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Pinku Kumar

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I am professional authors in medical science industry
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Patrizia D'Olivo

Henrik Grüttner

University of Southern Denmark

Mariska Janse van Rensburg

University of Pretoria

Md. Rakibul Islam

Fribourg University of Applied Sciences

Cheilene Cronje

Tshwane University of Technology

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Papers by Pinku Kumar

ECO Modular Retail

EcoMod: A Scalable, Modular, and Sustainable Point of Sale Display System for Global Retail, 2024

EcoMod is an innovative, scalable, and modular point of sale (POS) display system designed to rev... more EcoMod is an innovative, scalable, and modular point of sale
(POS) display system designed to revolutionize in-store marketing for Genomma Lab.
This system leverages a sustainable approach, addressing the inefficiencies and high
costs typically associated with conventional retail displays by creating a standardized,
reconfigurable solution that can be adapted across different products, trade channels,
and geographic regions.
The primary objective of EcoMod is to reduce material waste, minimize production costs,
and enhance flexibility in design while ensuring maximum consumer engagement
through visually appealing displays that maintain strong "stopping power." Our modular
design features standardized "blocks" that can be easily assembled, disassembled, and
reconfigured based on the specific needs of each retail setting, whether for end caps,
floor stands, sidekicks, shelf trays, or counter displays.
EcoMod focuses on a single base material—recycled, biodegradable, or renewable
materials like bamboo fiberboard or 100% post-consumer recycled plastic. This decision
is key to creating a more sustainable production and lifecycle model for POS displays.
The design is cost-effective, reduces environmental impact, and can be mass-produced
to meet Genomma Lab’s high-quantity needs. Our approach aligns with circular economy
principles by promoting the reusability of POS materials across multiple campaigns,
reducing the number of displays that end up in landfills.

Eco Repel Toilet

EcoRepel Toilet , 2024

EcoRepel is a biodegradable, plant-based surface treatment that creates a hydrophobic, self-clean... more EcoRepel is a biodegradable, plant-based surface treatment that creates a hydrophobic, self-cleaning layer on toilet bowl surfaces, preventing the adhesion of common stains like limescale, fecal matter, and urine scale. The solution is applied in a simple one-step process, either through a drop-in toilet cleaner or spray, and bonds with the ceramic surface. Once applied, EcoRepel minimizes the need for frequent cleaning and maintains a cleaner toilet for extended periods by repelling water and waste buildup. The biodegradable chemistry ensures environmental sustainability, aligning with modern eco-conscious consumer demands Solution Description: EcoRepel is a next-generation surface modification technology derived from renewable, plant-based sources. Its biodegradable formulation is designed to create a durable hydrophobic coating on the toilet bowl surface, making it highly resistant to stains. This solution draws inspiration from biomimetic surfaces found in nature, such as lotus leaves, known for their self-cleaning properties through water repellency.

Eco Heat Transformer

Eco Heat transformer, 2024

The EcoHeat Transformer is an innovative modular system designed to recover residual low-temperat... more The EcoHeat Transformer is an innovative modular system designed to recover residual low-temperature heat (40-60°C) from industrial processes, transforming it into usable energy forms. By integrating advanced thermoelectric materials with a patented heat exchange mechanism, the system ensures efficient energy conversion with minimal investment and operational disruption. This solution not only monetizes the waste heat by converting it to electricity or thermal energy for local reuse but also contributes to significant reductions in greenhouse gas (GHG) emissions and water usage. The plug-and-play design guarantees easy installation without affecting upstream operations, making it suitable for large-scale applications across various industrial sectors

Redispersible Microsilica

Redispersible Microsilica, 2024

This solution proposes the use of freeze-granulation, combined with a carefully optimized additiv... more This solution proposes the use of freeze-granulation, combined with a carefully optimized additive package, to achieve a scalable, efficient, and environmentally friendly drying process for silica nanoparticles (SNPs). The addition of tailored dispersants and binders prevents aggregation during freezing and sublimation drying, producing granules that are easily redispersible in water while maintaining the original particle size, shape, and surface area. This process meets the technical and economic targets, making it suitable for industrial-scale application

Solution Title: "Enzymatic Nano-Remediation: A Targeted Approach for Reducing PCB Concentrations and Toxicity in Soil and Sediment

Solution Title: "Enzymatic Nano-Remediation: A Targeted Approach for Reducing PCB Concentrations and Toxicity in Soil and Sediment, 2024

