TECH OFFERS

As climate change has led to hotter days, people are looking for ways to stay cool on the go. Whether for daily commutes, outdoor adventures, or work-related trips, there is a growing demand for portable cooling solutions. This technology offers a platform that can be applied to various wearable devices to cool down the human body. The battery-powered thermoelectric system is small, lightweight, and portable and can be used to create a variety of cooling products. This technology has the potential to make a real difference in people's lives. It can help people stay cool and comfortable in hot weather, which can improve their productivity, safety, and overall well-being. The technology provider is seeking collaboration partners to leverage this innovative cooling solution to develop alternative applications such as cooling sports equipment or personal protection devices.   The technology includes a battery-powered thermoelectric system that is lightweight and compact, weighing less than 60 grams. This makes it easily adaptable to wearable devices. The technology provides instant relief to the wearer in places of contact by directly cooling the body's circulating blood. This minimizes energy wastage, providing longer-lasting cooling without compromising performance. The technology can be applied to a variety of wearable devices, such as neck devices, wristbands, jackets, and more. The device can be optimized for different environments and activities, including travel and commuting, indoor workplaces, outdoor recreation activities, outdoor sports and fitness, and industrial workplaces. The market potential for personal air conditioner technology is promising. The global wearable air conditioner market size is projected to reach $7 billion in 2022 and grow at a CAGR of 19.3% to reach $41 billion by 2032. This growth is driven by the increasing demand for personalized and portable cooling solutions, as well as rising temperatures, global warming, and a growing focus on individual comfort and well-being. The market is currently dominated by a few players, but this technology stands out as the only solution capable of delivering uninterrupted cooling to the wearer. It was also well received on TrendHunter.com, a leading online trends platform. This technology provides a new way to cool down in hot and humid conditions. It is different from traditional cooling devices that merely circulate air. This technology provides targeted, continuous, and efficient cooling directly to the wearer's skin. This makes it more comfortable and effective than other cooling solutions. Personal Care, Wellness & Spa, Sustainability, Sustainable Living

An improvised LoRaWAN has been developed to enhance data transmission efficiency between LoRa trackers and LoRaWAN gateways addressing the prevalent issue of mid-air data loss due to collisions. This improved protocol enhances the data transmission rate from its current range of 10-30% to 65%. This substantial improvement leads to power savings for IoT end nodes, particularly those powered by batteries, by eliminating the need for data re-transmission. Moreover, the improved protocol also significantly increases gateway capacity, thereby reducing the capital expenditure associated with IT infrastructure. The technology enables LPWAN technology specifically LoRaWAN devices to operate for mission critical IoT applications. This protocol ensures robustness of data communication by low cost devices (e.g., LoRaWAN device suites). The stability in data delivery opens up the possibilities for extended applications for data monitoring to mission critical applications. The protocol uses existing hardware with a firmware update which can easily be adopted by device manufacturers, system integrators and application users directly. A robust data delivery method extends the ubiquity of IoT technologies and enables a wide range of applications such as Smart Cities, Smart Building, Assets & Human Tracking, Agritech, Environmental Monitoring, Logistics and Supply Chain, Smart Metering, etc. It enhanced real-time data collection, analysis, and communication between interconnected devices, leading to increased efficiency, automation, and improved decision-making. Data reliability and Quality of data transmission for mission critical applications. Enable power savings for IoT end nodes which are batteries powered Improve data reliability, eliminating the need for data re-transmission Increases LoRaWAN gateway capacity, thereby reducing the capital expenditure associated with IT infrastructure LoRa, LoRaWAN, IoT, IIoT, LPWAN Infocomm, Wireless Technology

