The number of coffee chains spread around the world is undeniable proof of how much people desire or even thrive on the beverage. Unfortunately, that number is also an indirect testament to the waste that the industry produces, especially when it comes to to-go cups. The majority of these cups are made of plastic, though some brands and consumers are becoming wiser and opting for more sustainable drinkware. The problem, however, is when you need to carry more than one of these cups, usually in precarious trays or bags. A paper cup design concept tries to hit two birds with one stone, offering not only a more sustainable cup but a better way to hold and carry them.

Designer: Shenzhen Samore Design & Research

Although iced coffee to go is still usually served in plastic containers, unless you bring your own reusable cup, the more common hot beverage is thankfully put in paper cups with cardboard sleeves. Their designs are simple and handy for holding in one hand, but some people have the unfortunate task of buying for a group. Some stores offer cardboard trays or boxes for carrying two or four drinks at once, though some have to resort to bags that could let the coffee spill as you swing it while walking.

Neither are ideal solutions, especially for long-term use or reusable cups, so someone thankfully thought of a better and admittedly more aesthetic solution to this common problem. It doesn’t have a formal name yet, but the Accordion Paper Cup design offers a simple yet ingenious way not just to carry coffee paper cups but also to hold one in your hand. In a nutshell, the paper cup has a sleeve that expands upward, turning it into a bag of sorts.

The trick to this sleeve design is the accordion-like structure can easily expand and contract without changing its total mass. This same structure happens to also be a good insulator against heat, allowing you to wrap your hand around a hot cup. It might not be an intentional part of the design, but the alternating pattern of holes and divisions also makes it easier to grip an otherwise smooth and slippery cup.

The paper cup and its innovative sleeve are allegedly made of recyclable, renewable, and biodegradable materials, further driving home the idea of an all-in-one sustainable solution for to-go cups. But while the cup itself seems to have that brown hue typically associated with recycled paper products, the sleeve has a gradient that softly shifts from blue to brown, though other colors are also possible. Unfortunately, there is no word on whether this concept has any chance of becoming an actual product, but it’s definitely an interesting avenue to consider for large coffee chains.

The post Accordion paper cup concept makes carrying coffee easier and more sustainable first appeared on Yanko Design.

The world is filled with many things that have the potential to become materials for creating products, and yet we still prefer typical materials like plastics, metal, or wood. Not all of these are sustainable, and those that are sustainable aren’t always easily renewable or require a lot of energy to process or recycle. Admittedly, looking for alternative sources of materials isn’t an easy task, but once in a while, we come across a promising solution both in terms of sustainability and beauty. This rope light and Ikebana vase, for example, are already quite striking in their unique shapes, but they are made even more significant by the fact that they are made using a biodegradable material based on one of the most common and simplest kind of plant on the planet: algae.

Designer: Su Yang Choi

One of the problems with supposedly more sustainable or recyclable materials is that the process of making or treating them isn’t always sustainable, requiring more energy and water than usual. In contrast, this algae-based material isn’t treated with harmful chemicals, has reduced energy consumption during manufacturing, and can easily be shaped using heat. Even better, leftover scraps from the production process can be collected and recycled to reduce material waste at every step.

While the material itself is quite impressive, putting it to good use is the real test. For this purpose, a pair of everyday objects were made not just to demonstrate the usability of this algae-based material but also to show off the complicated designs that can be made with it. And nothing can perhaps be more complicated than knots, especially the beautiful traditional Korean knots known as Maedeup.

This knotting is best exemplified in this Ikebana vase that loops around itself a couple of times in an almost random fashion, symbolizing the unpredictability and cyclical nature of life. In addition to this rather intriguing structure, the biodegradable material used here is mixed with coffee grounds, another sustainable material, to give it that earthy brown color.

On the opposite end of the color spectrum is a long string lamp that uses the algae-based material in a four-faced linear braid that wraps around a flexible LED strip. This segmented structure was inspired by Korean stone pagodas that rise in majesty and grandeur, characteristics carried by this string lamp. These two objects, part of the Slow series of artworks, embody the ingenuity and creativity that spring from combining modern material science and traditional craftsmanship to produce breathtaking designs that do no harm to the planet in return.

The post Algae-based material and traditional Korean braiding turn into striking lights, vases first appeared on Yanko Design.

