Kyoto Network partners with innovators and technology providers to deliver scalable, measurable, and deployable sustainability technologies. Our catalogue supports governments, corporations, and infrastructure developers in achieving tangible decarbonisation outcomes.
From waste-to-energy systems and carbon-capture installations to EV infrastructure and renewable power solutions, we provide access to technology that accelerates the global transition toward net zero. Every solution in our catalogue is vetted for technical feasibility, environmental performance, and alignment with SDG and ESG targets, ensuring that clients invest in outcomes with long-term value and verified impact.
Multi‑drone operations.
Operate drone missions from a climate-controlled command centre for stable, all-weather performance.
Impact: Efficient mission coordination.
Heavy‑lift reforestation.
Operate mid-range drones with 15kg payload capacity and 25-minute endurance for heavier field tasks.
Impact: Higher seed density deployment.
Long‑range mapping.
Use long-endurance drones capable of flying up to two hours for extended mapping and monitoring missions.
Impact: Large‑area coverage.
Ultra endurance.
Operate long-range drones with up to three hours of flight endurance for regional-scale reconnaissance.
Impact: Deep ecosystem surveys.
Heavy‑lift.
Use heavy-lift drones carrying 20kg payloads for one-hour operational missions.
Impact: High‑volume planting.
Ultra‑long endurance.
Deploy ultra-endurance drones capable of four-hour continuous flights for specialised extended missions.
Impact: Extensive MRV missions.
Ecosystem Restoration.
Identifies degraded or priority lands for planting. Monitors crop health, identify stress, disease or nutrient deficiency.
Thermal, multispectral, LiDAR.
Capture high-resolution imagery paired with advanced analytics for precision mapping and monitoring.
Impact: Accurate carbon/health assessment.
Mapping/monitoring.
Provide drones with 40-minute endurance and modular gimbals for versatile imaging and survey operations.
Impact: Low‑cost monitoring.
Hybrid ops.
Deploy VTOL drones offering one-hour flight times for efficient large-area mapping.
Impact: Precise MRV data.
Reforestation.
Deploy a lightweight drone capable of a 5kg payload and 20-minute flights for efficient seed dispersal.
Impact: Low‑cost scalable restoration.
Ecosystem Restoration.
Identifies degraded or priority lands for planting. Monitors crop health, identify stress, disease or nutrient deficiency.
Clean honey harvesting.
Enable clean, uncapped honey to flow directly into jars without contamination or manual extraction.
Impact: Higher quality product, lower processing cost.
Low-disturbance honey harvesting.
Use split-cell honeycomb frames for honey extraction without opening the hive, supported by external observation windows.
Impact: Reduced bee stress, improved colony health, higher honey yields, safe for beginner beekeepers.
Accessible urban & rural beekeeping.
Provide complete beekeeping kits including hives, tools, protective equipment and training materials.
Impact: Creates new livelihoods, supports local honey production.
Ecosystem restoration & crop pollination.
Deploy beehives across farms, orchards, agroforestry systems and restoration sites to support pollination.
Impact: Improved crop yields, increased biodiversity, stronger ecosystem recovery.
Energy recovery.
Convert residual organic waste into biogas for on-site electricity generation.
Impact: Renewable energy + reduced methane.
EngBC Production.
Convert organic residues into engineered biochar for long-term carbon storage and soil enhancement.
Impact: Carbon removal (CDR), soil enhancement.
High‑integrity credits.
Measure and verify the volume of CO₂ sequestered within engineered biochar products.
Impact: Premium VCM revenue.
Flexible deployment.
Provide plug-and-play systems with remote cloud monitoring for seamless deployment and real-time performance tracking.
Impact: Rapid scaling, low site requirements.
Quality control.
Pre-process biomass by adjusting moisture, refining particle size and removing impurities to optimise conversion.
Impact: High‑grade EngBC consistency.
Carbon measurement.
Track biogas production for carbon credit validation while remotely monitoring system performance and usage patterns.
Impact: Enables real-time monitoring of gas production and usage, improving system efficiency, reducing losses, and ensuring accurate carbon credit measurement.
Fuel Switching.
Convert livestock and organic food waste into biogas through anaerobic digestion, reducing indoor air pollution and reliance on smoky fuels.
Community energy distribution.
A central digestion hub processes organic and livestock waste into biogas, distributing fuel through a microgrid pipeline network to connected community users.
Impact: Delivers clean, reliable biogas to surrounding households and farms, cutting methane emissions, reducing deforestation, and lowering dependence on firewood and charcoal.
Circular agriculture.
Provide nutrient-rich organic fertiliser produced as a natural co-product of the biogas digestion process.
Impact: Digestate fertilizer creates a circular economy by turning organic waste into a valuable, nutrient-rich soil amendment, reducing the need for synthetic chemical fertilizers.
Biogas refinement.
Separate methane from CO₂ to enhance biogas purity and optimise energy output.
Impact: Higher biomethane value, clean energy.
Smoke-free cooking.
Burn biogas safely for cooking, replacing traditional three-stone fire stoves and reducing household smoke exposure to improve respiratory health.
Impact: Provides a smokeless, high-efficiency cooking solution that cuts household emissions, improves indoor air quality, and maximizes the clean energy benefits of biogas.
Large-scale biogas for schools.
Provide clean biogas for school kitchens through anaerobic digesters, replacing wood-fired systems, supporting 300–600 pupils, and producing a valuable fertiliser co-product.
Impact: Delivers clean, reliable biogas to surrounding households and farms, cutting methane emissions, reducing deforestation, and lowering dependence on firewood and charcoal.
Urban clean cooking.
Enable solar-powered electric cooking for community kitchens, reducing reliance on LPG and charcoal while supporting clean, smoke-free urban feeding programmes.
Impact: Delivers large-scale, zero-emission communal cooking capacity, reducing biomass use while providing clean, reliable heat for schools and community kitchens.
Bio‑CO₂ capture.
Capture and purify CO₂ generated during biomethane upgrading for downstream utilisation or storage.
Impact: Reduced emissions + saleable bio‑CO₂.
Emission control.
Use microbial biofilters to remove harmful gases and improve air quality around waste or biogas systems.
Impact: Cleaner emissions, regulatory compliance.
Industrial CO₂ supply.
Convert captured CO₂ into a purified liquid form suitable for food, industrial and commercial applications.
Impact: Stable domestic supply, replaces fossil CO₂.
CO₂ supply chain.
Aggregate CO₂ streams from multiple plants into a central processing or utilisation system.
Impact: Economies of scale, lower logistics costs.
Carbon monetisation.
Generate certified carbon credits under VCS, Gold Standard or Article 6 frameworks through verified emission reductions.
Impact: Additional revenue stream.
Bin collection.
Optimises waste collection routes, reducing manual checks and road time while making operations faster, safer and more efficient.
Impact: AI-powered routing leverages advanced algorithms and real-time data to dramatically increase efficiency, reduce resource consumption, and enhance decision-making in logistics and operational management.
Waste reduction, wifi production,.
Send real-time fill-level data to waste collection teams to prevent bin overflows and help keep urban areas cleaner.
Impact: This IoT sensor drastically reduces operational costs, optimizes waste collection routes, prevents bin overflows, and significantly improves urban cleanliness and public health.