Our innovative solution, Enzymatic Nano-Remediation, targets the significant reduction of polychl... more Our innovative solution, Enzymatic Nano-Remediation, targets the significant reduction of polychlorinated biphenyls (PCBs) in soil and sediment through a two-pronged approach: lowering both the concentrations and bioavailability of these hazardous compounds. This method utilizes specially selected enzymes for the degradation of PCBs and biodegradable additives to immobilize residual contaminants. Our technology is designed to meet EPA requirements for cost-effectiveness, minimal hazardous by-products, and compliance with environmental regulations. By effectively addressing PCB concentrations and their bioavailability, our solution promotes ecological recovery and ensures safer environments for communities Solution Description: 1. Technology Overview

Deep Eutectic Solvents (DES) for Enhanced Phenol Capture from Gas Streams

Deep Eutectic Solvents (DES) for Enhanced Phenol Capture from Gas Streams, 2024

This proposal introduces the innovative use of Deep Eutectic Solvents(DES) as a novel approach fo... more This proposal introduces the innovative use of Deep Eutectic Solvents(DES) as a novel approach for capturing phenol and its derivatives fromgas systems. DES, formed by mixing a hydrogen bond acceptor (HBA) anda hydrogen bond donor (HBD), exhibits superior solubility properties and ahigh affinity for phenolic compounds. By leveraging the uniquecharacteristics of DES, this solution aims to reduce phenol concentrationsin gas systems by at least seven-fold, addressing the limitations oftraditional methods like activated carbon and solvent absorption. Theproposed DES formulations can be applied as gels, pastes, or liquids,making them adaptable for various industrial applications. Additionally,their ability to capture not only phenol but also other related compoundssuch as cresols enhances their utility in diverse gas filtration system

Nano-Engineered Adsorbent and Electrochemical Hybrid Process for Cost-Effective Lithium Extraction from High-Salinity Brines

Nano-Engineered Adsorbent and Electrochemical Hybrid Process for Cost-Effective Lithium Extraction from High-Salinity Brines, 2024

This solution proposes a novel Direct Lithium Extraction (DLE) process that integrates nano-engin... more This solution proposes a novel Direct Lithium Extraction (DLE)
process that integrates nano-engineered adsorbent materials with an electrochemical
hybrid purification system. The proposed adsorbent offers high selectivity for lithium
ions in high-salinity brines while eliminating divalent and monovalent impurities in a
single step. The electrochemical system further concentrates the lithium-rich solution,
enabling direct crystallization into battery-grade lithium carbonate or lithium hydroxide
without the need for extensive downstream purification. By optimizing adsorption
efficiency and combining it with an energy-efficient electrochemical stage, the process
aims to reduce the cost of production to below $10,000 per ton of Lithium Carbonate
Equivalent (LCE) while maintaining the required purity level of 99.5% or higher.

Solution Title: "Dual Crystal Growth Modulation Using Ion-Specific Inhibitors and Evaporation Control for Efficient Carnallite Extraction

Dual Crystal Growth Modulation Using Ion-Specific Inhibitors and Evaporation Control for Efficient Carnallite Extraction, 2024

This solution proposes a novel approach to modify the crystal sizes of Carnallite and Halite in D... more This solution proposes a novel approach to modify the crystal sizes of Carnallite and Halite in Dead Sea evaporation ponds through a combination of ion-specific growth inhibitors and precise evaporation control. The technology promotes the selective enlargement of Carnallite crystals (≥ 1 mm) while restricting Halite crystals to a size of < 0.2 mm. By integrating sustainable, scalable additives and optimizing the evaporation process, the solution enhances the separation efficiency of Carnallite from Halite, reducing processing costs and improving potash recovery Solution Description: The challenge of separating Carnallite (KCl•MgCl₂•6H₂O) and Halite (NaCl) in Dead Sea water evaporation ponds has long hindered efficient potash extraction due to the co-precipitation of Halite. This solution addresses the problem by introducing two key components:

AI Enhanced Grid Optimization

AI Enhanced Grid Optimization, 2024

This solution proposes an AI-driven framework designed to optimize grid operations, focusing on ... more This solution proposes an AI-driven framework designed to
optimize grid operations, focusing on renewable integration, load forecasting,
cybersecurity, and incident management. The system leverages machine learning, large
language models (LLMs), and computer vision to create a multi-phase AI-based platform
that anticipates challenges, mitigates risks, and enhances grid stability. By combining
predictive analytics, real-time data monitoring, and adaptive algorithms, the proposed
solution enables dynamic load balancing, predictive maintenance, and cybersecurity
resilience across MISO’s grid.