Since introducing the concept for an energy-generating wall in 2021, designer Joe Doucet has been tirelessly working to turn this innovative idea into reality. Now, with the launch of Airiva, a modular rotary wind turbine wall designed for urban installations, this vision is closer than ever to being realized. Airiva promises to revolutionize how cities and infrastructures harness wind energy, bringing sustainable power generation directly to the places where people live and work.

Designer: Joe Daucet

Wind energy has been instrumental in reducing global dependence on fossil fuels. However, the adoption of wind turbines for residential and commercial use has been slow, largely due to their intrusive designs. Airiva addresses this challenge by combining functionality with aesthetic appeal.

The wind turbine wall is composed of multiple rotary blades that spin independently, driving a generator to produce clean, renewable electricity. This modular and scalable solution is tailored for urban and suburban environments, allowing it to augment or coexist with other power generation methods. The electricity generated can be used on-site, stored, or fed back into the grid. The system is not only efficient but also quiet and safe, making it suitable for a wide range of environments. Potential installation sites include municipal and public facilities, commercial buildings, transportation networks, and coastal areas, among others.

Airiva places a strong emphasis on sustainability. The manufacturing process aims to use at least 80% post-consumer and recycled materials, aligning with circular economy principles and minimizing environmental impact. This commitment to sustainability is a fundamental aspect of Airiva’s design and manufacturing strategy.

One of Airiva’s key strengths is its flexibility. The system’s modular design allows it to be easily transported and scaled to meet specific site requirements. Multiple units can be networked together, creating a flexible, clean energy system that can adapt to various use cases. Additionally, Airiva is designed to complement other distributed energy technologies, providing a versatile alternative that can enhance existing installations.

Airiva’s smart technology enables remote monitoring of system and site information, offering visibility and control over geographically dispersed installations. Each unit consists of two segments, each measuring 2100mm in length and height and 1050mm in depth, along with an end hub unit for controls, communications, and power management. This design facilitates global transport and distribution, ensuring that the system can be deployed wherever it is needed.

The initial idea in 2021 envisioned a wall of 25 vertical-axis turbines with a total peak power output of 10 kilowatts. While the intermittent nature of wind means that actual energy production can vary, the refined Airiva system is expected to produce approximately 2,200 kWh annually per unit. While this may not cover the entire energy needs of an average home, it can significantly reduce energy bills. Larger installations, such as those on commercial campuses or transportation hubs, can harness more power, demonstrating the system’s scalability.

Currently in the prototyping stage, Airiva plans to begin customer pilots in the latter half of this year, with orders expected to open in 2025. Although specific figures have yet to be disclosed, Airiva’s targeted Levelized Cost of Energy (LCOE) aims to be competitive both domestically and internationally against other small-scale distributed energy resources. Upcoming pilots will be crucial in validating these claims and demonstrating the system’s effectiveness in real-world conditions.

The post Airiva: Modular Rotary Turbine Walls Revolutionize Urban Wind Energy first appeared on Yanko Design.

Located in Heidelberg, the Wave House is designed to be a new data center in the urban heart of Germany. Designed by SSV and Mense Korte, and built by Peri 3D Construction for the developer KrausGruppe, the Wave House was 3D-printed, adding an element of style and personality to the rather mundane arena of cloud-computing infrastructure. The end result is Europe’s largest 3D-printed building! The building measures 6600 sq ft and has a rather unique appearance, in an attempt to draw attention and make it unlike the typical 3D-printed structures we come across.

Designer: SSV, Mense Korte & Peri 3D Construction

“Due to the typical absence of windows and large openings in all or the main areas of data centers, for safety and other reasons, data centers tend to look quite dull and uninspiring,” said a press release by COBOD. “As long as such data centers are placed far outside the cities this problem is perhaps of less concern, but the trend towards making data centers more in the vicinity of the users and therefore locate them in suburban areas and cities has created a need to make the data centers more visually appealing.

This issue was resolved by imparting the walls with an innovative wave design, which also lends the building its name. The fascinating waves could not have been built using traditional construction methods, hence 3D-printed technology was adopted, to support creative and design freedom while producing the walls.

The construction process of the Wave House is similar to other 3D-printed projects we’ve come across. It was printed using a single COBOD BOD2 printer, the same model that has been utilized to build other 3D-printed buildings of importance. The printer extrudes a recyclable cement-like mixture in layers via a nozzle. This is done at a rate of 43 sq ft per hour to create the exterior walls which have a length of 177 ft, a width of 35 ft, and a height of 29.5 ft.

