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Discover new technologies by our partners

Leveraging our wide network of partners, we have curated numerous enabling technologies available for licensing and commercialisation across different industries and domains. Our focus also extends to emerging technologies in Singapore and beyond, where we actively seek out new technology offerings that can drive innovation and accelerate business growth.

By harnessing the power of these emerging technologies and embracing new technology advancements, businesses can stay at the forefront of their fields. Explore our technology offers and collaborate with partners of complementary technological capabilities for co-innovation opportunities. Reach out to IPI Singapore to transform your business with the latest technological advancements.

AI-Based Material Sorting Robot For Plastic Recycling
Plastic recycling plays a crucial role in achieving a sustainable future. Proper sorting of waste plastics is essential, especially in mixed waste streams where various materials are combined. Some types of plastic are not recyclable, and even recyclable ones can be difficult to separate efficiently. Sorting mixed waste streams into different recyclable categories can be time-consuming and labour-intensive, especially for materials with similar appearances, such as different types of plastic. To address these challenges, this technology aims to automate and accurately sort plastic waste, reducing the reliance on manual processing and improving overall plastic recycling efficiency. The technology on offer is a patented artificial intelligence (AI) based material sorting robot that sorts plastic waste accurately. Comprising of a camera, recognition unit and analysis unit, each unit of this system can continuously identify and sort waste plastics and generate information in real time. Blower vacuum adsorption devices are placed within each unit to pick waste in a speedy and accurate manner. This technology effectively reduces the issue of labour shortage in the waste sector, lowers operating costs and contamination rates that hinders recycling efforts. Currently, the technology has been deployed successfully in South Korea to sort polyethylene terephthalate (PET), polyethylene (PE) and polypropylene (PP). The technology owner is interested to work with Singapore waste collection companies on joint development projects to testbed this technology and improve plastic recycling rates. This technology comprises of the following hardware and software components: Camera unit – for real time monitoring Recognition unit – for real time item detection and data collection Analysis unit – for analysis of the type, colour, contamination level, and presence or absence of lids and labels Conversion unit – for item selection and sorting AI-enabled dashboard Key features of this AI-enabled material robot include: Sort rate of 96 pieces per minute 99.3% accuracy 7 types of waste This technology has been validated for plastic waste sorting (PET, PE and PP) and can be expanded into sorting of other types of wastes such as paper, plastic vinyl films, aluminium, iron and textiles. Other potential applications include construction and marine waste. High recognition and sorting accuracy Improves waste sorting efficiency by 240% in terms of speed and 126% in terms of operation time Cost-effective solution for resource efficiency (279% reduction in sorting costs) artificial intelligence, AI, robot, waste, plastic recycling, sorting, smart city, waste management, automation, environment, recycling, resource recycling, circular economy, sustainability Infocomm, Artificial Intelligence, Waste Management & Recycling, Industrial Waste Management, Automation & Productivity Enhancement Systems, Sustainability, Circular Economy
Autonomous Marine Pollutants Recovery Robot
Pollution in oceans and rivers is a global concern due to contaminants like oil spills and microplastics, which harm biodiversity. In response to marine pollutions, extensive human and technological resources are typically deployed to mitigate the situation, this includes absorbent, oil skimmer machineries, drones or vessels depending on the complexity of required clean-ups, resulting it being costly and time consuming. Designed and developed by a Korea-based startup, the technology proposed herein is a robot deployed onto the water surface to efficiently recovers pollutants autonomously with minimum human intervention. Unlike conventional pollution recovery equipment that uses additional devices connected by hoses, the robot combines the recovery of pollutant, transportation and storage of pollutants into a single robot device that can travel up to 1000 m range. The robot is equipped with a proprietary hydrophilic ratchet-based contaminant recovery technology, which generates a flow that sucks water through the movement of a hydrophilic material and controls the attachment and