Solar powered irrigation (1)

Solar-Powered Irrigation System with Integrated Water Conservation, 2024

Solar-Powered Irrigation System with Integrated Water Conservation Our Solar-Powered Irrigation S... more Solar-Powered Irrigation System with Integrated Water Conservation
Our Solar-Powered Irrigation System with Integrated Water Conservation is designed to address the growing challenges of water scarcity, energy costs, and environmental impact in agriculture. By utilizing solar energy and precision irrigation techniques, this system optimizes water usage, reduces reliance on fossil fuels, and minimizes greenhouse gas emissions.

Key features include:

High-efficiency solar panels that power irrigation pumps, supported by an integrated battery energy storage system for continuous operation.
Precision irrigation techniques, such as drip irrigation and soil moisture sensors, to reduce water waste and enhance crop yield.
Water conservation measures, including rainwater harvesting and the reuse of treated wastewater, to minimize dependence on freshwater sources.
This system offers a sustainable, scalable, and cost-effective solution for farmers, particularly in regions like Northeast Syria, where water resources and energy are limited. It addresses the critical need for efficient irrigation and energy solutions in agriculture while promoting environmental stewardship and long-term sustainability

Debiopharm challenge

Hepatic Bypass: A Novel Strategy for Enhanced Tumor Targeting with Lipid-Based Nanocarriers, 2024

This solution introduces an innovative approach to reducing liver uptake of lipid-based nanocarri... more This solution introduces an innovative approach to reducing liver uptake of lipid-based nanocarriers (LNCs) by utilizing a novel surface modification technique. By incorporating a specific ligand that binds to receptors overexpressed on tumor cells, the LNCs are actively redirected to the tumor microenvironment, effectively bypassing the liver. This targeted delivery strategy maximizes drug concentration at the tumor site, enhancing therapeutic efficacy and minimizing systemic toxicity

Solution Title: PolySAFE Food-Grade Antistatic Agent for Safe & Sustainable Medical Packaging

Solution Title: PolySAFE Food-Grade Antistatic Agent for Safe & Sustainable Medical Packaging, 2024

is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in ... more is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in medical and food packaging. It combines glycerol monostearate (GMS) and citric acid to offer excellent antistatic properties, ensuring efficient charge dissipation, non-toxicity, and compatibility with existing equipment. PolySAFE's formulation meets stringent safety standards, making it a robust, production-ready solution for the packaging industry. Solution Description: PolySAFE is an effective and food-grade replacement for Atmer 163, designed for use in sensitive applications such as food, beverage, and medical packaging. It combines two commercially available, food-grade antistatic agents: Glycerol Monostearate (GMS) and Citric Acid.

Solution Title: PolySAFE Food-Grade Antistatic Agent for Safe & Sustainable Medical Packaging

