured a lot of stress for Walter.

Walter turned back to Gear Placer and Assembler, impatiently explaining to each what needed to be fixed on the device they had presented. They both excitedly responded in their own languages and raced off to fix their mistake.

“There has to be an easier way,” the tired woodchuck grumbled. “Maybe if I built another robot, one that could understand all their code and interpret for them… and me…” His voice trailed off as he turned to his drafting table and began drawing up yet another design.

After a few hours of intense thought and technical sketching (and with a few interruptions from the Production floor), he looked at his newest blueprint. “Yes, this should do nicely. I’m sure Oscar has the proper processors, auditory inputs, and servo impellers to make this happen. It will be my most advanced creation yet. I’ll need it to be able to learn, accept and provide feedback, and adapt to our design changes.” His brow furrowed. “This is going to be somewhat expensive, but that latest Widget order from Spagonia should cover the cost. Well worth it.”

He looked over the plans again and leaned back in his chair. Walter crossed his arms, smiled, and relaxed a bit. “Yes, you will be a great help to me… Code Compiler.”

#e vay #cc the ai #sonic the hedgehog #fanfic

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is-the-battlemech-cool-or-not · 2 months

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Transmission begins:

> message loading...

> loading... > message loaded

> decrypt? [Y/N]

> Y

> displaying message:

Origin: Canopus IV

Destination: Terra / Islington

Subject: Deployment of Magistracy Armed Forces for Operation TOUCHDOWN

Message: ALCON, 1st Canopian Cuirassiers have arrived at Islington. Available for tasking at discretion of Local Force Commander. Glory to the Magistracy.

Commanding Officer: Colonel Inanna Allard-Liao (see attached personnel file)

TO&E: 1x BattleMech battalion - 36x BattleMechs [8x Assault, 24x Heavy, 4x Light] (1 CANOPIAN CUIR.) 1x AeroSpace group - 18x aerospace fighters (1 CANOPIAN AIR GUARD) 1x Armor battalion - 72x armored fighting vehicles (1 CANOPIAN ARM. GUARD) 1x Infantry battalion - 448x infantry (1 CANOPIAN INF. GUARD)

> message ends

> open attachment 1? [Y/N]

> Y

> opening attachment:

// MAGISTRACY ARMED FORCES \\

--This information is not for public distribution.--

INANNA ALLARD-LIAO

Rank: Colonel, Commanding Officer 1st Canopian Cuirassiers

Assigned Unit: Command Lance

Personal 'Mech: Yaguara 'Inanna' YGR-2D-IAL

Date of Birth: 3103-04-28

Parents: Melissa Allard-Liao & Fredrik Allard-Liao [Né Richardson]

Age: 50

Listed Gender: F

Physiological Details: Full genetic modification treatment [extreme; "Animalia conversion", subtype: snow leopard] - performed @ Ceres Station - Terran System - 3119-04-28

Height: 190cm

Weight: 97kg

Eye Color: Grey

Languages Known: English (First Language),

Organ Donor: Y

Dependents: none (5 adult children)

Current Location: [Redacted]

COMBAT EXPERIENCE

32 years enlisted in MAF

7 large operations

25 deployments

22 combat deployments

[Redacted] confirmed kills

102 battlemechs incapacitated/destroyed [ranged]

69 battlemechs incapacitated/destroyed [melee]

199 combat vehicles incapacitated/destroyed

10 aerospace craft downed [ranged]

3 aerospace crafted downed [melee]

1 dropship downed [ranged]

1 dropship downed [melee]

Areas Deployed: [Redacted]

Awards: Canopus Cluster [Platinum w/ Ruby], Fist of Raventhir [3152], Bravery Medal 1st class x12, Combat Excellence Ribbon x5

> open attachment 1? [Y/N]

> Y

> opening attachment:

// MAGISTRACY ARMED FORCES \\

--This information is not for public distribution.--

Yaguara 'Inanna' YGR-2D-IAL

Mass: 75 tons Chassis: Earthwerks TDR IV Power Plant: Vlar 300 XL Cruising Speed: 43.2 kph Maximum Speed: 86.4 kph Jump Jets: Rawlings Model 60 Jump Capacity: 120 meters Armor: Hellespont cFF Armament: 1 Rotary AC/2 2 ER Large Laser 2 Medium Pulse Laser 1 Medium Vibroblade

Manufacturer: Majesty Metals and Manufacturing Primary Factory: Unknown Communication System: Tek BattleCom Targeting & Tracking System: Tek Tru-Trak Introduction Year: 3146 Tech Rating/Availability: F/X-X-X-X Cost: 27,480,250 C-bills

Overview

Proposed as part of Project BIG CAT for the Magistracy of Canopus, the Yaguara was designed by Majesty Metals and Manufacturing in 3146 as a fast moving, hard-hitting heavy 'Mech.

This custom variant, built for Inanna Allard-Liao, possesses an extremely dangerous close combat weapon - a 'Mech vibroblade, mounted on a 'Mech-scale myomer tail, in addition to most of the weaponry of the base configuration.

Capabilities

The Yaguara was built from the ground up with speed and long-ranged engagement in mind. Built around a supercharged Vlar 300 XL engine, the 'Mech can sprint over 86 kph, allowing it to keep up with lances comprised of much lighter 'Mechs than itself. It complements this ground speed with four Rawlings Model 60 jump jets, granting it a jumping distance of 120 meters for an extra mobility boost. Its armament is built around a pair of Clan-spec ER Large Lasers, uncommon in the region, and a Class-2 Rotary Autocannon, with a pair of SRM 6s and medium pulse lasers as close-engagement backups. All of this, unfortunately, comes at the cost of heat - the Yaguara was designed with bracket fire in mind, and MechWarriors are advised not to alpha strike without due cause. This custom variant was built for Inanna Allard-Liao. It is a hybrid Clantech refit, using many experimental technologies, as well as the removal of the previously-mounted SRM 6s, to allow for the addition of a custom myomer armored tail, with a 'Mech scale vibroblade mounted to the end. Complimenting this weapon are Triple-Strength Myomer and a Supercharger, to allow the 'Mech to reach truly incredible speeds for its weight.

Controlled by Inanna using a salvaged Word of Blake Buffered VDNI system, the 'Mech moves with the same fluid grace as its pilot. Advances in Belter/Canopian hybrid medical science have extended Inanna's lifespan estimate from 15 years to 75, and are predicted to have significantly extended the initial onset period for the madness which often accompanies use of neural interface systems.

Type: Yaguara 'Inanna' Technology Base: Mixed (Experimental) Tonnage: 75 Battle Value: 3,768

Equipment Mass Internal Structure Endo Steel 4 Engine 300 XL 9.5 Walking MP: 4 Running MP: 6(8) Jumping MP: 4 Double Heat Sink 15 [30] 5 Compact Gyro 4.5 Interface Cockpit [VDNI] 4 Armor Factor (Ferro) 231 12.5

Internal Armor Structure Value

Head 3 9

Center Torso 23 35

Center Torso (rear) 11

R/L Torso 16 24

R/L Torso (rear) 8

R/L Arm 12 24

R/L Leg 16 32

Right Arm Actuators: Shoulder, Upper Arm, Lower Arm, Hand Left Arm Actuators: Shoulder, Upper Arm, Lower Arm, Hand

Weapons and Ammo Location Critical Heat Tonnage 2 Jump Jet LL 2 - 2.0 Nova Combined Electronic Warfare System CT 1 - 1.5 Supercharger CT 1 - 1.0 CASE II RT 1 - 0.5 Medium Pulse Laser RT 1 4 2.0 2 Double Heat Sink RT 4 - 2.0 Rotary AC/2 Ammo (90) RT 2 - 2.0 3 Triple Strength Myomer RA/LA 3/3 - 0.0 ER Large Laser LA 1 12 4.0 Vibroblade (Armored) LA 2 - 5.0 Medium Pulse Laser LT 1 4 2.0 Double Heat Sink LT 2 - 1.0 Rotary AC/2 LT 3 1 8.0 2 Jump Jet RL 2 - 2.0 3 Triple Strength Myomer RA/LA 3/3 - 0.0 ER Large Laser RA 1 12 4.0

