Quest Climate的动态

?? Unlocking Sustainable Solutions: MicroAlgae Production Tech Leads the Way ?? In today's era of heightened sustainability concerns, industries worldwide are seeking alternatives to traditional ingredients. One such area of focus is algae—a botanical source widely recognized by consumers as safe and free of side effects. Algae's natural and exotic appeal has propelled it into the spotlight of the global nutraceutical and functional food industries, offering a rich source of bioactive compounds such as omega-3s, proteins, and carotenoids. ?? Global Impact: Algae's Potential Unleashed ?? With the global market for algae-based products valued at €6.4 billion annually, opportunities abound for businesses to harness this sustainable resource. While China and Indonesia dominate the market, there's significant room for growth in other regions. However, high production costs and limited volumes have thus far confined algae to high-value sectors like nutraceuticals. ?? Innovative Solutions: Addressing Industry Challenges ?? MicroAlgae Production Tech stands at the forefront of innovation, tackling key industry challenges head-on. By harnessing emitted CO2 from wineries, our technology provides a straightforward, low-cost solution to reduce carbon emissions. Through optimized cultivation methods and energy-efficient photobioreactors, we ensure high-quality microalgae production, opening doors to diverse applications in food, medicine, and beyond. ?? Empowering Sustainable Agriculture: Leading by Example ?? At MicroAlgae Production Tech, sustainability isn't just a buzzword—it's our guiding principle. By repurposing winery CO2 and optimizing cultivation processes, we're pioneering a greener, more sustainable approach to agriculture. From standards and reporting to claim offerings, our assurance programs empower businesses to adopt healthier practices and build a brighter future for generations to come. ?? Transforming Challenges into Opportunities: A Turn-Key Solution ?? The challenges facing the industry—from expensive CO2 sourcing to contamination risks—are significant. However, MicroAlgae Production Tech offers a turn-key solution for wineries, converting CO2 liabilities into high-grade microalgae with endless potential. Our automated cultivation processes ensure faster growth and higher volumes, paving the way for a more sustainable future. For more reads: https://lnkd.in/dm9T4Bey Join us in our mission to revolutionize sustainable agriculture and unlock the full potential of microalgae for a healthier, greener world. Together, we can turn challenges into opportunities and build a brighter future for all. #MicroAlgaeProduction #Sustainability #Innovation #GreenTechnology ??????

Digester Byproducts: Can They Have Value? Anaerobic Digestion generates a range of byproducts which could monetized. 1??Digestate ??Digestate is the 'waste stream' from biogas production, rich in nutrients (nitrogen, phosphorus, and potassium). ??It typically comes in two forms: liquid and solid. Uses: ??Liquid: A natural fertilizer for agriculture, can be ideal for direct soil application. ??Solid: A compost or soil amendment, or further processed into high-value bio-fertilizers for gardening and landscaping. Considerations: ??Digestate quality depends on the feedstock. ??Agricultural and food waste feedstocks can produce high-quality digestate ??Waste with contaminants may require additional treatment. 2?? Biochar ??Produced when digestate is subjected to pyrolysis. ??A carbon-rich material known for improving soil health and sequestering carbon ??A potentially valuable product for environmental and agricultural applications. Uses: ??Soil Amendment: Enhance soil structure, water retention, and nutrient availability. ??Carbon Sequestration: Locks carbon into the soil for hundreds of years, contributing to carbon offset projects. ??Wastewater Treatment: Filters and removes contaminants from water. Considerations: ??Pyrolysis equipment adds cost ??The environmental benefits and potential carbon credits can offset investment. 3??Carbon Dioxide (CO?): ??Biogas is primarily methane and CO?. ??Once biogas is upgraded to Renewable Natural Gas (RNG), CO? remains. Uses: ??Industrial applications in food processing, beverage carbonation, and greenhouse enrichment to accelerate plant growth. ??Can be fed to algae which are used in biofuels, food supplements, or cosmetics. Considerations: ??Requires investment in capture, purification, and transportation infrastructure. ??Demand is growing. 4??Sulfur ??A contaminant that is removed to protect equipment and improve gas quality. ??Desulfurization can produce elemental sulfur. Uses: ??In agricultural fertilizers to enrich sulfur-deficient soils. ??Industrial chemical manufacturing, such as sulfuric acid production. Considerations: ??Requires proper gas cleaning systems, but recovered sulfur can be a lucrative byproduct for the right markets. ??Volume, logistics, and offtakes matter. 5??Recovered Water: Water is often separated from digestate. Uses: ??Crop irrigation, conserving freshwater resources. ??Process water within the facility for cleaning or as a coolant. Considerations: ??Treatment may be required to meet quality standards for reuse. Maximizing byproduct value depends on several factors: ??Feedstock Quality ??Market Demand ??Technology Investment Evaluate your system. Find a buyer. Add a revenue stream.

