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cartridgebuyerdubai · 6 months ago

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The Importance and Benefits of Ink Recycling

In the digital age where printing is an integral part of personal and professional lives, the issue of disposable ink cartridges has become a major environmental concern or issue. Moreover, Ink cartridges are a ubiquitous component in printing presses but pose a serious threat to living things when disposed of improperly. Ink recycling is emerging as an important solution to mitigate these risks, with environmental and economic benefits.

Environmental exposure of ink cartridges

Ink cartridges are made of plastic, which takes hundreds of years to degrade. In addition, these pipes often contain residual ink, which seeps into the soil and water system and causes contamination. Recycling takes a lot of natural resources and energy, contributing to the exhaustion of non-renewable resources and increased greenhouse gas emissions For these reasons, it is not like Ink recycling cartridges use is an approach that is not only environmentally responsible but also an important step towards better waste management system.

How Ink Recycling Works

Ink recycling involves storing, refining, and reusing used ink. Here is a brief summary of the event.

1. Collection: Used ink is collected from homes, offices, and recycling centers. Many printer manufacturers and print supply stores offer replenishment programs to facilitate this process.

2. Sorting and Cleaning: Sorting depends on the nature and condition of the inventory. It is then rinsed to remove any remaining ink and residue.

3. Refill Or Remanufacture: Depending on the condition of the cartridges, they can be refilled with new ink or disassembled and remanufactured. This process includes replacing worn parts and testing laboratory equipment to ensure it meets quality standards.

4. Packaging and redistribution: The refurbished product is then packaged and redistributed for sale as recycled ink cartridges. A reputed and authentic Old cartridge buyer can provide you with the best prices for the same.

Benefits of Ink Recycling

1. Environmental Protection: Recycling ink cartridges greatly reduces the amount of waste entering landfills. Recycling conserves natural resources and reduces pollution associated with the production of new products.

2. Energy Savings: The process of reusing and remanufacturing ink cartridges is energy efficient as compared to renewal. This decrease in energy consumption translates into a decrease in carbon emissions, helping to combat climate change.

3. Economic advantage: For consumers, buying a recycled ink cartridge can be more economical than buying a new one. In addition, the recycling industry creates jobs and stimulates economic growth by establishing collection and processing facilities.

4. Corporate Responsibility: For businesses, participating in ink recycling programs raises their Corporate Social Responsibility (CSR) profile. It means a commitment to sustainability and environmental initiatives, which can improve brand reputation and customer loyalty. However, it’s recommended to connect with an Old cartridge buyer to get the desired results.

Conclusion Ink recycling is a practical and effective way to solve the environmental challenges posed by discarded ink. By adopting recycling practices, we can conserve natural resources, reduce pollution, and contribute to a sustainable future. Whether through individual efforts or corporate initiatives, ink recycling is a simple but powerful step toward saving our planet.

#Ink recycling #Old cartridge buyer

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drifloonz · 2 years ago

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also istg im getting to that one glitchy request eventually bc other than smth im currently writing ( bc its a headcanon post which is a lot less effort ) thats like the Last thing i have on the docket until i get more stuff in. it has a draft in i'll Write more for that eventually. just gotta get back to getting into the flow of writing bc im way more of an roleplay type of person so im less familiar to Actually Writing Things

#wispy chatters #although i was very much proud of the other fic i wrote 4 glitchy.#maybe i should publish that one on ao3/watt/quotev one day but idk if i care thaaatt much.#i write fanfics via literally just typing whatever comes to mind ideawise and then trying to find a way to string the different events #that i impulse type together. its very frantic but its honestly a fun way of doing things #eg: i'll get a random Inspiration Flash in my mind of a specific scene or quote a character will say and ill immediately write it down #and think of how to connect it to the main plot later. yes this is why theres so many timeskips theyre like. little snapshots of the reader #life bc writing all the inbetweens would make it Way too long and Way too filler-esque #its also mostly trying to make it diff enough from the last glitchy fic(?) thingy #but i dont know if im gunna end up caring that much if its similar #i did just recycle the whole “reader gets him from a games store in the used section” though bc well #funnier than getting him thru ebay or smth #<- its also cuz i like to think you get him after their previous player did intentionally yk. sell him to a game store #bc they couldnt destroy the cartridge so they just had to make it someone elses issue LMAO