The entire printing process involved around 140 hours, after which, finishing touches were added to the project by humans. These touches include the doors, roof, lighting, as well as the wiring and gear needed for a data center well-connected to the internet. A robotic painter by Deutsche Amphibolin-Werke was utilized to paint the interiors of the building. How cool!

The post Wave-Shaped Data Center Is Europe’s Biggest 3D-Printed Building Constructed In Only 140 Hours first appeared on Yanko Design.

It has only been a month since Microsoft unveiled its latest Surface-branded computers, and while the tech industry was awash with discussions on the company’s aggressive Copilot AI push and ARM-based Snapdragon X silicon, the products’ design may have left some people less than impressed. The Surface Pro 11 and Surface Laptop, for all intents and purposes, look exactly like their forebears, making one wonder if Microsoft has run out of creative juice or is desperate to milk its current design until it runs dry. Fortunately, that isn’t the end of the new Microsoft Story, as it turns out that the latest Surface Pro and Surface Laptop computers have one “invisible” upgrade it didn’t really talk about much: an easier repair process that has even the meticulous and stingy iFixit impressed.

Designer: Microsoft (via iFixit)

Laptops have come a long way from being impregnable fortresses that made even the smallest repairs or upgrades a hellish experience, though there are still some companies living the past in the present. Initially, the Surface Laptop was part of that group, requiring cutting through fancy Alcantara fabric just to open the laptop to replace a battery or upgrade the storage. This year’s design almost makes a complete U-turn with a bottom plate that’s only held down by four screws and magnets; no adhesive in sight. Even the battery can be easily removed by just removing screws and a few layers of parts blocking those.

Tablets are even worse news for repairs, especially with displays that are glued on top of the frame. To its credit, Microsoft has at least made changing the Surface Pro M.2 SSD painless by having an accessible magnet-locked panel to get to that storage instantly. The 11th-gen model takes things further by employing as little adhesive as possible, though you still have to go through the risky process of removing the screen first. Fortunately, getting to important parts like the battery is less of a grueling task, especially since it’s only held down by screws as well.

Even more impressive, however, is the fact that Microsoft officially supports such self-repair processes. It has made repair guides publicly available since day one and has even clearly marked out the number and types of screws that hold certain components in place. It’s far from perfect and definitely not on the same level as a Framework laptop, but it’s still an unexpected yet pleasant surprise, especially considering it’s Microsoft we’re talking about.

The post Microsoft Surface Pro 11, Surface Laptop 7 repairability gets thumbs up from iFixit first appeared on Yanko Design.

At the prestigious Salone Del Milano 2023 in Milan, Italy, the design lab HONOKA showcased their innovative TATAMI ReFAB PROJECT furniture series. This project, conceived by a team of forward-thinking product designers, leverages advanced manufacturing techniques like 3D printing to breathe new life into traditional Japanese tatami mats. The result is a fusion of heritage and cutting-edge technology that reintroduces the essence of tatami into contemporary living spaces.

Designer: HONOKA LAB

Tatami mats have been a staple of Japanese interiors for centuries, renowned for their aromatic qualities, humidity regulation, and odor reduction capabilities. HONOKA’s project aims to integrate these traditional benefits into modern furniture design. By blending recycled tatami with biodegradable plastic, they have created a sustainable material that is both adaptable and durable. This innovative composite can be 3D printed into a variety of functional and decorative home products, embodying the future of artisanal design while retaining a distinct connection to Japanese culture.

One of the key highlights of this project is its commitment to sustainability. Traditional tatami production often results in significant material waste, with nearly half of the plant-based material discarded. Honoka addresses this issue by recycling tatami waste and combining it with biodegradable plastic, significantly reducing the environmental impact. This material is not only eco-friendly but also versatile, allowing designers to explore new aesthetic possibilities and create unique forms that enhance modern living spaces.

The collection features several distinctive pieces that exemplify the versatility and beauty of the tatami-resin composite:

SORI and MUKURI:

These knitted tatami-resin furniture pieces reinterpret traditional Japanese shapes and textures through 3D printing. The unique structure of these items offers moderate transparency and varying visual expressions depending on the viewing angle. They are sturdy enough to support glass and other heavy materials, making them ideal for dining tables.

CHIGUSA:

Inspired by the traditional Japanese “Sen-suji” pattern, this stool combines multiple 3D-printed parts. The vertical pattern of the elastic and durable tatami-mixed resin provides a resilient and comfortable seating experience.