For dairy farms, carbon credits represent an opportunity to generate additional revenue while implementing sustainable practices that reduce greenhouse gas emissions. Here's how carbon credits work in the context of dairy farming: How Dairy Farms Can Earn Carbon Credits: 1. Methane Reduction: Dairy cows produce methane, a potent greenhouse gas, primarily through enteric fermentation (digestive process) and manure management. By adopting practices such as using methane digesters to capture and convert methane from manure into renewable energy, dairy farms can significantly reduce their emissions. 2. Manure Management: Improved manure management techniques, such as composting or converting manure into biogas, can also contribute to emissions reductions. These reductions can be quantified and verified, allowing the farm to earn carbon credits. 3. Pasture Management and Reforestation: Some dairy farms can participate in reforestation projects or improve pasture management, which can increase carbon sequestration—removing carbon dioxide from the atmosphere and storing it in trees and soil. **Financial Benefits:** - Selling Carbon Credits: Once a dairy farm earns carbon credits by reducing its greenhouse gas emissions, these credits can be sold on carbon markets to companies looking to offset their emissions. This creates an additional income stream for the farm. - Lower Operational Costs: Sustainable practices like biogas production can also reduce energy costs on the farm, further boosting profitability. Custom Energy Inc. Erika Kirkland | Message me 512-496-2307 Grants|Tax Credits| Carbon Credits| Depreciation Solar|Digester| Wind | Food System #agrivoltaics #agriculture #sustainability #carboncredits #renewableenergy #dairy #dairyfarm #SustainableFarming #Sustainability #climate #Watercrisis #SolarInAg #GreenFarming#Worldhunger https://lnkd.in/e4qq_2JY

Interesting fact of the day - ????More sustainable practises - Nutrient Recovery in Wastewater Treatment????: ??Struvite Precipitation ?? Process: Recovers struvite (magnesium ammonium phosphate) from wastewater by adding magnesium which forms a precipitate with phosphate and ammonium under controlled pH. Benefits: Effectively removes phosphorus and nitrogen, preventing eutrophication; produces valued slow-release fertiliser. Applications: Common in municipal wastewater facilities, particularly those with high nutrient loads from industrial sources. ??Anammox Process ?? Process: Biological nitrogen removal using bacteria that convert ammonium directly into nitrogen gas anaerobically. Benefits: More energy-efficient than traditional processes, reducing costs and carbon footprint. Applications: Ideal for facilities with high ammonium loads, like those processing sludge digestate or industrial effluents. ??Algae Cultivation ?? Process: Uses algae to absorb nutrients from wastewater, which are then harvested for biofuel, animal feed, or fertiliser production. Benefits: Treats wastewater while producing valuable biomass. Applications: Implemented in tertiary treatment stages, especially in systems designed for integrated bioresource recovery. ??Ion Exchange ?? Process: Uses resin materials to selectively adsorb nutrients from wastewater, which can be released upon regeneration. Benefits: Effective for targeted nutrient recovery, like ammonium or phosphate. Applications: Useful in municipal and industrial settings, often as a final step after primary treatments. ??Membrane Technologies ?? Process: Employs nanofiltration and reverse osmosis to selectively remove and concentrate nutrients for recovery. Benefits: Controls the purity of recovered nutrients, suitable for producing commercial-grade fertilisers. Applications: Used in advanced treatment plants aiming for zero liquid discharge or nutrient recovery. ?Bioelectrochemical Systems (BES) ? Process: Utilises electroactive bacteria to convert the chemical energy in wastewater into electrical energy, recovering nutrients. Benefits: Energy-positive, reduces operational costs while recovering valuable nutrients. Applications: An emerging technology with potential in innovative and sustainable treatment facilities. ????Conclusion???? Impact: Sustainable nutrient recovery methods transform wastewater treatment plants from treatment-only facilities into bioresource recovery hubs, supporting a circular economy and enhancing environmental sustainability. Customisation: Each method offers specific advantages and can be adapted to meet the needs of different facilities, contributing significantly to both environmental protection and resource efficiency. #Sustainability #Nutrientrecovery #Wastewatereenery #Watermanagement