is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in ... more is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in medical and food packaging. It combines glycerol monostearate (GMS) and citric acid to offer excellent antistatic properties, ensuring efficient charge dissipation, non-toxicity, and compatibility with existing equipment. PolySAFE's formulation meets stringent safety standards, making it a robust, production-ready solution for the packaging industry. Solution Description: PolySAFE is an effective and food-grade replacement for Atmer 163, designed for use in sensitive applications such as food, beverage, and medical packaging. It combines two commercially available, food-grade antistatic agents: Glycerol Monostearate (GMS) and Citric Acid. 1] Glycerol Monostearate (GMS) Function: Primary Antistatic Agent • Role in Process: GMS serves as the main antistatic agent in the polymerization process. Its primary function is to dissipate electrostatic charges that accumulate during the polymerization of propylene. This helps prevent issues such as fouling of the reactor and formation of polymer agglomerates Benefits: 1. Meets FDA and EU Food Contact Regulations: ○ Safety Compliance: GMS is recognized as safe for use in food contact applications, complying with both FDA and EU regulations. This ensures that GMS can be used in the production of packaging materials for food, beverages, and medical products without posing a risk to health. 2. Excellent Antistatic Performance: ○ Performance Comparison: GMS provides antistatic performance that is comparable to or even superior to Atmer 163. It effectively reduces static charge buildup, which is crucial for maintaining smooth operation and preventing issues such as reactor fouling. 3. Minimal Migration into the Final Product: ○ Product Safety: GMS has a low migration rate into the final polymer product, ensuring that it does not adversely affect the safety or quality of the packaging. This characteristic is important for meeting regulatory standards and ensuring that the final product is safe for sensitive applications. 4. Non-Reactive with the Catalyst: ○ Process Integrity: Unlike some antistatic agents, GMS does not interfere with the polymerization catalyst (Ziegler-Natta catalyst). This ensures that the polymerization process remains efficient and effective, without unwanted side reactions or impacts on the final polymer quality. 5. Available at Industrial Scale: ○ Commercial Availability: GMS is readily available in industrial quantities, making it a practical and scalable solution for large-scale polymerization processes. Its availability at an industrial scale ensures that it can be integrated into existing production systems without supply issues Conclusion: GMS is an effective solution to the challenge of finding a food-grade antistatic agent. Its compliance with safety regulations, excellent performance, minimal migration, non-reactivity with the catalyst, and availability at an industrial scale make it a suitable and reliable replacement for Atmer 163 in the production of food, beverage, and medical packaging. 2] Citric Acid Function: Secondary antistatic and catalyst termination agent : Citric Acid was selected as a secondary component in the proposed solution for several key reasons, addressing the challenge of finding a suitable food-grade antistatic agent. Here's how Citric Acid effectively meets the criteria: Citric Acid Function: Secondary Antistatic and Catalyst Termination Agent • Role in Process: Citric Acid serves dual functions: it acts as a secondary antistatic agent and as a catalyst termination agent. It supports the primary antistatic action of Glycerol Monostearate (GMS) and helps to terminate surface polymerization reactions by interacting with the Ziegler-Natta catalyst. Benefits: 1. Meets FDA and EU Food Contact Regulations: ○ Safety Compliance: Citric Acid is approved for use in food contact applications by both the FDA and EU. This ensures that it is safe for inclusion in packaging materials for food, beverages, and medical products, aligning with regulatory standards for these sensitive applications. 2. Effective in Terminating Surface Polymerization: ○ Reactor Efficiency: Citric Acid reacts with the Ziegler-Natta catalyst on the surface of the polymer granules. This reaction helps terminate the surface polymerization, preventing the buildup of polymer on reactor walls and mitigating fouling issues. This contributes to a smoother and more efficient production process. 3. Enhances the Effectiveness of GMS: ○ Synergistic Effect: When used in combination with GMS, Citric Acid enhances the overall antistatic and process control effectiveness. The dual action of both agents ensures more effective charge dissipation and surface polymerization control, improving process stability and product quality 1. Minimal Migration into the Final Product: ○ Product Safety: Citric Acid has a low migration rate, which means it does not significantly leach into the final polymer product. This characteristic ensures that the final packaging material remains safe for food and medical applications, meeting necessary safety and regulatory standards. 2. Available at Industrial Scale: ○ Commercial Availability: Citric Acid is widely available in large quantities, making it a practical choice for large-scale production. Its availability ensures that it can be easily sourced and integrated into existing production systems without issues related to supply or scalability. Conclusion: Citric Acid complements Glycerol Monostearate (GMS) by providing essential secondary antistatic properties and terminating surface polymerization reactions. Its compliance with food-grade regulations, effectiveness in process control, synergy with GMS, minimal migration into the final product, and availability at an industrial scale make it a suitable and valuable component in the proposed PolySAFE solution for replacing Atmer 163. OUR SOLUTION PolySAFE Works: PolySAFE effectively addresses the challenge of finding a food-grade antistatic agent by utilizing a combination of Glycerol Monostearate (GMS) and Citric Acid. How PolySAFE Works: 1. Antistatic Properties: ○ Role of GMS: Glycerol Monostearate (GMS) functions as the primary antistatic agent in the PolySAFE solution. It effectively reduces the buildup of static electricity during the polymerization process. By mitigating static charge accumulation, GMS prevents the formation of electrostatic attractions that can lead to polymer agglomeration and fouling of the reactor equipment. This ensures smoother operation of the polymerization process and minimizes the need for costly downtime and maintenance. 2. Catalyst Termination: ○ Role of Citric Acid: Citric Acid serves as a secondary antistatic agent and plays a crucial role in terminating surface polymerization reactions. During the polymerization process, Citric Acid reacts with the Ziegler-Natta catalyst on the surface of the polymer granules. This reaction effectively stops further polymerization on the granule surfaces, thereby reducing the formation of excess polymer on reactor walls. By controlling surface polymerization, Citric Acid helps maintain a clean reactor environment, reduces fouling, and ensures a more efficient and continuous production process Explanation of the Solution: • Combining Effects: The synergy between GMS and Citric Acid in PolySAFE enhances the overall effectiveness of the solution. GMS addresses static charge issues, while Citric Acid manages surface 5] Solution Overview-detail the features of your solution and how they address the Solution Requirements (500 words, there is space to add more in the summary field below, and to add any appropriate supporting data, diagrams, etc.).