TABA:

A lighting fixture designed to resemble bundled grass, TABA uses a dripping technique in its 3D printing process. The tatami-mixed resin diffuses light beautifully, with light spilling through the gaps in its branches, creating a soft, natural ambiance.

TACHIWAKI:

This self-standing basin, inspired by the Japanese “Tachiwaki” pattern, features multiple stripes created by varying the purging speed of the 3D printer. Its water-resistant nature makes it suitable for innovative bathroom designs.

YOCELL:

A stool that draws from the traditional Japanese “Asanoha” pattern, it uses the layer marks of the 3D printer to create unique visual effects by aligning them in different directions. The modular shape makes it sustainable even for transportation and packaging.

AMI:

Combining the aesthetics of traditional Japanese 2D weaving with modern 3D printing, the AMI stool and lampshade feature intricate designs created by dripping resin from the air. The resulting pieces change their expression based on the viewing angle.

KOHSHI:

This lattice-like vase is reminiscent of Japanese architecture and allows for flexible plant arrangements, inspired by the art of Ikebana. This design has such a lightweight aesthetic, making any room feel airy. It’s perfect for minimalistic homes.

The post The TATAMI ReFAB PROJECT Is A Product Of Fusing Japanese Traditions With 3D-Printed Sustainability first appeared on Yanko Design.

Ant Studio’s Beehive is a pioneering solution that marries traditional cooling techniques with modern design to offer an eco-friendly alternative to energy-intensive cooling and air purification systems. Created by Monish Kumar Siripurapu, a New Delhi-based architect and founder of Ant Studio, the Beehive system exemplifies the firm’s commitment to integrating art, architecture, technology, and nature. As the country sees soaring temperatures this summer, with New Delhi recording temperatures as high as the 50s Celcius (over 122°F), the Beehive is offering a low-cost tradition-backed cooling system that uses properties of materials and physics to help provide cooler temperatures without electricity or coolants.

Designer: Ant Studio

The Beehive system operates on the principle of evaporative cooling, a technique that has been utilized for centuries. The system employs earthenware pots, which are soaked with water to create a cooling effect as the water evaporates. This natural process is enhanced by the formation of biofilm on the pots, which aids in air purification. The Beehive’s modular design is not only zero-plastic and zero-emission but also aesthetically pleasing, making it an ideal solution for outdoor working conditions in urban environments.

Earthen pots have long been recognized for their cooling properties. Egyptians fanned the porous jar of water to get cool air. The Romans on a similar concept, hung wet thick material on the doors of their houses or tents. Others, who were wealthy, constructed an artificial channel conveying water along the walls of their houses to reduce the temperature under extreme hot weather. These ideas from the past were analyzed and later assimilated and are now being adapted to contemporary needs, demonstrating the enduring value and sustainability of traditional practices. The Beehive project embodies this philosophy, merging the cultural and environmental benefits of traditional methods with modern design and technology.

What sets the Beehive apart is its zero-plastic and zero-emission design. The use of earthen pots is deeply rooted in Indian culture, where such pots have been used for centuries to keep water cool, making the craft easily available and recognized in India. This ancient wisdom is ingeniously adapted into a contemporary design that is both sustainable and aesthetically pleasing. The Beehive demonstrates how age-old techniques can be revitalized to address modern environmental challenges.

In addition to its environmental benefits, the Beehive project aims to revive the dying craft of pottery. By engaging local artisans to construct the terracotta cones, Ant Studio is generating employment opportunities and supporting traditional craftsmanship. This approach not only ensures the creation of high-quality components for the Beehive system but also contributes to the preservation of cultural heritage and the economic well-being of local communities.

One notable application of the Beehive was at the Deki Electronics factory in Noida. The factory faced extreme heat generated by a generator set at its entrance, which posed health risks and reduced productivity for the workers. Ant Studio’s Beehive system provided an economical and effective solution to this problem. The system’s ability to significantly lower temperatures using evaporative cooling proved beneficial in making the working environment more bearable and safe.

While the beehive pattern is an efficient and aesthetically pleasing design, it is important to consider that some people may experience discomfort due to trypophobia, a fear of clusters of small holes. To make the system more inclusive, Ant Studio could explore alternative forms and patterns that provide the same cooling efficiency without triggering trypophobia. This could involve experimenting with different geometric designs or arrangements of the terracotta pots that maintain functional benefits while catering to a wider audience.