This is SUPER IMPORTANT ??? ”Based on feedstock, municipal waste stands as the PREDOMINANT feedstock in the biomethane market, representing the largest segment. This is attributed to the increasing recognition of municipal waste as a valuable resource for biomethane production” says ”Research and Markets” ?? Let us remember that food waste, through anaerobic digestion, is an important source of renewable ENERGY ??& sustainable FERTILIZER ?????? https://lnkd.in/dusJ7EYx

And on top of that let’s remember that as of this year there is a requirement on all of the EU that biowaste waste must be separately collected. And, according to the art 10 of Waste Framework Directive such separately collected waste cannot be landfilled nor incinerated.

I'm happy to share our latest article, "Eco-sustainable biorefinery to the management of winery waste by integrating sequential ready-to-use pigments and bioenergy through advanced multi-step kinetic slow pyrolysis", which was published in Industrial Crops and Products. This study aimed to design a sequential biorefinery from wine-making by-products for obtaining value-added products, focusing on extracting natural pigments and the evaluation of bioenergy produced by remaining biomass from Carménère Grape Residues (CGR) through slow pyrolysis. To achieve these goals, solid-liquid extraction of pigments from CGR was performed using a reusable bio-based solvent. Concurrently, these pigments' antioxidant activity and toxicity were evaluated in embryo cells, exploring their potential applications in the cosmetic industry. Secondly, it focused on applying the residual colorless biomass derived from the initial extraction process. This involved the evaluation of kinetic triplet: apparent activation energy, pre-exponential factor, and reaction model. From these parameters, the thermodynamic properties (?H, ?G, and ?S) were estimated. The results from the first step revealed the recovery of 18.21?mg/gCGR?of total anthocyanin that exhibited robust antioxidant capabilities and compatibility with biological systems, indicating potential applications in the cosmetic industry. The pyrolysis of residual colorless biomass revealed a complex chemical structure with multiple stages of decomposition. The kinetic parameters, including activation energy and pre-exponential factor, indicated better energy yield than other biomass, highlighting the potential for bioenergy production. The difference between activation energy and standard enthalpy of the reaction was less than 5.72?kJ/mol, indicating a favorable exothermic reaction and the feasibility of the energetic process. This study provides insights into the dual benefits of utilizing CGR for pigments recovering and bioenergy, contributing to sustainable practices towards a circular economy model. This work was led by Cassamo Ussemane Mussagy, PhD, and had the collaboration of ?Leonardo Mendes de Souza Mesquita,?Mauricio Rostagno, Felipe F.?Haddad, Jean L.?dos Santos, Cauê B.?Scarim, Rondinelli D.?Herculano, Jérémy?Valette, and Diakaridia?Sangaré. Thank you, Cassamo Ussemane Mussagy, PhD for the opportunity to collaborate with your work. You can find the full article in the link below: https://lnkd.in/dGXiywhd