Features the following Design Quirks: Animalistic Appearance, Battle Computer, Battle Fists, Battle Fists, Combat Computer, Directional Torso Mount (Vibroblade), Fine Manipulators, Hyper-Extending Actuators, Improved Communications, Improved Sensors, Multi-Trac, Nimble Jumper, Reinforced Legs, Rugged (1 Point), Difficult to Maintain

#battletech #mechwarrior #story event #oc lore #(OOC: new muse!)

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vinceaddams · 2 years

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Top 5 WORST fabrics

1. that fuckign. synthetic knit that some of the sport coats at work are made of. I don't know what it's called but I hate it. It's polyester with barely any stretch and is. so. DENSE. Worst thing to alter. Damn near impossible to get a pin or a hand sewing needle through, and sometimes it makes the machine skip stitches. A lot of the sport coats are half lined, and if you bring me one of those ones with the side seams pinned to take in, I will just take in the centre back seam instead because I DO NOT want to hand sew the lining back down to both entire side seams on that horrible impenetrable bullshit fabric. Sometimes it has a woven looking pattern printed on it, as if to mock me.

Some of the shirts at work are made of a slightly softer version of the same stuff, and I once tried to mend a small hole in one of them using a zigzag stitch and it shredded the fabric and ruined the shirt. They had to go find the customer an identical replacement shirt, because the stupid fabric couldn't hold up to a few tightly spaced zig zags. Bullshit, bullshit garbage fabric. I hate it, I hate it I hate it I hate it. Everyone should stop manufacturing it immediately. Stop making it and destroy the formulas so nobody can ever make it again. It's not even a particularly bad texture to touch, relatively speaking, it's just a nightmare to sew.

2. Faux fur. To be fair, there is some decently nice faux fur out there, but most of it is just such an icky plastic-y texture and it sheds so much. So so much, and then you're worried about breathing in floating fuzzies of plastic. And it can also be really hard to get a pin or needle through the base fabric, depending on what kind it is. I remember I had some scraps of white faux fur that I used for craft projects as a small child, and it was like that, and there was some kind of finishing (presumably to help glue the hairs in place) that made the back of the fabric all crusty. It's the kind of thing that's awful to touch if your hand is even the slightest bit sweaty. I dislike polyester fleece for the same reason. No fleece sheets or pyjamas for me, ick!

3. Really loosely woven boucle. Who would invent a fabric that frays so gotdamn much? Look at this. (image source) Awful. Falls apart if you sneeze at it. Unpleasant texture, and not even nice to look at. (Yes I chose an ugly picture on purpose, but it's not a look I like even if it is in nice colours.)

Where's your structural integrity?? You can have weird lumpy fabric and still weave it decently tight! Especially if it's wool and you felt it a little bit. I shortened a skirt for a co-worker and it was made of similar stuff, and I was worried I'd damage it because it was so loose and shifty. What happens if you walk by a tree or something and snag a thread? Whole thread comes out and deforms a big patch of fabric? Well that's what you get for making all your threads just acquaintances instead of best friends. (I hate poly chiffon for similar reasons.)

4. Poly/cotton blends, because they feel like a betrayal. You could have been 100% cotton but you aren't :( Could have been a nice comfy shirt or nightgown that could eventually be used for firestarters once it's too worn out, but no, can't use blends for kindling because the polyester part melts into nasty little black plastic blobs. Not like 100% cotton or linen, which burns nicely and leaves basically no ash. And I hate pilling, horrible hell texture, and synthetics tend to pill way more.