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andrewmadison90 · 2 years ago

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#toner recycling #toner cartridge recycling

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marcomoochala · 2 years ago

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Maximize Your Printing Potential with the HP PageWide XL Pro 5200

The ultimate solution, is for the fastest print machine in Singapore. http://www.uscsolns.com http://www.largeformatspecialist.com.sg If you’re looking for a large format printer that can help you respond quickly to customer demands and expand your business, the HP PageWide XL Pro 5200 is an excellent choice. With its impressive speed and versatility, this printer is capable of handling a wide…

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#Board printing #Cardstock printing #Energy-efficient printing #FSC-certified paper #HP Eco-Carton cartridge #HP Learn #HP PageWide technology #HP SmartStream #HP-branded solution #Large format printer #LED printer comparison #Printing efficiency #Printing speed #Printing versatility #Recyclable prints #Short-term retail posters #Water-based inks

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b1asho · 3 months ago

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Round one of the species introduction!!!!

Prectikar Master Post:

Here's some info on them, and if you want to see some other drawings I've done of them (albeit some occasionally older n crustier ones), check out my deviantart: https://www.deviantart.com/blasho

Anyway let's get into a terribly long string of paragraphs about some of their info:

Prectikar are a large sentient species, usually standing at around 8-9 feet tall when fully upright and weighing anywhere close to or upwards if 1000 pounds

They are covered in feather-like fur (or is it fur-like feathers? They're occasionally branched like feathers, and all have quills, but some are more hairlike) due to the cold climate they evolved in, though length and thickness of it now varies by region.

They are omnivorous, and while they have many traits to help them hunt and kill, most of their diet tends to be plants.

Originally rush-down predators, they use their considerable strength to move in quick bursts and their specialized tusks to either ram prey to death or gouge into it as they grapple it.

Their jaw strength is also insane,with their skull actually sacrificing brain space in favor of it, which helps them eat pretty much anything they come across. They pay a lot of attention to food and cooking because of their high calorie needs and very sensitive nose/tongue.

They have manganese as an oxygen carrier is a result of the scarcity of other metals in their environment and potentially because of its general affinity for oxygen.

This causes their blood to be an amber/orange brown and shades of pink depending on its exposure to oxygen.

Through a network of cooperative bonding and other adaptations (like better oxygen retention in muscles and the easily carried size and longevity of the molecule) they’ve managed to bring this manganese transport molecule close to hemoglobin in terms of effectiveness, though they can also make use of manganese’s catalyst properties to temporarily push it to bring lots more oxygen to their tissues at a time (used for short bursts of speed and strength that allow them to take down large prey and plants for food).

their large body size (selected by their colder environment) lets them use their own high body heat to keep the O2 fixation and liberation going in their highly effective lungs.

An extensive understanding of their internal chemistry is unknown (aka gatekept by their colonizers/"uplifters" who ill get to later) but it seems like they also have a network of bacteria in their body just to manage the more reactive and damaging oxides that form, and to remove/convert the spent manganese into connective tissue and aid in bone maintenance.

They have higher calorie needs from keeping up the body temp and recycling/removing all that stuff, alongside just being big in general. Alongside a lot of sleeping, they also basically just eat all the time (compared to other species) to compensate, though their mammal-like fat retention and other metabolic adaptations for scarcity mean that they can handle long periods without resources(though this causes increasingly compounded problems for them)

Some other downsides include low tolerance of changes in oxygen levels (particularly low) and temperature levels, and poor adaptation to environments outside of their biosphere/without all the microorganisms since these things upset their delicate balance.

(part of why so many tribes were nomadic was/is to chase temperate and ‘warm’ seasons, even though to us that’s still cold. Prectikar living in human dominated areas often just take a lot of supplements with beneficial bacteria in them to cope with thr lack of that in their environent, and any food printers need an 'ink' cartridge containing these things or else theyre basically useless.),

They also experience faster general wear and tear from having constant complex and intensive chemical reactions(sometimes with dangerous chemicals) going on in their bloodstream and tissues.

( I’m not a biochemist, so if there’s any glaring issues with this then just explain it away to yourself with ‘they have a gland for that’ or ‘just don’t think about it actually’ which is what I did. I just wanted the fun color with a metal that can reversibly bond with oxygen :). )

They have one nasal passageway for smell/air and a second, bigger cavity for just vocalization (which they can’t breathe in from as easily).