detachment of contaminants on the surface of the material by capillary force. This proprietary recover technology enables the robot to recover bunker fuel spills including high viscosity low sulfur fuel oil (LSFO), low viscosity heavy fuel oil (HFO), diesel, as well as microplastics in an efficient manner. The technology owner is seeking to collaborate with companies that provides marine pollution control/recycling service and government agencies to conduct a pilot trial in Singapore, with an option to further co-develop and integrate technologies that enhances the capabilities of the robot, such as identification of marine pollutants. Two solutions were offered: Oil skimming robot: 100 kg remote controlled robot of up to 1000 m operating range. About 1.0 ton of recovered oil/contaminant storage tank and process up to 26.6 kL/h. Capable of unmanned/autonomous/remote operation with minimum supervision. Field demonstration performed in river, harbour, and open sea in Asia and Middle East. Ocean cleaner robot: 45 kg remote controlled robot of up to 1000 m operating range. About 0.2 ton of contaminant storage tank and process up to 2 ton/h. Both solutions work in tandem with an air drone that pins a GPS location where pollutants are found. The information is then relayed to the robot for its autonomous navigation to its target location for its operation. The robots can be deployed for floating pollutants recovery from the surface of the water, such as rivers, beams, dams, and oceans. Pollutants that can be recovered include high viscosity low sulfur fuel oil (LSFO), low viscosity heavy fuel oil (HFO), diesel, microplastics of 0.001-5 mm, etc. A ratchet-shaped material that enhances the effect of attracting water to hydrophilic porous materials to optimise the recovery of marine pollutants in an autonomous robot. Marine Waste Management, Marine Pollutants, Marine Pollutant Recovery Robot Environment, Clean Air & Water, Mechanical Systems
Practical IoT Solutions for Facility Management, Asset Tracking and Digital Medicine
This technology provides simple, practical, and reliable IoT solutions designed for seamless integration and easy deployment across various industries, including Facility Management, Smart Cities, Asset Tracking, and Digital Healthcare. The solutions are designed for high reliability and low total cost of ownership, featuring easy deployment that requires minimal technical expertise. The technology is built with a carrier-grade design approach, ensuring robust performance and exceptional system longevity. It supports extensive scalability and security features, making it ideal for both public and private network operators. The flexible architecture allows for integration with existing digital infrastructures, facilitating improved operational efficiency and data-driven decision-making, and driving forward the digital transformation agenda This offering is particularly suitable for enterprises seeking to implement smart technologies in utilities, facility management, healthcare systems, and industrial IoT environments. The technology consists of IoT gateways and sensors leveraging LoRaWAN technology, known for its low power consumption and long-range connectivity advantages. The system features include Carrier-Grade design, advanced data analytics, and extensive scalability. It is secured with strong protocols, ensuring data integrity and privacy. Ideal collaboration partners are telecommunications operators, urban planners for smart city initiatives, healthcare institutions advancing in digital solutions, and enterprises looking to deploy their own private IoT networks. These partners will gain from the technology’s low-power, long-range capabilities, allowing them to deploy low-maintenance solutions over large areas. This IoT technology, utilizing LoRaWAN’s capabilities, is versatile enough for deployment across multiple sectors. Key industries include: Smart Cities: Enhancing urban infrastructure through applications like smart utilities, traffic management, environmental monitoring, and public safety systems. Facility Management: Optimizing operations in commercial and residential buildings through energy management, predictive maintenance, property protection (ie. leak monitoring) and security systems. Healthcare: Deploying digital healthcare solutions such as remote patient monitoring, medical asset tracking and environment monitoring Utilities: Facilitating smart grid technologies, water management solutions, and utility usage monitoring to improve efficiency and reduce operational costs. Agriculture: Supporting precision agriculture techniques with soil monitoring, crop health tracking, and automated irrigation systems. The technology owner is seeking collaboration with deep-tech companies specialising in AI development for IoT applications to enhance the value of their solutions. Specifically, they aim to partner with experts in on-device or edge AI for low-power