The Beehive air-cooling system has garnered international recognition, winning the Asia-Pacific Low-Carbon Lifestyles Challenge and a $10,000 grant from the UN Environment. This accolade underscores the system’s potential to revolutionize cooling solutions globally. Ant Studio has successfully installed Beehive in 20 different locations, including factories and new builds. Despite challenges in standardizing the manufacturing process, which relies on local potters and craftsmen, the startup continues to inspire both artists and energy pioneers in India.

Siripurapu envisions a future where personal cooling systems like Beehive could transform the cooling industry. Instead of cooling entire rooms, these systems could focus on cooling the air around individuals, drastically reducing energy consumption. The Beehive system not only addresses immediate cooling needs but also supports the revival of traditional pottery crafts, generating employment and preserving cultural heritage.

Ant Studio Team

The post Honeycomb-inspired Terracotta Wall can cool houses without any chemicals or electricity first appeared on Yanko Design.

Sustainable gardens aim to reduce human impact on the planet by conserving natural resources and minimizing waste. Embracing these practices can contribute to a happier, healthier Earth. As one engages in activities like potting, pruning, and maintaining green space, one should contemplate adopting more eco-friendly gardening habits, as sustainable gardening is more achievable than one might imagine.

Image courtesy of: puhimec

Why is Sustainable Gardening important?

Amid a global green revolution, sustainable gardening plays a crucial role in minimizing pollution and chemical risks associated with various activities, particularly food production. By embracing sustainable gardening practices, one not only contributes to environmental protection but also safeguards health from potential chemical hazards. The shift towards ‘sustainable gardening’ not only diminishes our carbon footprint but also encourages healthier eating habits. The fruits and vegetables cultivated at home are devoid of pesticides and other preservatives typically employed in mass production, thus preventing harmful chemicals from entering your body and maintaining environmental well-being.

Image courtesy of: DisobeyArtPh

Planting a sustainable garden with native and local species prevents the spread of invasive weeds into natural areas, reducing the need for chemical pesticides and herbicides. Aditionally, sustainable gardens play a crucial role in preventing water pollution by recognizing the significance of water as a valuable resource. Unlike traditional gardening practices, sustainable gardening avoids the use of additives that could contaminate the water supply. Here are ten ways to make your garden more sustainable:

1. Go Organic

The initial action involves transitioning to organic methods and minimizing chemical usage in your garden. Begin by ensuring high-quality soil abundant in nutrients through the addition of natural compost. If the plants are affected by insect pests or plant diseases, it is important to address them using organic remedies.

Image courtesy of: VroniV

2. Add Mulch

An effective method to prevent weed growth involves mulching, which not only retains soil moisture but is especially advisable in regions with water limitations or scarcity. This can be achieved by applying a 2 to 3-inch layer of mulch around landscape plants, utilizing materials such as shredded bark, grass clippings, or coir derived from coconut hulls.

3. Go for Native Plants

In sustainable gardens, it’s advisable to include native plants that are well-suited to the region. These plants demand less maintenance, utilize less water, and flourish more effectively than perennials, because of their natural adaptation to the local climate, rainfall, and soil conditions. It’s important to note that a perennial plant, commonly known as perennials, persists for more than two years. Additionally, native plants offer the benefit of attracting indigenous insect and bird species to the area.

4. Say Yes To Composting

Image courtesy of: YuriArcursPeopleimages

Embracing composting stands out as a top practice for cultivating a sustainable garden. By composting your green waste, such as grass clippings, deadheaded flowers, dried leaves, and kitchen scraps, one can transform it into a nutrient-rich fertilizer, fostering sustainability in gardening endeavors.

5. Reuse Plastic Pots

Image courtesy of: pernilla11

Certain plants are sold in plastic pots. Instead of purchasing new ones, consider reusing pots for seed sowing and repotting. Simply rinse them with warm water and detergent before reuse to eliminate any potential diseases or one can return them to the nursery for reuse.

6. Conserve water

Image courtesy of: halfpoint

Maintaining vibrant gardens in summer often entails frequent watering. To minimize your garden’s reliance on mains water during hot, dry spells, consider installing a water butt and incorporating ground cover plants to lessen moisture evaporation and cool the soil.