This second cavity is between their first set of eyes, and has a phonic lip structure inside to produce higher pitched sounds.

The upper nasal opening has muscled nostrils that act as lips to further help control sound. The noise coming from here sounds very high to them, but to us it sounds like a nasally human voice, broken uobhere and there with squeaks, buzzes, and clicks).

They can pitch this nose voice very high, closer to dolphin-like clicking noises but not quite echolocation level.

Their throat vocal cords by their air sac are very long and thick, used for making very deep noises that carry long distances.

However, the vocal control they have through their mouth is very poor due to this and the inarticulate lips and tongue they have, and due to the more limited air they can bring in and out of it, so when speaking only through their mouth they sound a lot like seals or dogs and can only really go in short bursts before having to refill the sac.

Most of their languages are spoken with the nose and mouth sounds in tandem, where the high and low mix to make a more even sounding voice.

It’s fairly easy to understand them, but nearly impossible for us to truly speak any of their native languages, and if they wanted to they could also just start making sounds we cant hear.

They see it as strange that humans and other species speak with a single tone without difficulty.

The red flaps pictured on the drawing of their mouth and nasal passages can be moved to seal off the passage and direct airflow elsewhere.

The big red one in their throat acts as a “diaphragm” to fill and empty the air sac (which is left over from when their digestive and respiratory tracts were more connected like ours, but time in the water heavily shifted it to a more ‘blowhole’ type outline to help them breathe and vocalize from the surface).

The other flap by the air sac and its vocal cords moves upwards to block off the digestive tract whenever the mouth or nose is opened to allow air to be drawn in by this diaphragm.

The two red flaps making a pinched shape can move independently or with the other red flap, but never at the same time with each other. The main airway is always separate from the digestive tract, though the flap to the middle, non vocal nasal passage can be moved so that it’s a part of either the vocal nasal passage to draw in air or the air sac part to act as another resonance chamber.

Air can be drawn in by the diaphragm via open mouth and through the nose via open top red flap at the same time, and can be released at the same time, resulting in their near continuous double speak sound they use for their own language.

Their characteristic large tusks are retractable and housed in a cone-shaped bony socket on the side of their jaw.

A muscle is attached to the bony root of the tooth, and pushes it out. As it slides towards the front of the mouth, the cone socket narrows and wedges a protrusion on the tooth into a hole in the socket, and then the muscle stiffens, locking it in there.

When the tusk retracts, the muscle quickly jimmies the tooth forward then draws it back to get it out of the hole, and then pulls it back into the wider part of the socket.

This is mainly because their tusks are ever growing (but very slowly) but not great at self sharpening, and are their main weapon in self defense and hunting,so it seems this just happened to keep them safe.

If a tusk is broken, as long as it was not cracked at the root, it can be regrown with extensive time in the socket, but otherwise they stay safely stowed in da socket where the majority of its sharp edge can stay protected from chewing and other mouth stuff. Tusks won't start growing in until their teenage years.

They are primarily bipedal/ quadrupedal and switch between the two occasionally.

Knuckle walking helps distribute their top-heavy weight and give them more balance for long and short distance, while walking upright gives them better visibility, less stress on their neck/upper back, and quicker but unsteadier movement.

Their gallop/sprint utilizes both arms and legs to propel them forward in a gait halfway between a bear and a gorilla (since their big mid arms are set like a bears) to overtake prey after an ambush or drive them into the rest of the pack waiting elsewhere. Quad walking also helps them get around in buildings meant for species half their size.

Their hands are some of their only places without hair, but as they age, they loose it on their arms and face too.

Prectikar have different uses for each of their pairs of limbs, and have for all stages of their evolution.

The front ones specialized for grappling prey and grabbing things, and so have a ‘sprawling’ shoulder position like humans and have hands with relatively nimble fingers, the outer two are angled inwards but can also move in a pamprodactyl ish fashion (which acts as their version of a thumb, and lets them switch from big to little grabbing motions) .

Their mid limbs used to be wings with hands, and still have a basically zygodactyl finger position that was helpful for holding onto branches (with the backwards facing finger), but over time they have been converted into terrestrial knuckle-walking limbs, with the one that swings back and forth being brought forwards to walk or swung back to adjust grip on big things they want to move or for balance on unstable terrain like ice . The fingers on this one are big and clumsy, pretty much only useful for digging, walking, or slashing.