To achieve a net-zero carbon emission goal, energy derived from fossil fuels are replaced with green renewables such as solar, wind, etc. However, these renewable energies are intermittent in nature and therefore requires a reliable energy storage system to store these energies. Today, batteries based on lithium-ion and lead-acid are widely used as the go-to energy storage system. However, there are fire safety concerns for the conventional lithium-ion batteries due to its highly volatile and flammable electrolyte while the acidic electrolyte and carcinogenic lead used in lead-acid posed threat to both human and environmental health. Therefore, there is a need for a new safe and environmentally friendly battery system. This technology offer is a safe and rechargeable water-based battery using a unique green electrolyte formulation (close to neutral pH). Owing to the widened electrochemical stability window and high ionic conductivity of the proposed electrolyte formulation, it enables superior electrochemical performance of the electrode materials used in the batteries, suited towards large-scale energy storage applications. Safe technology: No risk of fire or explosion Green: Environmentally friendly, non-toxic and non-corrosive materials used High performance: High-rate capability with superior cell energy density (50 – 140 Wh/kg, 5000 – 10000 cycles, 80 – 90% cycle efficiency) Ease of assembly and maintenance: System can be handled and operated in an ambient environment Cheap ($45/kWh) This technology offer is for industries or partners who are interested in energy or battery storage systems. The potential applications include but are not limited to: Store clean renewables energies (e.g., solar, wind, etc) from power generation side Supply low-cost energy and power energy demand from household/industrial/ commercial/EV charging station Provide safe and stable energy system as a backup power for high security building (e.g., data centre, etc) Safe (non-flammable system) High performance (50 – 140 Wh/kg, 5000 – 10000 cycles, 80 – 90% cycle efficiency) Cheap ($45/kWh) Easy assembly and maintenance Scalable Environmentally friendly (non-toxic and non-corrosive materials) Battery, sustainability, energy, Electrolyte, energy storage system Energy, Battery & SuperCapacitor, Sustainability, Low Carbon Economy

Bitumen is widely used as an essential binder for many applications due to its excellent adhesive properties, waterproofing, and high durability. However, the conventional application of bitumen involves on-site melting at high temperature exceeding 250°C, necessitating rapid pouring on the surface with additional torch-on, which poses complications and safety risks. Moreover, the on-site melting process releases harmful gases, including hydrogen sulphide and volatile organic compounds (VOCs), endangering workers and nearby areas. To address these challenges, there is a need to develop a safer form of bitumen that does not compromise material performance. This technology transforms solid bitumen into a single-component liquid bituminous coating at room temperature via a simple and cost-effective formulation using solvents, fillers, and additives. The fillers used in the single-component liquid bituminous coating can be made from waste materials such as food waste. Such sustainable fillers could offer comparable material performance to conventional industrial fillers. This high-performance bituminous coating has excellent workability at room temperature, fast drying, and easy production without the need for heating. Thus, this technology eliminates the hazards associated with conventional application of bitumen, providing a safe and energy-saving alternative. One practical application of this technology is a roof waterproofing system that complies with Singapore standards SS133:2017 and/or SS374:1994 (2023). This technology is available for R&D collaboration, IP licensing, and test-bedding with industrial partners in the construction and infrastructure sectors.   Free of smoke and fumes Simple and energy-saving production (no heating required) Water-resistant, corrosion-resistant, and UV resistant Fast-drying and odourless after drying Easy application with excellent coverage Can be easily applied by brush, spray, squeegee, or trowel Compatible with various substrates and structures (dry or damp surfaces) Applicable to both horizontal and vertical surfaces without substantial runoff Option to incorporate sustainable fillers Complies with SS133:2017 and/or SS374:1994 (2023) standards The potential applications include: Primer and paints Waterproofing coating Sealants Adhesives Binder additive in various substrates, including cement, concrete, metal structures, and castings The technology offers the following unique features: Transform solid bitumen into a single-component liquid bituminous coating at room temperature via a simple and cost-effective formulation Option to incorporate sustainable fillers Simple, eco-friendly, and energy-saving process without heating Can be applied to different structural elements for waterproofing, damp proofing, and corrosion resistance Materials, Composites, Chemicals, Coatings & Paints, Organic