?????????????? ???????????? ????????, ??????????, ?????? ????????????????: ?????????????? ?????????? ?? Biochar Market is anticipated to grow at a #CAGR of ????.??% in the forecast period (????????-????????)??, with the market size valued at USD ??.?? billion in 2023 and projected to reach USD ??.?? billion by 2034. ?????????????????? ???????????????? ???????? ?????? ???????? (????????-????????)???????????????? ???????????? ???????????? ? https://lnkd.in/g8rpsvaM Biochar, a charcoal-like substance made from burning organic materials in a low-oxygen environment, is gaining traction in the environmental and agricultural worlds. This wonder material boasts a range of benefits, from boosting soil health to capturing carbon dioxide. As a result, the biochar market is on a promising trajectory and is projected for significant growth in the coming years. Let's delve into the current size, key players, and exciting future of this sustainable solution. ?? ?????????????? ?????????????? ?????? ?????????????? ????????????: Several factors are contributing to the biochar market's growth: ???????????????? ?????????????????????????? ????????????????: Sustainability is becoming a top priority for both consumers and governments. The capacity of biochar to enhance soil health and sequester carbon is a perfect fit for these expanding issues. ???????????????? ???????? ????????????????: There is a sharp increase in the demand for organic food. Biochar is a great complement to organic farming methods since it functions as a natural soil additive that fosters healthy plant growth without the need for artificial fertilizers. ?????????????????????? ????????????????: The biochar market can be greatly expanded by government policies that support sustainable practices and carbon sequestration. ?? ?????? ??????????????: ? Carbon TerraVault ? CoolPlanet ? Active Earth Systems Pty. Ltd. ? BIOCHAR NOW LLC ? Phoenix Energy ? Diacarbon Energy Inc. ? Genesis Industries ? AGRI-TECH PRODUCERS, LLC ? Pacific Pyrolysis Pty Ltd ? Earth Systems ? Vega Biofuels Inc ? The Biochar Impact Company ? Full Circle Biochar ? BIOCHAR SUPREME, INC ? Airex Energy ????????? ???????? ???????????? ?? https://lnkd.in/gJ9gvKyQ ?? ?????????????? ???? ???????????? ???? ?? ?????????????????????? ?????? ?????????????????????? ?????????????????? ????????????? The biochar market might be a field worth exploring. Remember, this is a relatively young market, so conducting thorough research is crucial before making any investment decisions. #biocharproduction #biochartechnology #biocharresearch #organicfarming #regenerativeagriculture #circulareconomy #biocharinvesting #biochar #biocharmarket #sustainableagriculture #soilhealth #carbonsequestration #climatechange #greenfuture #renewableenergy ?????????? ????????????: https://lnkd.in/gkqbYPhw