7. Grow Wildlife Friendly Plants

Image courtesy of: Mint_Images

Opt for pollinator-friendly plants with uncomplicated flower structures, making it easier for insects like bees and butterflies to access food. Aim for a variety of plants that bloom at different times or have extended flowering seasons to ensure a continuous food source for pollinators throughout the year.

8. Invest in Sustainable and Durable Pots

Image courtesy of: Beachbumledford

Opt for sustainable pots and planters to minimize single-use plastics in your garden. It is important to take care of your existing plastic pots and trays for reuse or invest in durable materials like pots made from 100% recycled waste, addressing plastic waste beyond gardening. Bamboo pots and seed trays offer longevity, lasting up to five years, and can be composted at the end of their life cycle. Consider the Hemp Planters Range for greenhouse or terrace use, offering both sustainability and maximizing crop yields.

9. Minimize Use of Fertilizer

Image courtesy of: YuriArcursPeopleimages

Prioritize minimizing fertilizer use in sustainable gardening practices to prevent runoff and excessive plant growth. Start by testing your soil to understand its natural fertility and determine if any adjustments are needed; many soils can sustain plant growth without added fertilizer. Consider enriching your soil with homemade compost as an alternative to synthetic fertilizers, promoting soil health and reducing environmental impact.

10. Use Less Energy

Image courtesy of: valeriygoncharukphoto

Reduce outdoor energy consumption by focusing on lawn care practices. Opt for electric or push-reel mowers and keep blades sharp for efficiency. Prioritize manual weed removal to prevent spread before mowing. Decrease lawn size by planting trees or expanding gardens. Choose solar-powered LED bulbs for lighting to conserve energy and provide natural illumination.

How does a sustainable garden combat climate change?

Home gardeners contribute significantly to addressing climate change through sustainable practices. By employing sustainable gardening and landscaping techniques, they can mitigate future warming by reducing carbon emissions and enhancing carbon storage in soil and plants.

• Choosing rechargeable electric options for mowers and trimmers aids in cutting gas emissions by reducing reliance on gas-powered lawn and garden equipment.

Image courtesy of: duallogic

• Avoiding synthetic nitrogen fertilizer is crucial in sustainable gardening, as it is a major contributor to greenhouse gas emissions.
• Strategically position trees and greenery around your home and community structures to save energy, ensuring they align with the sun’s orientation. Deciduous trees offer summer shade and winter sunlight, while evergreen trees provide protection from winter winds and improve insulation.

Image courtesy of: duallogic

• With climate change, one can expect more rainfall and floods. Sustainable gardens mitigate excess water through rain gardens or vegetated buffers, reducing runoff and erosion. Make it a point to use rain barrels for water storage.
• Food waste in landfills produces methane, a potent greenhouse gas that traps 28 times more heat per unit mass than carbon dioxide. To mitigate emissions, growing your food in sustainable gardens and purchasing from local sources minimizes the environmental impact of long-distance transportation and storage.
• Sustainable gardens aid in carbon storage by maintaining soil coverage with a variety of plants. Enhancing soil health involves adding organic matter and minimizing soil disturbance, while compost serves as a valuable resource for enriching and enhancing soil quality.
• Landscapes boasting diverse plant life exhibit increased resilience against emerging pest and disease threats and environmental shifts such as extreme heat and drought. In sustainable gardens, greater plant diversity also fosters support for pollinators and beneficial insects crucial for pest management and decomposition. Additionally, opting for native plants whenever feasible is important, as they demand less water and fertilizer while offering vital sustenance and shelter for wildlife. Perennial native plants contribute to carbon storage and help control soil erosion.

Image courtesy of: YuriArcursPeopleimages

In conclusion, gardeners can bolster the resilience of their green spaces to climate change impacts by diversifying native plants, improving soil health, cultivating heat-tolerant vegetables, and implementing stormwater management. This approach also termed climate-resilient gardening, fortifies landscapes against climate-related challenges

The post 10 Proven Tips for Creating a Sustainable and Eco-Friendly Garden first appeared on Yanko Design.

In Colombia, the dire reality of 3.7 million people lacking access to clean and safe drinking water has been aggravated by a severe drought in 2024. Many of these individuals reside in remote areas, where they endure extreme heat and scarce water sources, often contaminated and leading to thousands of deaths annually. In response to this critical situation, Filsa Water, a scientific company dedicated to developing infrastructure and technology solutions, has partnered with Ogilvy, Baylor International, and the Colombian Red Cross to introduce a groundbreaking product; the 3D printed Filter Cap. This innovative device transforms a universal bottle cap into a powerful water filtration system, providing an immediate and practical solution to the world’s water crisis.