Their back limbs also used to be for grasping but were mainly counterbalances, but have now turned into plantigrade walking limbs (and much like humans, that’s pretty much all they use them for). All have nonretractable claws.

Prectikar are viviparous and usually give birth to litters of up to 8.

They have a specific mating season, where their dimorphic traits will become more pronounced.

Males in rut will shed the feathers on their throat sac region and it will become a bright ambery yellow color, and they will also grow in longer feathers on their butt region (in a fan shape for display purposes. The dont have a true post anal tail like humans).

They will also develop some of that pinkish orange/yellow on their chest skin. Females go throguh estrus cycles and will also grow a more prominent butt feather crest, as well as some very long feathers around their neck, shoulders, and abdomen for babies to hold onto.

Their skin patches turn a much brighter shade of yellow to help direct newborns to where they can feed from. Once they give birth, they will start making an oily and thick secretion across the skin patch which is collected into a divot which the infant licks from. Part of why the babies hold onto them is so they can constantly lick the 'milk'so they can grow.

Newborns come out blind and hairless, but quickly grow in a thick down and open their eyes so they can climb on mom.

Once they're weaned, they'll drop off and use the muscles they gained hanging on and climbing to start moving with the adults. They grow very fast, and canes are a common sight in teens to help deal with the rapid bone and muscle growth.

Usually, it is only during this season where chest/skin related nudity standards change to be more conservative, since showing those colors means youre down to fuck and so doing that is usually restricted to in private with their partner or for bachelors.

They have very strict binaries for sex and gender based on this seasonal divide and religion.

Most tribes show gender identity through a piercing on their lower nose for male or chin for female (so dont worry, the main guy up there is showing some male presenting chest outside of the mating season, so hes fine).

Normally, only some cultures pierce their ears, which are like if owls had a little mobile flap of outer ear to swivel I stead of their whole head. Very little of it is actually flesh, and the sound is mainly captured by the feathers around it.

While they have a reputation otherwise, Prectikar are highly social within their tribal/family groups.

They regularly allogroom, greet each other with hugs, and usually travel in sibling groups. Households are multi generational.

They have a reputation as standoffish or irritable because they take things very differently and have other standards/specific body language truggers. also most other species treat them differently/with fear by default.

their upper pair of eyes is larger and focused on long distance vision while their lower pair is for close up vision, creatign a bifocal effect for them when using both at once.

Aaaaaand that oretty much everything, I think. I'll post some other arts related to them soon, but consider this the Master Post on the things you should know about them!!

#spec evo #worldbuilding #alien species #xenobiology #drawing #illustration #original species #prectikar #lore stuff

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mariacallous · 5 months ago

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A new report by environmental groups lays out a case for banning deep sea mining—and explains why the real solution to humanity’s energy crisis might just be sitting in the trash.

Deep sea mining is the pursuit of rare, valuable minerals that lie undisturbed upon the ocean floor—metals like nickel, cobalt, lithium, and rare earth elements. These so-called critical minerals are instrumental in the manufacture of everything from electric vehicle batteries and MRI machines to laptops and disposable vape cartridges—including, crucially, much of what’s needed to transition away from fossil fuels. Political leaders and the companies eager to dredge up critical minerals from the seafloor tend to focus on the feel-good, climate-friendly uses of the minerals, like EV batteries and solar panels. They’ll proclaim that the metals on the deep seafloor are an abundant resource that could help usher in a new golden age of renewable energy technology.

But deep sea mining has also been roundly criticized by environmentalists and scientists, who caution that the practice (which has not yet kicked off in earnest) could create a uniquely terrible environmental travesty and annihilate one of the most remote and least understood ecosystems on the planet.

There has been a wave of backlash from environmentalists, scientists, and even comedians like John Oliver, who devoted a recent segment of Last Week Tonight to lambasting deep sea mining. Some companies that use these materials in their products—Volvo, Volkswagen, BMW, and Rivian among them—have come out against deep sea mining and pledged not to use any metals that come from those abyssal operations. (Some prominent companies have done the exact opposite; last week, Tesla shareholders voted against a moratorium on using minerals sourced from deep sea mining.)

Even if you can wave away that ecological threat, mining the sea might simply be wholly unnecessary if the goal is to bring about a new era of global renewable energy. A new report, aptly titled “We Don’t Need Deep-Sea Mining,” aims to lay out why.