ECO Modular Retail

EcoMod: A Scalable, Modular, and Sustainable Point of Sale Display System for Global Retail, 2024

EcoMod is an innovative, scalable, and modular point of sale (POS) display system designed to rev... more EcoMod is an innovative, scalable, and modular point of sale
(POS) display system designed to revolutionize in-store marketing for Genomma Lab.
This system leverages a sustainable approach, addressing the inefficiencies and high
costs typically associated with conventional retail displays by creating a standardized,
reconfigurable solution that can be adapted across different products, trade channels,
and geographic regions.
The primary objective of EcoMod is to reduce material waste, minimize production costs,
and enhance flexibility in design while ensuring maximum consumer engagement
through visually appealing displays that maintain strong "stopping power." Our modular
design features standardized "blocks" that can be easily assembled, disassembled, and
reconfigured based on the specific needs of each retail setting, whether for end caps,
floor stands, sidekicks, shelf trays, or counter displays.
EcoMod focuses on a single base material—recycled, biodegradable, or renewable
materials like bamboo fiberboard or 100% post-consumer recycled plastic. This decision
is key to creating a more sustainable production and lifecycle model for POS displays.
The design is cost-effective, reduces environmental impact, and can be mass-produced
to meet Genomma Lab’s high-quantity needs. Our approach aligns with circular economy
principles by promoting the reusability of POS materials across multiple campaigns,
reducing the number of displays that end up in landfills.

Eco Repel Toilet

EcoRepel Toilet , 2024

EcoRepel is a biodegradable, plant-based surface treatment that creates a hydrophobic, self-clean... more EcoRepel is a biodegradable, plant-based surface treatment that creates a hydrophobic, self-cleaning layer on toilet bowl surfaces, preventing the adhesion of common stains like limescale, fecal matter, and urine scale. The solution is applied in a simple one-step process, either through a drop-in toilet cleaner or spray, and bonds with the ceramic surface. Once applied, EcoRepel minimizes the need for frequent cleaning and maintains a cleaner toilet for extended periods by repelling water and waste buildup. The biodegradable chemistry ensures environmental sustainability, aligning with modern eco-conscious consumer demands Solution Description: EcoRepel is a next-generation surface modification technology derived from renewable, plant-based sources. Its biodegradable formulation is designed to create a durable hydrophobic coating on the toilet bowl surface, making it highly resistant to stains. This solution draws inspiration from biomimetic surfaces found in nature, such as lotus leaves, known for their self-cleaning properties through water repellency.

Eco Heat Transformer

Eco Heat transformer, 2024

The EcoHeat Transformer is an innovative modular system designed to recover residual low-temperat... more The EcoHeat Transformer is an innovative modular system designed to recover residual low-temperature heat (40-60°C) from industrial processes, transforming it into usable energy forms. By integrating advanced thermoelectric materials with a patented heat exchange mechanism, the system ensures efficient energy conversion with minimal investment and operational disruption. This solution not only monetizes the waste heat by converting it to electricity or thermal energy for local reuse but also contributes to significant reductions in greenhouse gas (GHG) emissions and water usage. The plug-and-play design guarantees easy installation without affecting upstream operations, making it suitable for large-scale applications across various industrial sectors

Redispersible Microsilica

Redispersible Microsilica, 2024

This solution proposes the use of freeze-granulation, combined with a carefully optimized additiv... more This solution proposes the use of freeze-granulation, combined with a carefully optimized additive package, to achieve a scalable, efficient, and environmentally friendly drying process for silica nanoparticles (SNPs). The addition of tailored dispersants and binders prevents aggregation during freezing and sublimation drying, producing granules that are easily redispersible in water while maintaining the original particle size, shape, and surface area. This process meets the technical and economic targets, making it suitable for industrial-scale application

Solution Title: "Enzymatic Nano-Remediation: A Targeted Approach for Reducing PCB Concentrations and Toxicity in Soil and Sediment

Solution Title: "Enzymatic Nano-Remediation: A Targeted Approach for Reducing PCB Concentrations and Toxicity in Soil and Sediment, 2024