Liquid fuels from biogas are a promising source of renewable and clean energy as they give a lower emission of sulphur dioxide, nitrogen oxide, and soot than conventional fossil fuels. They are sustainable and economically viable as they can be obtained from agricultural waste. However, transforming biogas into a high-value liquid fuel equivalent to diesel or gasoline requires a costly two-step process.  The technology developer has developed a novel enhanced capsule catalysts with unique core-shell structures that enable the production of high value-added liquid fuels from biogas in a single step with only one reactor. These capsule catalysts directly convert synthetic gas (syngas) into liquid fuels, which have improved petrol-like qualities. Therefore, these liquid fuels can be used either as diesel or gasoline substitutes without any modification to engines and existing refuelling facilities. The technology developer seeks companies looking for renewable and clean energy through the gas-to-liquid (GTL) technology to license and commercialise this technology.  The novel enhanced capsule catalysts have a unique core-shell structures to produce liquid fuels from biogas in a single step. The capsule catalysts have the following properties: Dual functionalities, which bring about gas-to-liquid reactions while enabling catalytic cracking and isomerisation, thus achieving a one-step process Excellent durability and high surface area, enabling a higher yield of liquid fuel A robust mesoporous framework that is optimised for the conversion rate of reaction High selectivity for shorter-chain or light hydrocarbon (C5-C10) and a high CO conversion, allowing biogas to be converted more efficiently into high-value liquid fuels within a shorter period of time The direct conversion of syngas allows liquid fuels to be obtained with properties similar to diesel or gasoline, as a renewable and clean energy source, without any modification to engines and existing refuelling facilities. The technology developed for catalyst production and syngas conversion to liquid transport fuels is highly scalable. This technology has the potential to reduce the overall cost of the process as only one reactor is required with these novel catalysts as compared to two reactors using the existing technology. Biogas has been identified as one of the sustainable and economically viable solutions because the feedstock can be obtained from agricultural wastes and wastewater from industries, either locally or from neighbouring regions. Therefore, this technology has the potential to penetrate the market for catalytic materials in the gas-to-liquid processes.  Suitable for: Poultry farms Food waste treatment plants Wastewater treatment industries  Companies who are looking for renewable and clean energy through the gas-to-liquid (GTL) technology to diversify their energy sources. Applications: Diesel or gasoline substitutes  Reduce gas-to-liquid production costs as only one reactor is required Ability to obtain liquid fuels with properties similar to diesel or gasoline without further modifications Scalable More efficient compared to the existing technology with a single-step process conversion to liquid fuel biogas, clean energy, renewable energy, sustainable fuel, bioenergy Energy, Biofuels & Biomass, Waste-to-Energy, Sustainability, Circular Economy, Low Carbon Economy

Wireless monitoring solutions are gaining traction worldwide due to their added benefits of continuous monitoring capability 24/7. An innovative technology has been devised that has a way of converting variations in the reflected wavelength from fiber grating based sensors into intensity variations that can be easily processed through the electronic circuits and transmitted wirelessly. Conventional fiber grating based sensors measure the wavelength shift of the reflected light to determine the mechanical strain experienced by the medium in which the grating is embedded.  This is conventionally done through a Fabre Perot interferometer which is referred to as the Interrogator but is a costly solution. The innovative circuitry eliminates the need of the costly, and typically more bulky interferometer, replacing them with cost effective and compact fiber components configured in such a way that converts mechanical strain into intensity changes. Fiber Bragg Grating based fiber optic sensors connected to a LoRaWAN (923MHz) based wireless network. 1550nm Centre wavelength sensors connected to a configured wireless node to capture data and send to a designated server. Low powered, battery operated device with fully configurable sensor inputs. Suitable for players in the condition monitoring/structural health monitoring/ FEA validation fields. The system is designed for structural health monitoring applications which is agnostic in terms of specific industry. The system can be deployed in any industry that requires some form of monitoring of their asset, e.g. Aerospace/Oil and Gas, Civil Infrastructure, Rail, Mining etc. Conventional wireless technologies do not cater for fiber optic sensors, where fiber option solutions may have significant advantages in specific use cases. This system provides all of the benefits of a wireless system but based on fiber optic sensors. Conventional fiber optic systems are expensive in comparison to conventional electrical systems and are also not readily suitable for on-site deployment. This system reduces the cost of the optical components with the simplified architecture, as well as provides a system that is suitable to be deployed directly in the field. Fiber Bragg Grating, FBG, Wireless, Structural Health Monitoring, Condition monitoring, Sensor Electronics, Printed Electronics, Lasers, Optics & Photonics, Infocomm, Big Data, Data Analytics, Data Mining & Data Visualisation, Green Building, Sensor, Network, Building Control & Optimisation, Wireless Technology