5. Anything with glitter on it, because it's contagious. Small sequins are also bad (see blog post linked in poly chiffon line) but at least they're sewn on and only come off where you cut them. I think we as a species have moved past the need to glue glitter onto fabric, because it does not stay glued. We have foil print, and metallic ink, and beading and rhinestones and metallic thread and all kinds of other ways to do the sparklyshiny. No more sticking glitter on things that might go in the wash.

Generally speaking I dislike synthetics and Bad textures, though everyone's opinion of bad textures is different. I'm also not fond of stretch knit, but it has its uses.

#ask #ask meme #fabric #sewing

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clockworkcontraption · 2 months

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it all started rather innocently. we just found two magical rocks in our d&d campaign - one that produces heat, and another that creates water. my character (well, okay, my character was a warlock and not an artificer, so it was mostly me, really) put two and two together and figured out that this may be used as an infinite source of steam. tech level of our campaign allowed us to manufacture or commission custom parts made of metals like bronze, copper, platinum, et cetera. and so, shenanigans ensued. out of character, i devised a contraption that would shoot a blast of steam and parboil anything that stands in front of it. war crimes, yay!

so, i turned to fusion360 to produce a feasible design for this nightmare contraption. as we had access to copper and bronze, i figured out that a simple tube shape with a conical nozzle could realistically withstand the heat and hold the steam pressure. one compartment holds the water rock, the other has a copper radiator with the heat stone inside of it. pull the lever, water contacts copper, water go whoosh and boom, steam cannon! for some unknown reason, i actually turned to thermodynamics and material science to figure out how thick the tubes should be. i suppose i was just taken by fey mood and went full turbonerd on this. ah well.

then, the first prototype was finished and rendered. after some back and forth, and quite a bit of negotiating with our DM (i'm really sorry for exposing you to my bullshit, Telen) we agreed that this could feasibly be produced within our setting. but something felt off. i was not quite satisfied with how it looked.

i carried on and added a collapsible tripod for easier deployment, and a handle on the top for better portability. (realistically, of course, this contraption would be awfully heavy, and only the strongest member of our party could carry it around. ah well). and finally, i had a stroke of inspiration. or maybe just a regular stroke. i though, what if we build up the pressure instead of just releasing it immediately? what if we somehow block the main nozzle for a while, and let it cook? the blast would be much stronger when you finally release it. and so -

the final version took form. i added a sliding attachment to the main nozzle that could block the output for a while (we figured it would be reasonable for it to take a full turn in combat to build up steam pressure), and then release it through one of the nozzles. and as the final stroke, i named this abomination - "Heated Exchange".

witness.

#3d model #dnd #steampunk #3d art #3d render #3d artwork #my project #d&d #fusion 360 #contextless #metalwork #nerd shit #turbonerd

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mxmparts · 1 year

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China metal parts manufacturer Custom CNC turned parts for World customers, competitive CNC turning steel turned parts Customize Service. mxmparts.com

#china metal parts #cnc turning #mxmparts #turned parts #custom parts #china steel parts #china turned parts #cnc turned parts #china cnc turning #steel parts manufacturer #steel turned parts #china supplier

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foobagorch · 2 months

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Working on a robot today

I work on a team that develops combat robots, and it is a very tedious task. This year alone I have put hundreds of hours into designing, prototyping, assembling, testing, and manufacturing our robot. I’ve made computer models, 3D printed components, worked with metal parts, developed organizational systems, drafted engineering drawings, drawn logos, and so much more. Every weekday im working on this thing and somehow even now theres still stuff left to do. Just today I was hoping to finish my work, so I would have time to relax and chat with some friends at the end of the day, but just as I finished all my work and was about to take some time off our driver comes in with the robot and points at the wheels. The wheels, which are custom made by our production team, were falling apart, even though we had just put them on a couple minutes ago. The outermost layer of rubber on the wheels was peeling right off. This hadn't happened with any of our other wheels so naturally my first thought was, “What the heck?? There goes my free time.” I disassembled the robot and removed one of the wheels to look at it, and then compared it with a matching wheel from one of our older sets.