Our innovative solution, Enzymatic Nano-Remediation, targets the significant reduction of polychl... more Our innovative solution, Enzymatic Nano-Remediation, targets the significant reduction of polychlorinated biphenyls (PCBs) in soil and sediment through a two-pronged approach: lowering both the concentrations and bioavailability of these hazardous compounds. This method utilizes specially selected enzymes for the degradation of PCBs and biodegradable additives to immobilize residual contaminants. Our technology is designed to meet EPA requirements for cost-effectiveness, minimal hazardous by-products, and compliance with environmental regulations. By effectively addressing PCB concentrations and their bioavailability, our solution promotes ecological recovery and ensures safer environments for communities Solution Description: 1. Technology Overview

Deep Eutectic Solvents (DES) for Enhanced Phenol Capture from Gas Streams

Deep Eutectic Solvents (DES) for Enhanced Phenol Capture from Gas Streams, 2024

This proposal introduces the innovative use of Deep Eutectic Solvents(DES) as a novel approach fo... more This proposal introduces the innovative use of Deep Eutectic Solvents(DES) as a novel approach for capturing phenol and its derivatives fromgas systems. DES, formed by mixing a hydrogen bond acceptor (HBA) anda hydrogen bond donor (HBD), exhibits superior solubility properties and ahigh affinity for phenolic compounds. By leveraging the uniquecharacteristics of DES, this solution aims to reduce phenol concentrationsin gas systems by at least seven-fold, addressing the limitations oftraditional methods like activated carbon and solvent absorption. Theproposed DES formulations can be applied as gels, pastes, or liquids,making them adaptable for various industrial applications. Additionally,their ability to capture not only phenol but also other related compoundssuch as cresols enhances their utility in diverse gas filtration system

Nano-Engineered Adsorbent and Electrochemical Hybrid Process for Cost-Effective Lithium Extraction from High-Salinity Brines

Nano-Engineered Adsorbent and Electrochemical Hybrid Process for Cost-Effective Lithium Extraction from High-Salinity Brines, 2024

This solution proposes a novel Direct Lithium Extraction (DLE) process that integrates nano-engin... more This solution proposes a novel Direct Lithium Extraction (DLE)
process that integrates nano-engineered adsorbent materials with an electrochemical
hybrid purification system. The proposed adsorbent offers high selectivity for lithium
ions in high-salinity brines while eliminating divalent and monovalent impurities in a
single step. The electrochemical system further concentrates the lithium-rich solution,
enabling direct crystallization into battery-grade lithium carbonate or lithium hydroxide
without the need for extensive downstream purification. By optimizing adsorption
efficiency and combining it with an energy-efficient electrochemical stage, the process
aims to reduce the cost of production to below $10,000 per ton of Lithium Carbonate
Equivalent (LCE) while maintaining the required purity level of 99.5% or higher.

Solution Title: "Dual Crystal Growth Modulation Using Ion-Specific Inhibitors and Evaporation Control for Efficient Carnallite Extraction

Dual Crystal Growth Modulation Using Ion-Specific Inhibitors and Evaporation Control for Efficient Carnallite Extraction, 2024

This solution proposes a novel approach to modify the crystal sizes of Carnallite and Halite in D... more This solution proposes a novel approach to modify the crystal sizes of Carnallite and Halite in Dead Sea evaporation ponds through a combination of ion-specific growth inhibitors and precise evaporation control. The technology promotes the selective enlargement of Carnallite crystals (≥ 1 mm) while restricting Halite crystals to a size of < 0.2 mm. By integrating sustainable, scalable additives and optimizing the evaporation process, the solution enhances the separation efficiency of Carnallite from Halite, reducing processing costs and improving potash recovery Solution Description: The challenge of separating Carnallite (KCl•MgCl₂•6H₂O) and Halite (NaCl) in Dead Sea water evaporation ponds has long hindered efficient potash extraction due to the co-precipitation of Halite. This solution addresses the problem by introducing two key components:

AI Enhanced Grid Optimization

AI Enhanced Grid Optimization, 2024

This solution proposes an AI-driven framework designed to optimize grid operations, focusing on ... more This solution proposes an AI-driven framework designed to
optimize grid operations, focusing on renewable integration, load forecasting,
cybersecurity, and incident management. The system leverages machine learning, large
language models (LLMs), and computer vision to create a multi-phase AI-based platform
that anticipates challenges, mitigates risks, and enhances grid stability. By combining
predictive analytics, real-time data monitoring, and adaptive algorithms, the proposed
solution enables dynamic load balancing, predictive maintenance, and cybersecurity
resilience across MISO’s grid.