?? From Pasta to Power: How We Convert Food Waste into Methane Gas ?? Did you know that your leftover pasta can be turned into renewable energy? Let's dive into the fascinating process of converting food waste, like pasta, into methane gas! ? Collection: The journey begins with the collection of food waste. Leftover pasta from households, restaurants, and food processing plants is gathered and transported to a biogas facility. ? Pre-treatment: At the facility, the pasta is pre-treated to remove any contaminants and broken down into smaller pieces. This makes it easier for the microorganisms to digest it. ? Anaerobic Digestion: The prepared pasta is placed in a large, sealed container called a digester. Inside the digester, the pasta undergoes anaerobic digestion, a process where microorganisms break down the organic matter in the absence of oxygen. This process generates biogas, primarily composed of methane and carbon dioxide. ? Biogas Collection: The biogas produced during anaerobic digestion is collected from the digester. This raw biogas is rich in methane, the key component used for energy production. ? Biogas Upgrading: The collected biogas is then purified to increase its methane content. This involves removing impurities like carbon dioxide, hydrogen sulfide, and moisture. The result is high-quality biomethane. ? Energy Generation: The purified biomethane can now be used as a renewable energy source. It can be burned to generate electricity, used as a clean fuel for vehicles, or injected into the natural gas grid for heating and cooking. ? Digestate Utilization: The byproduct of the anaerobic digestion process, called digestate, is rich in nutrients and can be used as a natural fertilizer to enrich soil. By converting pasta and other food waste into methane gas, we not only reduce landfill waste but also create a sustainable source of energy. This innovative process is a win-win for both the environment and energy production! ?? Learn more at https://lnkd.in/g8hu7JJR Get in Contact with Neil Gorsuch email [email protected] call or text Neil at 707-921-8182 #Corenco #FoodProcessing #FoodIndustry #FoodManufacturing #FoodProduction #FoodTech #FoodMachinery #FoodSafety #FoodPackaging #FoodInnovation #FoodProcessingEquipment #FoodProcessingTechnology #FoodProcessingAutomation #FoodProcessingFactory #FoodProcessingMachine #FoodProcessingSystem #IndustrialGrinding #industrialGrinder #wetgrinder #fruitsandvegetables #foodgrinder #granulation #extraction #juiceextraction #sizereduction #extractionequipment #liquidextraction #grinders #longevity #Efficiency #IndustrialGrinders #Automation #Productivity #CostSavings #Innovation #FreeTesting #RenewableEnergy #Sustainability #Biogas #FoodWaste #CircularEconomy

Anaerobic Digestion (AD) In the absence of oxygen, a biological process known as anaerobic digestion (AD) breaks down organic compounds including sewage sludge, food waste, agricultural waste, and other biodegradable materials. This is how it operates: 1. Anaerobic Conditions: An oxygen-free environment, usually a sealed reactor or digester, is used for anaerobic digestion. Anaerobic bacteria use a sequence of metabolic events to break down complex organic compounds into simpler ones in the absence of oxygen. 2. Four Phases: Usually, anaerobic digestion happens in four stages:? Hydrolysis: Simpler compounds such as sugars, amino acids, and fatty acids are produced when complex organic matter is broken down by hydrolytic bacteria. Acidogenesis: These simpler compounds are further broken down by acidogenic bacteria producing alcohols and volatile fatty acids (VFAs).? Acetogenesis: VFAs are converted into acetate, hydrogen, and carbon dioxide by acetogenic bacteria. Methanogenesis: As a result of the consumption of acetate, hydrogen, and carbon dioxide, methanogenic archaea produce carbon dioxide (CO2) and methane (CH4) as metabolic byproducts. 3. Production of Biogas: One of the main products of anaerobic digestion is biogas, which is a combination of carbon dioxide (CO2) and methane (CH4) with trace amounts of other gases, such as hydrogen sulfide (H2S), and other gases. Biogas is a sustainable energy source that may be collected and utilised for heating, power generating, and biofuel. 4. Digestate: The residue left over after digestion is referred to as digestate. It is nutrient-rich and can be applied as fertiliser or a soil conditioner. 5. Temperature Range: Mesophilic circumstances (about 30°C to 40°C) and thermophilic conditions (about 50°C to 60°C) are two temperature ranges across which anaerobic digestion may take place. 6. Benefits: Anaerobic digestion converts organic waste into biogas for renewable energy, lowers pathogen levels, reduces odour, and creates nutrient-rich liquid digestate for agricultural use. Organicco's digestate management and ??????DRYER solutions further transform it into stable granular green fertiliser. All things considered, anaerobic digestion is a versatile and eco-friendly way of dealing with organic waste that also produces valuable byproducts and renewable energy. Using Organicco’s ??????DRYER solution can make it even more environmentally friendly and less water-polluting. Redirects to: https://lnkd.in/eTU_jDFq #anaerobicdigestion #biogas #renewableenergy #sustainableenergy #wastetoenergy #circulareconomy #greenenergy #wastemanagement #zerowaste #ecofriendly