The wheels are made by pouring liquid rubber around a plastic hub in the center so that when the rubber hardens around the hub it locks in place. Heres a picture that kinda shows how the two pieces go together:

(Sorry for terrible quality I drew this on a phone)

The newer wheel had a ton of bubbles in the rubber, and was way squishier than the old wheel. Too much air must have gotten in when we were mixing it and not gotten out when it hardened. Think of a block of foam verses a plastic brick. If you rub foam on sandpaper it’s just going to disintegrate because it has a bunch of air in it, while the plastic brick is going to take longer to degrade because it’s more dense. The old wheels were much more resistant to tearing because they were more dense. The new wheels were less dense because of all the bubbles, meaning that they just shredded apart when they rolled on the floor. Our only option here was to remove the bad rubber from around the hubs and re-cast the wheels. Unfortunately, removing the rubber really sucks. Or… at least it does when the wheels are cast properly. The squishy bad rubber came off really cleanly, and didn’t adhere to the central hub properly when it hardened meaning it was easier to remove. It still was difficult to take off because you kinda had to wedge a screwdriver between the hub and the rubber and pry it off, but not as bad as having to cut the rubber into chunks and manually scrape it off because it’s stuck to the central hub. Eventually I figured out that you could just put the wheel in a press and squeeze the hub right out of the rubber. It was super fun using the press to remove the rubber, and I was sad when I finished all of the wheels because now I couldn’t use the press anymore. So that took up all my free time but at least we don't have to deal with that later, hooray.

(oh also the robot cut me twice today because its really stinking sharp on the front :/)

#Robotics #Rubber casting #combat robotics #Battlebots #Wheels #Manufacturing #infodump #Yippeeee

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easoomade · 7 months

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Toasting to the Quirks of CNC Machining Description: Let's chat over a beverage about the fascinating occurrences in daily CNC machining. Discuss your adventures in customizing metal parts. #CNCMachining #CustomMetalParts #Manufacturing

#CNCMachining #CustomMetalParts #Manufacturing

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rametarin · 6 hours

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silly WH40K inspired idea.

It's the year XXX in the future. A cabal of people exist that take up a paladin-esque role with elements of cowboyism and monastic trappings.

As part of the graduation, the prospective member of the order is provided the hand tools necessary to construct their own firearm. They must design it on paper and utilize simulator technology to prove the design is safe and capable of withstanding the brutalities associated with its own existence. Unwise decisions that result in the operator's self-harm or destruction of the firearm are possible, and politely discouraged.

But every member of the group effectively needs to be capable of being an engineer and gunsmith, able to turn raw ingredient metals into components for firearms and ammunition. The organization supplies the education necessary, and at least information on how to hand make the tools to make firearms, but it's ultimately up to the prospective gunsmith to smith them.

There'd also be an organization standard for firearm blueprints and ammunition size and case style. Exactly what, I don't know, but the organization's emphasis is on being able to make that exact kind of firearm almost anywhere on planet earth from locally available rocks, sunlight and parabolic mirrors (for the heat) and component molds.

There'd be a trial to just make Whatever Was Necessary to fire a bullet at a target to a minimum small arms range, and then exceptional marks are made for ranges exceeding the length of the curvature of the earth, and a separate trial to be able to make an Organization Standard Performance Rifle, out of materials ideal for that (assuming care would be taken to acquire the necessary materials, not just scrap together something that just has to survive firing a bullet once.)

Reason being is the continued education in the traditions of the personal firearm, as well as other force multiplier forms of weaponry, and the continued fabrication of such when you have a minimum of material components to work with. And yes, the implication such materials might be being bottlenecked and withheld from the public is not an accident, but the organization's trials and system assumes as much, that simple trade and procurement may not be possible or legal.

That's the lowest level member. Being able to make your own small arms is the minimum base requirements for initiation. Above those are the Large Arms makers. Kinetic weapons that are just really big guns that may or may not require multiple people to man. This includes everything from mortars, to howitzers, to artillery, to anti-air gun batteries. Whom similarly operate under the idea that the only way these things might exist in an area, is if they know how to personally manufacture and fabricate each and every component themselves.