Solar powered irrigation (1)

Solar-Powered Irrigation System with Integrated Water Conservation, 2024

Solar-Powered Irrigation System with Integrated Water Conservation Our Solar-Powered Irrigation S... more Solar-Powered Irrigation System with Integrated Water Conservation
Our Solar-Powered Irrigation System with Integrated Water Conservation is designed to address the growing challenges of water scarcity, energy costs, and environmental impact in agriculture. By utilizing solar energy and precision irrigation techniques, this system optimizes water usage, reduces reliance on fossil fuels, and minimizes greenhouse gas emissions.

Key features include:

High-efficiency solar panels that power irrigation pumps, supported by an integrated battery energy storage system for continuous operation.
Precision irrigation techniques, such as drip irrigation and soil moisture sensors, to reduce water waste and enhance crop yield.
Water conservation measures, including rainwater harvesting and the reuse of treated wastewater, to minimize dependence on freshwater sources.
This system offers a sustainable, scalable, and cost-effective solution for farmers, particularly in regions like Northeast Syria, where water resources and energy are limited. It addresses the critical need for efficient irrigation and energy solutions in agriculture while promoting environmental stewardship and long-term sustainability

Debiopharm challenge

Hepatic Bypass: A Novel Strategy for Enhanced Tumor Targeting with Lipid-Based Nanocarriers, 2024

This solution introduces an innovative approach to reducing liver uptake of lipid-based nanocarri... more This solution introduces an innovative approach to reducing liver uptake of lipid-based nanocarriers (LNCs) by utilizing a novel surface modification technique. By incorporating a specific ligand that binds to receptors overexpressed on tumor cells, the LNCs are actively redirected to the tumor microenvironment, effectively bypassing the liver. This targeted delivery strategy maximizes drug concentration at the tumor site, enhancing therapeutic efficacy and minimizing systemic toxicity

Solution Title: PolySAFE Food-Grade Antistatic Agent for Safe & Sustainable Medical Packaging

Solution Title: PolySAFE Food-Grade Antistatic Agent for Safe & Sustainable Medical Packaging, 2024

is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in ... more is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in medical and food packaging. It combines glycerol monostearate (GMS) and citric acid to offer excellent antistatic properties, ensuring efficient charge dissipation, non-toxicity, and compatibility with existing equipment. PolySAFE's formulation meets stringent safety standards, making it a robust, production-ready solution for the packaging industry. Solution Description: PolySAFE is an effective and food-grade replacement for Atmer 163, designed for use in sensitive applications such as food, beverage, and medical packaging. It combines two commercially available, food-grade antistatic agents: Glycerol Monostearate (GMS) and Citric Acid.

Solution Title: PolySAFE Food-Grade Antistatic Agent for Safe & Sustainable Medical Packaging