operations, focusing on areas such as anomaly detection, predictive maintenance, and sensor data analysis. Additionally, they are looking for partners with expertise in cloud-based AI to improve data processing, model training, and analytics capabilities. The technology owner is focused on expanding into new markets, particularly in the ASEAN region, and is seeking local collaborators with strong R&D capabilities, deep market knowledge, and a proven track record of success. By working together, they aim to tailor solutions that meet the specific needs of these markets, driving innovation and ensuring a competitive edge. This technology significantly advances the state-of-the-art in IoT solutions through its use of LoRaWAN technology, which provides unique benefits over traditional IoT systems: Extended Range and Penetration: Unlike conventional Wi-Fi or cellular-based IoT systems, LoRaWAN offers a far reaching signal that can penetrate dense urban infrastructures and reach rural areas without requiring extensive power or infrastructure, making it ideal for wide-area IoT applications. Low Power Consumption: The technology is designed for minimal energy use, enabling devices to operate for years on a single battery charge. This is a critical advantage for IoT applications where frequent battery changes are impractical, such as in environmental sensors or remote locations. High Network Capacity: It supports thousands of nodes over a single network without significant loss of performance, catering to the growing demands of urban developments and large-scale industrial deployments. Cost-Effectiveness: The setup and operational costs are significantly lower than those of traditional cellular networks, providing a more affordable solution for businesses and municipalities looking to implement IoT solutions. IoT, IIoT, Wireless Technology, Facility Management, Assest Tracking, Smart Buildings, Smart Cities, Digital Medicine, Digital Healthcare Green Building, Sensor, Network, Building Control & Optimisation, Indoor Environment Quality, Infocomm, Internet of Things, Smart Cities, Logistics, Inventory Management
Lixiviant for High Extraction of Silver from Silver-Coated Solid Wastes
Strongly corrosive acids and highly toxic cyanide-based solutions are currently the most commonly used lixiviants for extraction of silver from solid wastes through hydrometallurgy. While acids are generally able to achieve high extraction of silver, it is non-selective and leaches most of the other metals present, resulting in a complex mixture that needs rigorous segregation and purification downstream. Cyanide solutions are comparatively more selective towards silver but require costly safety infrastructure and measures to be put in place as they generate large amount of hazardous wastes.          The lixiviant developed offers a more user and environmentally friendly means to efficiently extract silver selectively from silver-coated solid waste. The formulation is free of cyanide and omits the use of any strong acids, making it relatively easy to handle and eliminates the safety, health and environmental problems associated with the use and post-treatment of conventional lixiviants, as the waste stream is mildly acidic and can be easily treated as normal acid waste. The raw chemical materials are also easily available in the market. The technology provider is seeking industry partners to test-bed the lixiviant and is open to license the technology to interested partners. Free of cyanide Contains low concentrations of organic acids and no strong acids Non-fuming and extracts under mild temperatures ≤ 40°C Contains stabilisers to reduce reagent consumption Allows high purity silver to be recovered from the leachate by conventional means such as precipitation & reduction ≥97 wt.% of silver extracted with saturation concentration of >10 g/L at 40°C Extraction is fairly selective, with silver constituting a major 85 – 98% of the metals leached This technology can be applied for extraction of silver from: Electronic wastes, such as printed circuit boards, connectors, lead frames etc. Industrial wastes, such as photographic films, solar panel wafer etc.  Recovered silver can be sold or recycled for other uses. Silver is widely used in the manufacture of numerous products such as electrical and electronic devices, photovoltaics (PV) modules, solders, photographic films and jewelleries. The demand for silver is forecasted to grow with its use in 5G-infrastructure and upcoming intelligent electronics, as well as in PV modules as more countries adopt renewable energy to counter climate change.     To meet the increasing demand for silver, recycling from secondary sources such as electronics and industrial wastes is essential. Increasing regulations put up worldwide that mandate the recycling of electronic wastes, accounts for the bulk of secondary sources of silver. Hydrometallurgy offers a way to recycle silver at a relatively low cost and smaller scale. With the employment of an effective lixiviant that is able to achieve high and selective extraction of silver from these secondary sources, it ensures that the most value is drawn from them. Additionally, the omission of strong acids and cyanide in the lixiviant eliminate the need for costly safety infrastructure and treatment of toxic waste streams generated.  Lixiviant can be directly employed in existing operating line Works under mild operating conditions Does not generate highly toxic waste streams Recovered silver in high purity Silver-Coated Solid Wastes Chemicals, Organic, Waste Management & Recycling, Industrial Waste Management