Designer: Filsa Water, Baylor International Ogilvy,  and Colombian Red Cross

The Filter Cap is a compact, lightweight device weighing just 24 grams, designed to be attached to any standard PET bottle. Utilizing advanced 3D additive technology, the cap is composed of a mix of minerals, metals, and natural extracts. This ingenious design allows the cap to purify water as it flows through, effectively turning any PET bottle into a portable water treatment plant. The filtration system increases the water’s pH, adds hydrogen, reduces impurities by 70%, and eliminates 90% of heavy metals, making it a vital tool for ensuring safe drinking water in areas where it is scarce or unavailable.

The introduction of the Filter Cap comes at a critical time for Colombia, where the drought of 2024 has highlighted the vulnerability of remote communities. The compact nature of the Filter Cap makes it an ideal solution for humanitarian efforts and disaster relief. It offers a simple yet effective way to purify water, reducing the risk of waterborne diseases and improving the overall health and well-being of affected populations.

The device is designed to be environmentally responsible. Its casing, also 3D printed from cornstarch-based resin, is compostable after use. This feature not only promotes the reuse of plastic bottles but also aligns with sustainable practices, addressing both the water crisis and environmental concerns.

The impact of the Filter Cap extends beyond immediate water purification. By reclaiming over 300,000 liters of water in just two months, the device demonstrates its potential to significantly improve access to safe drinking water in underserved areas. This level of efficiency and effectiveness underscores the importance of innovative solutions in tackling global challenges.

Filsa Water and its partners have envisioned the Filter Cap as more than just a product; it is a lifeline for communities in need. By making clean water accessible and affordable, the Filter Cap has the potential to transform lives, offering hope and relief to millions of people. Its ease of distribution ensures that even the most remote populations can benefit from this technological advancement, marking a significant step forward in the global effort to provide safe drinking water for all.

The post 3D Printed Filter Cap Delivers Clean Drinking Water To Millions In Drought-Stricken Colombia first appeared on Yanko Design.

They say everything in nature has a purpose for existing, even if their existence is a nuisance to us humans. Scavengers, for example, are nature’s janitors and recyclers, putting dead things to good use. Even termites, whose presence is often a death sentence for homes and structures, are important to the ecosystem, and they can apparently serve as artful inspiration as well. Maybe not the termites themselves but the complex tunnels they create inside their mounds. These patterns are actually meant to facilitate airflow, which makes it the perfect reference for a man-made cooling solution that brings natural design and technology together to create a more sustainable solution to hot temperatures.

Designer: Rameshwari Jonnalagedda

There has been some interest in alternative cooling solutions, especially those that don’t consume too much electricity or none at all. Traditional techniques, particularly evaporative cooling that makes use of clay pots or pipes, have gained a lot of traction, especially because they can become decorative pieces inside modern homes. That said, the old methods don’t exactly scale well to today’s climate, room sizes, and needs, so designers have to think a bit outside the box to come up with a better solution to fit modern needs.

TerraMound looks to termites for one part of the solution, particularly how their shapes exemplify high surface-area-to-volume ratios, meaning how much surface area there is in a compact space. Surface area is one of two critical elements in an evaporative cooler, and that is made possible by utilizing complex geometric patterns that look like artistic versions of termite mounds. Such a design would be impossible to do en masse by hand, which is where 3D printing comes in and where the project’s uniqueness really shines.

The other critical element to this type of cooling solution is porosity, which is why clay is the preferred material for this kind of cooler. Clay is also not a typical 3D printing material, which is what makes this ceramic cooler design even more special. This method can eventually be extended to large-scale 3D printing technologies, allowing the quick and easy production of facade panels, walls, and other structures that not only look beautiful but can also help improve airflow in buildings.

As a cooler, TerraMound isn’t completely passive, as it has a fan at the bottom to draw air upwards. A planter sits on top as a source of water that trickles down the desktop cooling tower, utilizing the absorbent properties of the terracotta clay to help the evaporation process. It also acts as a distinctive and beautiful piece of table decoration, one that you wouldn’t have guessed was inspired by something we humans consider to be pests.

The post 3D printed ceramic cooling tower takes inspiration from termite mounds first appeared on Yanko Design.