The report is a collaboration between the advocacy group US PIRG, Environment America Policy Center, and the nonprofit think tank Frontier Group. Nathan Proctor, senior director of the Campaign for the Right to Repair at PIRG and one of the authors of the new report, says the solution to sourcing these materials should be blindingly obvious. There are critical minerals all around us that don’t require diving deep into the sea. You’re probably holding some right now—they’re in nearly all our devices, including the billions of pounds of them sitting in the dump.

The secret to saving the deep sea, Proctor says, is to prioritize systems that focus on the materials we already have—establishing right to repair laws, improving recycling capabilities, and rethinking how we use tech after the end of its useful life cycle. These are all systems we have in place now that don’t require tearing up new lands thousands of feet below the ocean.

“We don't need to mine the deep sea,” Proctor reiterates. “It's about the dumbest way to get these materials. There's way better ways to address the needs for those metals like cobalt, nickel, copper, and the rest.”

Into the Abyss

Schemes for delving into the deep ocean have been on the boards for years. While the practice is not currently underway, mining companies are getting ready to dive in as soon as they can.

In January 2024, the Norwegian Parliament opened up its waters to companies looking to mine resources. The Metals Company is a Canadian mining operation that has been at the forefront of attempts to mine in the Pacific Ocean’s Clarion-Clipperton Zone (CCZ)—an area of seabed that spans 3,100 miles between Mexico and Hawaii.

The proposed mining in the CCZ has gotten the most attention lately because the Metals Company secured rights to access key areas of the CCZ for mining in 2022, and its efforts are ramping up. The process involves gathering critical minerals from small rock-like formations called polymetallic nodules. Billions of these nodules rest along the seabed, seemingly sitting there ripe for the taking (if you can get down to them). The plan—one put forth by several mining companies, anyway—is to scrape the ocean floor with deep sea trawling systems and bring these nodules to the surface, where they can be broken down to extract the shiny special metals inside. Environmentalists say this poses a host of ecological problems for everything that lives in the vicinity.

Gerard Barron, the CEO of the Metals Company, contends that his efforts are misunderstood by activists and the media (especially, say, John Oliver).

“We're committed to circularity,” Barron says. “We have to drive towards circularity. We have to stop extracting from our planet. But the question is, how can you recycle what you don’t have?”

Both Barron and the authors of the activist report acknowledge that there aren’t perfect means of resource extraction anywhere—and there’s always going to be some environmental toll. Barron argues that it is better for this toll to play out in one of the most remote parts of the ocean.

“No matter what, you will be disrupting an ecosystem,” says Kelsey Lamp, ocean campaign director with the Environment America Research and Policy Center and an author of the report. “This is an ecosystem that evolved over millions of years without light, without human noise, and with incredibly clear water. If you disrupt it, the likelihood of it coming back is pretty low.”

For many of the life-forms down in the great deep, the nodules are the ecosystem. Removing the nodules from the seabed would remove all the life attached to them.

“This is a very disruptive process with ecosystems that may never recover,” says Tony Dutzik, associate director and senior policy analyst at the nonprofit think tank Frontier Group and another author of the report. “This is a great wilderness that is linked to the health of the ocean at large and that has wonders that we’re barely even beginning to recognize what they are.”

Barron counters that the life in the abyssal zone is less abundant than in an ecosystem like rainforests in Indonesia, where a great deal of nickel mines operate—although scientists discovered 5,000 new species in the CCZ in 2023 alone. He considers that the lesser of two evils.

“At the end of the day, it's not that easy,” You can't just say no to something. If you say no to this, you're saying yes to something else.”

The Circular Economy

Barron and others make the case that this ecosystem disruption is the only way to access the minerals needed to fuel the clean-tech revolution, and is therefore worth the cost in the long run. But Proctor and the others behind the report aren't convinced. They say that without fully investing in a circular economy that thinks more carefully about the resources we use, we will continue to burn through the minerals needed for renewable tech the same way we've burned through fossil fuels.

“I just had this initial reaction when I heard about deep sea mining,” Proctor says. “Like, ‘Oh, really? You want to strip mine the ocean floor to build electronic devices that manufacturers say we should all throw away?’”