is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in ... more is a high-conductivity, non-toxic antistatic agent tailored for polymerization processes used in medical and food packaging. It combines glycerol monostearate (GMS) and citric acid to offer excellent antistatic properties, ensuring efficient charge dissipation, non-toxicity, and compatibility with existing equipment. PolySAFE's formulation meets stringent safety standards, making it a robust, production-ready solution for the packaging industry. Solution Description: PolySAFE is an effective and food-grade replacement for Atmer 163, designed for use in sensitive applications such as food, beverage, and medical packaging. It combines two commercially available, food-grade antistatic agents: Glycerol Monostearate (GMS) and Citric Acid. 1] Glycerol Monostearate (GMS) Function: Primary Antistatic Agent • Role in Process: GMS serves as the main antistatic agent in the polymerization process. Its primary function is to dissipate electrostatic charges that accumulate during the polymerization of propylene. This helps prevent issues such as fouling of the reactor and formation of polymer agglomerates Benefits: 1. Meets FDA and EU Food Contact Regulations: ○ Safety Compliance: GMS is recognized as safe for use in food contact applications, complying with both FDA and EU regulations. This ensures that GMS can be used in the production of packaging materials for food, beverages, and medical products without posing a risk to health. 2. Excellent Antistatic Performance: ○ Performance Comparison: GMS provides antistatic performance that is comparable to or even superior to Atmer 163. It effectively reduces static charge buildup, which is crucial for maintaining smooth operation and preventing issues such as reactor fouling. 3. Minimal Migration into the Final Product: ○ Product Safety: GMS has a low migration rate into the final polymer product, ensuring that it does not adversely affect the safety or quality of the packaging. This characteristic is important for meeting regulatory standards and ensuring that the final product is safe for sensitive applications. 4. Non-Reactive with the Catalyst: ○ Process Integrity: Unlike some antistatic agents, GMS does not interfere with the polymerization catalyst (Ziegler-Natta catalyst). This ensures that the polymerization process remains efficient and effective, without unwanted side reactions or impacts on the final polymer quality. 5. Available at Industrial Scale: ○ Commercial Availability: GMS is readily available in industrial quantities, making it a practical and scalable solution for large-scale polymerization processes. Its availability at an industrial scale ensures that it can be integrated into existing production systems without supply issues Conclusion: GMS is an effective solution to the challenge of finding a food-grade antistatic agent. Its compliance with safety regulations, excellent performance, minimal migration, non-reactivity with the catalyst, and availability at an industrial scale make it a suitable and reliable replacement for Atmer 163 in the production of food, beverage, and medical packaging. 2] Citric Acid Function: Secondary antistatic and catalyst termination agent : Citric Acid was selected as a secondary component in the proposed solution for several key reasons, addressing the challenge of finding a suitable food-grade antistatic agent. Here's how Citric Acid effectively meets the criteria: Citric Acid Function: Secondary Antistatic and Catalyst Termination Agent • Role in Process: Citric Acid serves dual functions: it acts as a secondary antistatic agent and as a catalyst termination agent. It supports the primary antistatic action of Glycerol Monostearate (GMS) and helps to terminate surface polymerization reactions by interacting with the Ziegler-Natta catalyst. Benefits: 1. Meets FDA and EU Food Contact Regulations: ○ Safety Compliance: Citric Acid is approved for use in food contact applications by both the FDA and EU. This ensures that it is safe for inclusion in packaging materials for food, beverages, and medical products, aligning with regulatory standards for these sensitive applications. 2. Effective in Terminating Surface Polymerization: ○ Reactor Efficiency: Citric Acid reacts with the Ziegler-Natta catalyst on the surface of the polymer granules. This reaction helps terminate the surface polymerization, preventing the buildup of polymer on reactor walls and mitigating fouling issues. This contributes to a smoother and more efficient production process. 3. Enhances the Effectiveness of GMS: ○ Synergistic Effect: When used in combination with GMS, Citric Acid enhances the overall antistatic and process control effectiveness. The dual action of both agents ensures more effective charge dissipation and surface polymerization control, improving process stability and product quality 1. Minimal Migration into the Final Product: ○ Product Safety: Citric Acid has a low migration rate, which means it does not significantly leach into the final polymer product. This characteristic ensures that the final packaging material remains safe for food and medical applications, meeting necessary safety and regulatory standards. 2. Available at Industrial Scale: ○ Commercial Availability: Citric Acid is widely available in large quantities, making it a practical choice for large-scale production. Its availability ensures that it can be easily sourced and integrated into existing production systems without issues related to supply or scalability. Conclusion: Citric Acid complements Glycerol Monostearate (GMS) by providing essential secondary antistatic properties and terminating surface polymerization reactions. Its compliance with food-grade regulations, effectiveness in process control, synergy with GMS, minimal migration into the final product, and availability at an industrial scale make it a suitable and valuable component in the proposed PolySAFE solution for replacing Atmer 163. OUR SOLUTION PolySAFE Works: PolySAFE effectively addresses the challenge of finding a food-grade antistatic agent by utilizing a combination of Glycerol Monostearate (GMS) and Citric Acid. How PolySAFE Works: 1. Antistatic Properties: ○ Role of GMS: Glycerol Monostearate (GMS) functions as the primary antistatic agent in the PolySAFE solution. It effectively reduces the buildup of static electricity during the polymerization process. By mitigating static charge accumulation, GMS prevents the formation of electrostatic attractions that can lead to polymer agglomeration and fouling of the reactor equipment. This ensures smoother operation of the polymerization process and minimizes the need for costly downtime and maintenance. 2. Catalyst Termination: ○ Role of Citric Acid: Citric Acid serves as a secondary antistatic agent and plays a crucial role in terminating surface polymerization reactions. During the polymerization process, Citric Acid reacts with the Ziegler-Natta catalyst on the surface of the polymer granules. This reaction effectively stops further polymerization on the granule surfaces, thereby reducing the formation of excess polymer on reactor walls. By controlling surface polymerization, Citric Acid helps maintain a clean reactor environment, reduces fouling, and ensures a more efficient and continuous production process Explanation of the Solution: • Combining Effects: The synergy between GMS and Citric Acid in PolySAFE enhances the overall effectiveness of the solution. GMS addresses static charge issues, while Citric Acid manages surface 5] Solution Overview-detail the features of your solution and how they address the Solution Requirements (500 words, there is space to add more in the summary field below, and to add any appropriate supporting data, diagrams, etc.).