Empower Your IoT Devices with Wireless Charging
In recent years, with the increasing use of the Internet of Things (IoT), the number of information devices, including sensors, has risen significantly. This surge has led to challenges in battery replacement, charging, and power wiring for these devices. To address these issues, there is a growing demand for wireless power transfer technology. Traditional wireless power transfer technologies, such as smartphone charging systems, have primarily focused on supplying power over short distances. This limitation makes them unsuitable for devices installed over wide areas, such as IoT devices. In response, the development of long-distance wireless power transfer technology using microwaves has emerged. However, the amount of power that can be transmitted is constrained due to concerns about the effects of microwaves on human health and other communication devices. The developed microwave power transmission technology can efficiently transmit power using low-power microwaves within regulated limits. This advancement allows the use of devices like sensors as power sources even in environments where people and communication devices are present. The technology owner is seeking collaboration with IoT solution providers, platform providers, system integrators, and sensor manufacturers. The technology consists of a transmitter and multiple receivers. One transmitter can provide power to several receivers over a certain distance. Additional transmitters can be added if the total power demand of the receivers exceeds the limit. It is designed to solve power supply problems for IoT devices by efficiently and stably converting Radio Frequency to DC power. Small and High-Efficiency Reception: Advanced antenna design technology combines compact size with high efficiency, enabling the device to receive even weak microwaves despite its small size. Long-Distance Transfer: Innovative circuit design technology converts low-power microwaves within regulated limits into stable, efficient DC power, allowing the power supply to multiple receiving devices within a range of up to 10 meters. High-Speed Distributed Control: Further technological advancements facilitate the distributed cooperative control of multiple low-power transmitters. This enables the rapid formation of power concentration spots and the ability to follow human movement seamlessly. This technology can serve as a power source for IoT sensors where battery replacement and wiring are challenging. Applications include: Manufacturing Sites: Sensors attached to the moving parts of production equipment and robots. Infrastructure Inspection: Sensors for inspecting infrastructure facilities that are difficult for humans to access. Nursing Care Monitoring: Wearable sensors for monitoring the elderly. Office Environments: Numerous sensors collecting environmental information in office settings. With existing wired IoT sensor deployments, a sizable amount of budget and deployment time is required for installation, cabling, or regular replacement of batteries. This wireless charging technology enables wireless-power sensor deployments, reducing the complexity of wiring infrastructure, deployment time, and associated cabling and labor costs. Compact Design for Versatile Installation: The small size of the receiving devices allows for installation in confined spaces, offering greater flexibility in system design and integration. Efficient Power Distribution: Simultaneous power transmission to multiple receiving devices over a broad area minimizes the need for extensive wiring and frequent battery replacements. Advanced Power Management: Technological advancements in distributed cooperative control enable targeted power delivery to specific devices, making it ideal for applications that require higher power.  Wireless Power Transfer (WPT), Microwave Wireless Power Supply, Wireless Charger, Power transmitter & Power Receiver, IoT Sensors and Sensor Network Electronics, Power Management, Green Building, Indoor Environment Quality, Infocomm, Internet of Things, Wireless Technology
Exploration Robot for Pipeline Asset Anomalies Identification and Analysis