While mining companies may wax poetic about using critical minerals for building clean tech, there's no guarantee that's where the minerals will actually wind up. They are also commonly used in much more consumer-facing devices, like phones, laptops, headphones, and those aforementioned disposable vape cartridges. Many of these devices are not designed to be long lasting, or repairable. In many cases, big companies like Apple and Microsoft have actively lobbied to make repairing their devices more difficult, all but guaranteeing more of them will end up in the landfill.

“I spend every day throwing my hands up in frustration by just how much disposable, unfixable, ridiculous electronics are being shoveled on people with active measures to prevent them from being able to reuse them,” Proctor says. “If these are really critical materials, why are they ending up in stuff that we're told is instantly trash?”

The report aims to position critical minerals in products and e-waste as an “abundant domestic resource.” The way to tap into that is to recommit to the old mantra of reduce, reuse, recycle—with a couple of additions. The report adds the concept of repairing and reimagining products to the list, calling them the five Rs. It calls for making active efforts to extend product lifetimes and invest in “second life” opportunities for tech like solar panels and battery recycling that have reached the end of their useful lifespan. (EV batteries used to be difficult to recycle, but more cutting-edge battery materials can often work just as well as new ones, if you recycle them right.)

Treasures in the Trash

The problem is thinking of these deep sea rocks in the same framework of fossil fuels. What may seem like an abundant resource now is going to feel much more finite later.

“There is a little bit of the irony, right, that we think it's easier to go out and mine and potentially destroy one of the most mysterious remote wildernesses left on this planet just to get more of the metals we're throwing in the trash every day,” Lamp says.

And in the trash is where the resources remain. Electronics manufacturing is growing five times faster than e-waste recycling, so without investment to disassemble those products for their critical bits, all the metals will go to waste. Like deep sea mining, the infrastructure needed to make this a worthwhile path forward will be tremendous, but committing to it means sourcing critical minerals from places nearby, and reducing some waste in the process.

Barron says he isn't convinced these efforts will be enough. “We need to do all of that,” Barron says, “You know, it's not one or the other. We have to do all of that, but what we have to do is slow down destroying those tropical rainforests.” He adds, “If you take a vote against ocean metals, it is a vote for something else. And that something else is what we’ve got right now.”

Proctor argues that commonsense measures, implemented broadly and forcefully across society to further the goal of creating a circular economy, including energy transition minerals, will ultimately reduce the need for all forms of extraction, including land and deep-sea mining.

“We built this system that knows how to do one thing, which is take stuff out of the earth, put it into products and sell them, and then plug our ears and forget that they exist,” Proctor says. “That’s not the reality we live in. The sooner that we can disentangle that kind of paradigm from the way we think about consumption and industrial policy the better, because we're going to kill everybody with that kind of thinking.”

Just like mining the deep sea, investing in a circular economy is not going to be an easy task. There is an allure of deep sea mining when it is presented as a one-stop shop for all the materials needed for the great energy transition. But as the authors of the report contend, the idea of exploiting a vast deposit of resources is the same relationship society has had with fossil fuels—they’re seemingly abundant resources ripe for the picking, but also they are ultimately finite.

“If we treat these things as disposable, as we have, we’re going to need to continually refill that bucket,” Dutzik says. “If we can build an economy in which we’re getting the most out of every bit of what we mine, reusing things when we can, and then recycling the material at the end of their lives, we can get off of that infinite extraction treadmill that we’ve been on for a really long time.”

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sometipsygnostalgic · 2 months ago

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The best system to play Gameboy games on is... well... you can play them on many devices.

Officially it would be GBA SP because it can run Gameboy and GB Colour games.

However, very few backlit SPs were ever released (they are frontlit). So a better unit for Gameboy Advance games might be the DS Lite, which universally is backlit and which is lightweight enough to not cause problems. It also has better ergonomics than the SP, but I am bugged by the black borders and empty second screen.

A really popular mod is called the "Gameboy Macro", which is when you take a DS Lite lower screen and use it solely as a gameboy advance. It is a great way to recycle DS units with a broken top screen, a common issue, though it makes me cringe to think some people modify perfectly fine units this way.

The Lite also has issues with the cartridge sticking out the bottom, so many prefer using the "phat" for this purpose. The original DS is both frontlit and backlit for some reason. The image is still an improvement on frontlit SPs.

The best units to play DS and 3DS games on are... the DS and 3DS.