Perhaps they have some process to work backwards and marry carbon with hydrogen to create propellants. Perhaps they eschew "messy" forms of propellants and use some custom material that is effectively just hydrogen, for light gas guns. That'd be neat. I'm not 100% sure. But I do know as the component of a kinetic weapon, it'd be another part of the manufacturing process of your own gun and ammunition.

Why light gas guns, specifically? Because when you use hydrogen as a propellant, it burns cooler (temperature-wise, I don't mean, 'that's cool/awesome') and has greater impulse. A person so inclined could literally fire a payload and escape the earth's orbit with it, while conventional propellants cannot do this. Hydrogen gas or liquid as a propulsion system means very very fast projectiles that can conceivably move so fast that they tear themselves apart in the atmosphere. When you need to fire something screaming and generating its own plasma out into space from the ground, but you can't use a railgun, you go to the Light Gas Gun guys.

Above them would be the Electropropulsion Systems. Yes, I'm talking railguns and coil guns. Due to the sheer complexity and investment in materials required for the magnets and armatures, considered somewhat impractical, but when you need absurd range and power and want a simpler propulsion system, you go to the coil and rail guys. A big advantage of these sorts of drive systems would be it's simply less high profile than components to create or transport hydrogen gas than it is electronic components.

And above them, would be the realm of computer scientists and electricians, because now the order gets into rockets and guided self-propelled projectiles. Requiring the organization's resources and manpower, they still standardize fabrication units to make the exact specified digital computer components needed to create missiles with the topological data and inertial drives to tell exactly where they are on earth at any given moment of time, and where they should be. No more computing power than is necessary to go as far as a missile of their size with the fuel that offers the greatest possible range to chemical science and physics and get it from where it's fired to where it needs to be. They do not rely on satellites (though the option may exist), they hard insulate the self-propelled projectiles against radio interference, give them a very detailed map and send them on their way.

Sitting atop the heap are the engineers and electricians and computer scientists for fire control systems for everything from large kinetic weapons like naval guns and artillery, as well as the guys behind the computers and component standards for missiles. Not just components of other specialty weapon types, but their own group in the organization, given how essential a standard and the science is for the function of other weapon types. They bear the standards on the absolute minimum material components and methods for fabricating the ideally sized and powered pieces, be they electro-mechanical, or digital. As a rule, for things that are made to resist neglect and the rigors of time, electro-mechanical things are preferred. For power and control and performance, refined and perfected digital fire control systems are ideal. Cartographers, map makers, cosmologists, everything one would need for obscenely accurate missiles ranging from lipstick tube sized to ICBMs.

And from there we get to limited robotics and machines for mobility. Terrestrial, legged or wheeled, flying, swimming. Drones. Turrets. Things that allow movement. Considered its own subset skill, it's added last only because it encompasses everything that comes before, and applies to all. That includes rockets and jets.

And, really. That's kind of all she wrote. Well, he. 'Cause, I wrote it, and I'm a cisgendered dude. Once you get to the point you've reached the end of the tech tree for chemical propulsion bullets and how to be pinpoint dead on balls accurate down to a science, once you've acquired the knowledge and resources to do the same for artillery and triangulation to within millimeters even in adverse weather conditions, once you have the capacity to make and fire hypersonic missiles capable of taking off from the ground, going around the world at LEAST once to its origin point the long way and blowing up or entering orbit and staying up there until a scheduled time or parameters dictate to change trajectory, then, well.. you kind of have every method of long range weapon figured out.

Bows, longbows and crossbows? Yeah. But they're for especially oppressive times. The science and instructions on how to make bows and strings and arrows capable of being fired over 1,000 feet. Given how one doesn't need chemical propellants or potentially brow raising amounts of metals or smithery, they're a lesser science. May even be training wheels for would-be initiates.

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