Leaks in water pipelines are a common problem for utility companies. In the utility sector, the term “real losses” refers to actual physical water leaks that occurs on transmission and distribution mains, leakage and overflow at utility storage tanks and leakage on service connections up to the water meter. These non-revenue water losses cause a significant economic loss even to some of the most well-managed water distribution systems in the world. To manage and reduce water loss, utility companies carry out preventive maintenance, perform active water network monitoring by using noise loggers, smart meters, flow/pressure meters to collect useful data. Another proactive approach is to employ state of the art leak detection and localisation technologies such as acoustic leak detection (hydrophones), accelerometers, or the use of robots/endoscopes. Such approaches often face the challenges of false alarms, inaccurate leak pinpointing, limited exploration range and high cost of long-term monitoring. Developed by a South Korea-based startup, the proposed technology herein relates to an AI-aided exploration robot for underground/buried pipeline diagnosis for leaks, cracks, corrosion, scale, surface damage and other anomalies using image, audio, pH and LiDAR sensor data. Unlike conventional robots, the exploration robot is designed to be relatively small (smallest being 4.4 cm diameter x 11 cm length) to enable direct inspection of the inside of small diameter water pipelines. Designed to complement hydroacoustic technology, the exploration robot also addresses the current challenge of short explorable distance of about 100 m by offering up to 3 km exploration range. The startup is seeking to work with utilities or companies providing services to utilities to perform trial preferably in Singapore and explore long term collaborations in terms of customising solutions to specific applications, as well as technology licensing and revenue sharing through joint development with Singapore-based partners. Consist of two types of tethered exploration rovers: 1) Small robot equipped with image, sound and pH sensors, and 2) Robot equipped with LiDAR equipment. Designed to navigate bends and angles within pipelines, the robot is capable of inspecting water pipes with diameters ranging from 50 mm to 300 mm. Based on the collected data, the system performs AI-aided diagnosis of anomalies of up to 5 classes, i.e., Normal Pipe, Weld, Corrosion, Scale, and Surface Damage, along with a water pipe deterioration score and recommendation for pipe cleaning and/or replacement cycle. Capability to develop 3D maps based on image and other sensor data to enable digital twin-based asset management solution for the water distribution network and facilities. Utilities or public agencies that operates and maintains the water distribution network. Facilities that are close to its useful life: for early warning / prediction of the cleaning and replacement cycle of pipes. Future development for oil and gas pipelines applications. As of 2018, the global water industry generated about $1087.4 billion, accounting for about $600 billion in capital expenditures and operational expenditures for water and sewage-related facilities. Singapore's smart city and infrastructure management market is growing rapidly, and it is expected to reach billions of dollars by 2025. In particular, the water supply and infrastructure management market constitute a significant portion, estimated at several million to tens of millions of dollars annually. The nationwide water leakage rate in Singapore is around 10%, which is a substantial loss for a small city-state. Efficient and accurate pipeline inspection and maintenance powered by AI image analysis and digital twin. Exploration robots equipped with multiple types of sensors including LiDAR to generate 3D maps, with industry leading exploration range of up to 3 km. AI-driven robot inspects water pipelines in real-time, detecting issues such as leaks, corrosion, and blockages without requiring service interruptions, which ensures a continuous water supply and minimises costly manual inspections. Water pipes, Abnormal signs, Exploratory robot, 3D maps, Digital twin Environment, Clean Air & Water, Sensor, Network, Monitoring & Quality Control Systems
Durable and Cost-Effective Anti-Fouling Coating