Specifically the best place for NDS games is the DSi XL. No non-DS device has the touchscreen versatility to run DS games well, and it's very awkward scaling the tiny screen on an emulator.

The 3DS is also not a great place for DS games. The 3DS top parallax screen is incapable of a 1:1 pixel ratio even in pixel-perfect mode, which already has the issue of black borders around the screens, making touch-based games more finicky.

It is especially apparent on the XL models but is also an issue on the smaller 3ds models.

The best unit to play DS games on is the DSi XL. It has a backlit screen and more power and memory than the first two units, making loading faster. It doesn't have the scaling issues of the 3ds, as it doesn't need to do any upscaling at all - the XL has the same number of pixels as a normal DS.

I've never used a DSi XL because all the ones sold in the UK are these ugly beige colours and they never took off, but if you don't mind the loss of the GBA slot, it's the best device for DS games.

Unfortunately DSis seem to be plagued by yellowing screens. I can tell you the small unit I just bought has some very slight yellowing on both screens.

What's the best way to play 3ds games? Well, on a 3ds obviously. It's even harder to accurately emulate 3ds games than DS games, and you lose the 3d effects altogether.

But which 3ds is best?

It depends on what you want. The 3ds more than any other Nintendo system besides the Gameboy is heavily based on preference instead of objective superiority.

To get it out the way first, while the original 3ds has the sleekest look, it's the worst one. The original 3ds and 3dsXL have a much worse 3D implementation, relying on you to stare at the screen at an odd angle.

Not only does the New3ds fix the 3d with an eye tracking sensor, it also has more power again, and a "c-stick". I also think the screens on the New3ds are of a higher quality and run flat games better too.

However the New3dsXL has some downgrades. The SD card is replaced with a microSD but now requires a mini screwdriver to access, removing the back plate. The stylus is also a really tiny one like on the DS, in an awkward place, and the metallic skin on the console will decay very quickly with use. My New3DSXL's skin started peeling under my hands after just six months of use.

The New3DSXL is the best unit to play 3ds games if you are looking to have all the features at their most optimal. It is the best by far for playing in 3d. It can also run the DS library fine, if in a poor image quality.

Personally I prefer the XL, the larger size is easier on the eyes, though the customizable panels on the hard-to-find normal size New3ds are cute too.

If you don't care for 3d, the Wedge and Doorstop may be for you.

The 2ds has all the features of a 3ds apart from the 3d, while in a wedge shape that looks dreadful but actually feels more ergonomic. It has similarities to the first Gameboy Advance and you can't tell you're holding something so tall.

The original 2DS is sold for much cheaper than the other units because Nintendo sold it for cheaper and nobody particularly wants one, so it's the most affordable way to try every game in the DS library, especially if you pair it with a jailbroken SD card. Unfortunately it still uses the 3ds screen, just with no 3d slider, so it still upscales DS games and doesn't have perfect rendering of 3ds games either, but it's harder to tell as the screen's tiny.

The New 2ds XL was the last DS ever sold, it came out after Switch. A lot of cute variants of the 2ds XL exist, and most games coming out around its release didn't have 3d enabled anyway. The feature had died in popularity, so while a 2d 3ds was originally scoffed at, in 2017 it just made sense.

While the New2ds XL looks fancy in a distance, the ergonomics are worse than any 3ds, and far worse than the wedge 2ds. The New2dsXL is all style and no substance, with the speakers being covered by the user's hands, and it's made out of a flimsy plastic. It's clear Nintendo made the materials for the hull cheaper and cheaper over time, so by the end of the 3ds's life they had gone from a very premium-feeling device to cheap plastic. The Switch would follow this design philosophy.

I do salivate over that Pikachu version and I'd enjoy trying one, but my mind tells me it's not a great device.

All told, which do I think is better? Well I think the 3ds XL having the most features is inviting for me, and I have the choice of turning off 3D. However if you want bang for your buck, the 2ds wedge might be your safest option.

Unfortunately the New 2ds XL and New 3ds XL will cost you as much as a Nintendo Switch these days. It seems that sellers have wisened up to the demand from people who missed out on the 3ds and want to try it out. There's also talk of IPS screens being better and the New2ds XL, 3ds XL and DSi XL all use IPS screens, so people are scalping them or raising prices.

#nintendo #nintendo ds

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