With a focus on built environment, the digital twin technology developed by a Singapore SME offers a suite of tools to model, analyse and continually optimise entire groups of buildings, portfolios, communities, cities and resource networks across their lifecycle, providing a truly scalable solution to decarbonise the built environment. Bridging the gap between the real world and simulation, the digital twin enables the energy efficient design and continuous operational optimisation of not just single but entire groups of buildings. The digital twin solution investigates operational problems using AI and machine learning, engaging the community feedback in real time. It improves operational decisions by understanding where to focus attention on and facilitate decision making by the building operators. The technology owner is seeking partnerships with large building portfolio owner, product developer, IoT solutions provider who can deploy the digital twin solution for their clients. The digital twin tools integrate physics-based simulation with 3D models, real-time operational data, machine learning and AI, to provide a digital twin solution for the built environment that is unique to any other in today’s market. The digital twin technology provides: Physics Enabled Simulation Climate Ready Master-planning Design & Retrofit to Zero-Carbon Standards Community Energy & Renewable Integration Operational & Community Dashboards Data Analysis from Physical & Virtual Sensors Real-Time Optimisation & Fault Detection The digital twin technology can be used in any built environment (e.g. universities, local authorities, commercial real estate, healthcare, manufacturing, cities). The solution can be used for singular buildings or scale up to a city, across any geographical scale, the tools link all aspects of every building’s lifecycle from design and construction right through to operation. The solution connects everyone from owners and occupants, to planners and community leaders, in a single collaborative environment. Digital twins are one of the fastest growing technology segments in the market. Fortune Business estimates the market to be USD 6.7bn with a CAGR of 40%. The growth potential coupled to the growing applications makes digital twins an enormous potential for this decade.  Fully scalable from a single building to an entire city, The digital twin technology goes beyond building information modelling to create a live digital twin which responds and behaves like its real world counterpart. Delivering the data-driven information needed to uncover significant energy, carbon, capital and operational savings, while taking account of resource use, transport, social and economic factors. Digital Twins, Decarbonization, Net-Zero Buildings, Zero Carbon, Sustainability Energy, Sensor, Network, Power Conversion, Power Quality & Energy Management, Green Building, Sensor, Network, Building Control & Optimisation, Environment, Clean Air & Water, Sensor, Network, Monitoring & Quality Control Systems, Sustainability, Low Carbon Economy

Recycling of lithium-ion battery material is becoming an increasing necessity and to execute that task in an environmentally friendly and cost-effective method is as important. The novel method of recycling spent battery material using a redox flow battery approach requires the solid spent battery material to react with liquid electrolyte in the tank. The proposed technology by a Singapore-based research team relates to an electrolyte tank filtration system designed to allow solid particles to freely mix and react with electrolyte in the tank of the flow battery system, while being filtered and prevented from entering the pump and cell stack. The holder is designed to be simply placed into and removed from the electrolyte tank, and subsequently, for the easy removal of the solid from the holder itself. This innovation will allow the continuous running of the flow battery system while changing the filter periodically. The research team anticipates that companies planning to utilise redox flow battery recycling method would require the use of such a filter system to reduce the downtime of the entire system. The team is seeking to collaborate with an industrial partner for further research and development of the filtration system and subsequent licensing of the technology for commercialisation. The electrolyte tank filtration system allows free mixing of electrolyte with solid reactants, while preventing the solid particles from entering the pump and cell with the electrolyte Flexibility in addition and removal of multiple filter holders Ease of removing filter paper and solid product from filter holder Able to run flow battery continuously without having to stop for filter removal, leading to no downtime of the system While this technology is designed specifically for the recycling of solid spent battery materials using the redox flow battery system, it can be adapted to be deployed in any flow battery applications that requires filtration of solids reactants from a liquid electrolyte. Based on a non-exhaustive secondary research by the team, there is no “state-of-the-art’ filtration system designed for redox flow battery used for battery material recycling. Filtration systems in the market are not specifically made for the purpose of recycling battery material in a flow battery and therefore do not come with the features and the advantages that come with the proposed technology. Present technology can only allow for such filtration batch by batch, causing stoppages and idle time for the entire flow cell system. Lithium battery, Material recycling, Flow battery, Filter design, Flow frame, Tank design Energy, Battery & SuperCapacitor, Waste Management & Recycling, Industrial Waste Management