Anti-fouling coatings have garnered significant attention due to the increasing demand for durable, low-maintenance, and aesthetically pleasing surfaces in both residential and commercial spaces. These coatings help maintain cleanliness and appearance, reduce cleaning frequency and effort, and offer substantial cost savings in maintenance. However, balancing the performance and cost of anti-fouling coatings, particularly in achieving both oil repellence and dust resistance, remains a challenge. There is also a growing emphasis on developing stain-repellent coatings that provide long-lasting protection against abrasion. The technology offers a special fluororesin-based functional coating with excellent water and oil repellence and dust resistance. This thin, transparent and durable coating can be applied to metals, plastics, ceramics and various other surfaces. It effectively reduces the accumulation of oil and stain build-up on the surface, prolonging the life span of home appliances and reducing maintenance frequency. With these superior properties, such coatings have great potential for applications across electronics, household appliances, and automotive applications, enhancing product performance and durability while improving user convenience and hygiene.  The technology owner is seeking joint R&D collaboration and partnership with companies interested in integrating this coating into their products and applications. The coating formulation is a unique organic-inorganic composite resin that incorporates particle dispersion technology. It is synthesized by copolymerizing acrylic resin with polysiloxane and fluorine units, resulting in a resin with high water and oil repellency and low surface resistance. Key features of the anti-fouling coating include: Balanced performance: effectively repels water, oil stains, and dust Ultra-thin and transparent: preserve the appearance of materials with a 2-5 µm clear coating layer Long-lasting: improved scratch resistance due to the highly durable resin layer Customisable: tailor the coating by adding anti-static, antibacterial and antiviral properties Cost-effective: more affordable than existing PTFE and high fluorine content coatings Versatile application: suitable for a wide range of materials and surfaces Easy application: a simple 3-step process involving surface cleaning, spray coating and low temperature baking (100 °C). Energy saving and environmentally friendly The potential applications of anti-fouling coating include but are not limited to: Households: interior walls, ceilings, kitchen countertops, toilet seats, furniture, etc. Electrical appliances: lighting, ventilation fans, refrigerators, ovens, etc. Electronics: mobile phones, displays, touch panels, printed circuit boards (PCBs), etc. Automotive: windows, dashboards, wheels, fabric seats, etc. Industrial sectors: machinery, equipment, packaging materials, etc. Textiles and fashion: silks, fabrics, wallpapers, etc. Optimal performance: balanced oil repellence and dust resistance Enhanced durability: ensures long-lasting effect Cost-effective: low material cost and simple process (low temperature baking) Anti-fouling, coating, surface durability, water-repellent, oil-repellent, Dust resistence Materials, Composites, Chemicals, Coatings & Paints, Sustainability, Circular Economy
Carbon Mineralization Technology for Upcycling of Industrial Solid Waste
With rising concerns about carbon emissions, Carbon Capture, Utilization and Storage (CCUS) plays a crucial role in combating climate change. CCUS helps reduce emissions by capturing carbon from flue gas, removing carbon from the atmosphere, and transforming captured carbon into value-added products. However, conventional CCUS technologies often involved high energy consumption and operational expenses. Current carbon mineralization processes face challenges such as slow reaction rates, limited scalability, and high associated costs. To address these challenges, the technology owner has developed an economically viable carbon mineralization technology that integrates carbon fixation and the reuse of industrial solid wastes in an integrated manner. This technology targets both carbon utilization and long-term carbon storage. It focuses on using alkaline industrial solid wastes, such as steel slag, fly ash, and cement waste, which are rich in calcium and magnesium oxides, to efficiently sequester CO2. The process involves leaching calcium and magnesium ions from slag and precipitating them as carbonates for various applications. This modular technology is scalable and adaptable to different waste materials, promising substantial carbon reduction and transforming industrial waste into valuable resources. Implementing this technology allows steel, cement and chemical companies to tackle high carbon emissions and waste disposal issues simultaneously. The final product, with carbon-negative properties, helps downstream clients reduce the carbon footprint of their products, such as plastic, paper, rubber tires, paint and cement.  