Partial discharges (PDs) are early indicators of the deteriorating health condition of high-voltage electrical assets in power distribution networks. PDs are caused by localised dielectric breakdowns within assets such as generators, transformers, and switchgears. Left undetected, the health of the assets can deteriorate and lead to irreversible damage, posing safety hazards such as fire and explosion. Therefore, there is a need to detect and monitor PD events to ensure asset health and safety to extend the life time.  This technology offer is a compact PD sensor equipped with a fast detector which can be mounted on assets to detect and monitor PD events 24/7. The system integrates a wireless platform, allowing remote retrieval of information about the times of PD occurrences and source identifications (IDs). This information can be used to trace and identify PD emitting sources. By using the proposed technology to detect and monitor PD events, early signs of asset degradation can be identified. This allows necessary preventive measures to be taken to avoid unexpected failures and damages, saving costs associated with repair or replacement. Additionally, the technology enhances safety by minimizing the risk of fire and explosion caused by PD-related damages. Overall, the proposed technology helps ensure the health and safety of high-voltage electrical assets, while reducing costs and downtime associated with unexpected failures and damages. The main features of the technology offer are: A highly innovative solution that consists of a patented near-field PD sensor integrated with a high-speed detector. Can be powered by either a battery or an external power source, providing maximum convenience and versatility. Designed to work seamlessly with a wireless platform, enabling measurement data to be stored either on premises or in the cloud. Remote monitoring and data analytics capabilities allow users to quickly identify and troubleshoot issues in real-time, minimizing downtime and maximizing asset health and performance. The system's patented near-field PD sensor, high-speed detector/processing unit, and versatile power options make it the ideal choice for users seeking the highest levels of performance, reliability, and flexibility. The system can be further customised to monitor the health and performance of high-voltage electrical assets such as generators, transformers, and switchgears. Minimum size of sensor is 150mm * 150m * 8mm Size of the processing unit is 150mm * 90mm * 45mm Maximum power required by the system is 2W; it can be powered by a battery or adapter which can provide 5V voltage through USB type-C interface This technology offer is versatile and can be deployed in a wide range of different applications, such as, in high-voltage power transmission and distribution industries, especially for owners of high-voltage electrical machines and equipment providing critical services. The technology benefits: Semiconductor fabrication plants to ensure high-voltage electrical assets remain in peak condition, minimizing downtime and financial losses. Data centres to ensure reliable and efficient power supplies to operate effectively and deliver uninterrupted services to clients Public transportation systems such as, trains and subways, to ensure their safe and efficient operation. Hospital environments to provide reliable and efficient electrical assets that are critical for patient care and treatment Existing PD measurement systems in the market are deployed for periodic PD measurements, which is not real-time and may miss out early signs of insulation degradation of high-voltage equipment. These systems are sophisticated and good for comprehensive diagnostic and analysis, but they are too costly for large-scale deployment to provide 24/7 PD monitoring of multiple assets simultaneously. This technology offer is a low-cost, non-intrusive method which is scalable for deployment in a large-scale environment. The wireless platform allows remote monitoring of multiple assets at multiple sites from a dashboard. The data will be automatically collected and stored in the cloud for long-term analysis. Hence, this technology serves as a first-level PD detection and monitoring to identify a specific asset with degraded insulation issue and a more sophisticated PD measurement system can then be deployed for diagnostic purposes. The technology owner is keen to do R&D collaboration and licensing to high-voltage equipment manufacturers, and power system maintenance service providers. partial discharge, remote monitoring, high-voltage, near-field sensor Electronics, Sensors & Instrumentation, Energy, Sensor, Network, Power Conversion, Power Quality & Energy Management