The technology owner is seeking collaboration with industrial partners, especially industrial waste producers, high carbon emission plants, cement companies using post-carbonation slag, and manufacturers of paper, plastic, and rubber. The technology consists of a carbon mineralization plant with 4-steps facilities: Reaction Facilities: extract calcium ions from industrial solid wastes using CO2 based acid Solid-Liquid Separation Facilities: separate liquid enriched with calcium ions and the post-carbonation slag Precipitation Facilities: produce calcium carbonate Drying Facilities: dry the final product to meet client’s requirement Key features of this technology include: Flexible CO2 Sources: can use ambient air, flue gas from various plants, or any gas mixtures containing CO2 Lower Energy Consumption: utilizes industrial waste, reducing energy-intensive raw material processing Cost-Effective: reagent recycling minimizes material costs, making the process economically viable Scalability: modular and adaptable design allows for easy scaling and application across various industries Environmental Impact: converts waste into valuable products, addressing CO2 emissions and industrial waste Industries for Deployment: Steel plants Cement plants Coal power plants Other industrial sites producing CO2 emissions and solid wastes Marketable Products: High-purity calcium carbonates for various industrial applications such as plastic, paper, paint, rubber tyre, etc. Post-carbonation slag with low iron content can be used as supplementary cementitious materials (SCM) for clinker Post-carbonation slag with high iron content can be recycled to the sinter plant as sinter ore Dual Benefit: combines carbon capture and waste management Economic Viability: generates revenue from products, offsetting costs Flexibility: adaptable to various industries and CO2 sources Sustainability: support a circular economy by turning waste into resources Carbon Capture, Utilization and Storage (CCUS), Carbon Mineralization Technology, Industrial waste Waste Management & Recycling, Industrial Waste Management, Sustainability, Low Carbon Economy
Eco-Friendly Water-Based Air Purification
Controlling both outdoor and indoor air pollution is crucial for protecting human health and the environment. Outdoor air pollution from industrial emissions and vehicle exhaust contributes to respiratory and cardiovascular diseases, global warming, and environmental degradation. Indoor air pollution can also cause chronic respiratory conditions and other health issues. According to the World Health Organization (WHO), outdoor air pollution causes approximately 4.2 million premature deaths annually, while indoor air pollution accounts for around 3.8 million premature deaths each year. Traditionally, wet scrubbers are used to reduce air pollution, ensuring regulatory compliance and protecting human health. However, they have drawbacks such as scaling, fouling, inefficient pollutant removal, and generating solid waste. These issues lead to frequent maintenance, high operational costs, and environmental pollution. This technology addresses these pain points by utilizing an array of water jets without the need for packing materials. This innovative solution offers more efficient pollutant removal, reduced maintenance, a compact design, and lower energy consumption, effectively solving the problems associated with traditional wet scrubbers. The technology owner is seeking collaborations with companies in the chemical/ pharmaceutical/ steel manufacturing sector for test-bedding and research and development (R&D) projects that require an eco-friendly scrubber. The advanced scrubber technology features 3000 high-efficiency water jets that maximize contact area and ensure even water distribution, eliminating the need for traditional packing materials. This design addresses issues like scaling, fouling, and corrosion, resulting in lower maintenance and operational costs. The system is compact, enhancing space utilization within facilities. It operates with a compressed spray, effectively capturing pollutants through vertical collision and inertial force. Test results demonstrate a significant reduction in pollutants such as ammonia, formaldehyde, and acetic acid. Additionally, the technology is energy-efficient, reducing power consumption compared to traditional scrubbers, and supports sustainability goals by minimizing solid waste generation.  This technology has the potential to be applied on these areas, harnessing on its ability to remove pollutants effectively using water as a filter: Chemical Manufacturing: Handles a wide range of chemical emissions effectively, ensuring compliance with environmental regulations Steel and Metal Processing: Captures fine particulate matter and metallic dust, improving air quality Food and Beverage Processing: Improves air quality in processing plants, enhances worker safety, and reduces environmental impact Pharmaceutical Manufacturing: Ensures high removal efficiency for specific pollutants such as ammonia and formaldehyde High-Efficiency Water Jets: For maximizing gas-liquid contact, ensuring even water distribution, eliminating issues with uneven waterjet output when compared to traditional systems No Packing Materials: Does not require packing materials, addressing problems like scaling, fouling and corrosion of traditional scrubbers Statistically Proven: 100% reduction in pollutants such as ammonia, formaldehyde and acetic acid Environment, Clean Air & Water, Sanitisation, Mechanical Systems, Sustainability, Sustainable Living