Ai Engineering S.r.l. | Ai Studio’s Post

Today we are pleased to announce that SOLAR MEMS has been awarded the 𝗜𝗠𝗔𝗚𝗜𝗡𝗔 project, supported by the Spanish Ministerio de Industria, Comercio y Turismo ⁣ W𝗵𝗮𝘁 𝗱𝗼𝗲𝘀 𝘁𝗵𝗶𝘀 𝗽𝗿𝗼𝗷𝗲𝗰𝘁 𝗰𝗼𝗻𝘀𝗶𝘀𝘁 𝗼𝗳?⁣ ⁣ IMAGINA aims to investigate the design, development and implementation of a set of innovative Artificial Intelligence tools.⁣ The innovation is that these tools will be applied for the first time to certain tests and processes based on image analysis, in which human visual inspection currently plays a unique and fundamental role.⁣ ⁣ To this end, a novel prototype will be developed based on the combined application of Computer Vision and Artificial Intelligence techniques to automate and create new capabilities in different use cases such as:⁣ ⁣ - Identification and quantification of corroded areas in bonded joints of aluminium specimens, in BLC (Bond Line Corrosion) bond line corrosion quantification tests.⁣ - Inspection of the surface soldering processes of electronic components on Printed Circuit Boards, specifically SMD (Surface Mount Device) and Flat-pack soldering for space applications.⁣ ⁣ 𝗧𝗵𝗮𝗻𝗸 𝘆𝗼𝘂 𝗳𝗼𝗿 𝘆𝗼𝘂𝗿 𝗰𝗼𝗻𝗳𝗶𝗱𝗲𝗻𝗰𝗲 𝗶𝗻 𝗦𝗢𝗟𝗔𝗥 𝗠𝗘𝗠𝗦⁣ ⁣ #AEIMAGINA ANDALUCÍA AEROSPACE Cluster Empresarial The CT Engineering Group Titania Ensayos y Proyectos Industriales SOLAR MEMS

Dr. Walid EL FEZZANI, with the support of the sustainability center at GULF University Bahrain, has developed the NFC ID card project. This innovative card can be utilized for both personal and company purposes, eliminating the need for traditional printed identification. With NFC technology, individuals can store all their personal information, including name, phone number, address, location, and social media profiles, on the card. By simply tapping the card on a smart phone, the information is easily transferred and stored on the device. The NFC ID card is a sustainable solution, promoting a paperless environment while reducing carbon emissions, effluent discharges, and waste production, contributing to achieving SDG 13 (Climate Action) and SDG 15 (Life on Land). Additionally, the adoption of NFC technology aligns with SDG 9 (Industry, Innovation and Infrastructure) by encouraging sustainable entrepreneurship practices and promoting technological advancements in the fast-paced digital landscape. By using NFC business cards, inclusivity and accessibility are enhanced, making it easier for people of diverse backgrounds to exchange information. This supports SDG 10 (Reduced Inequalities) by providing equal opportunities for networking and career growth through the use of cutting-edge technology. Gulf University Re Sustainability Limited @

battery power backup magnetic technology system flywheel device. it is reducing motor current ampere and warming by rotating magnetic field. it is a free magnetic friction.... It sounds like you're describing a flywheel-based energy storage system with magnetic bearings. These systems use rotating flywheels to store energy, which can then be used to provide backup power or supplement electrical systems. The magnetic bearings flywheel reduce friction and allow for efficient energy storage and retrieval. It's an innovative technology with potential benefits for various applications, including reducing electric vehicles motor current and minimizing warming. Gujarat technology ahemdabad Gujarat India

Rail Vehicle Turning Simulation using universal mechanism software Curve simulation is a crucial aspect of the dynamics of rail vehicles, aimed at evaluating the performance and safety of the vehicle against derailment risks. The critical condition typically analyzed in this simulation is the presence of track twist on the curve, which can cause instability and increase the risk of accidents. Through curve simulation, engineers can identify and address potential issues in the design and operation of both the track and rail vehicles, thereby enhancing the safety and efficiency of the rail transportation system. The track twist value simulated is 5% with a small curve radius of 150 meters and a speed variation of 15 km/h. Rail Curve Specifications: L = 10 (Length of the curve segment) P11 = 40 (Curve angle in degrees) R = 150 (Curve radius of 150 meters) S = 120 (Superelevation of 120 mm) P12 = 30 (Transition curve angle or cant adjustment) H = profile (Track profile design) Dy = 0 (No vertical displacement of the track) RESULT It was obtained in the Y/Q table with 9213 parameters, with the average of the speed of 15km/h being at 0.307922, the minimum value of -0.13496, and the maximum being 0.79533. This value is still included in the Y/Q value range, which is Y/Q<0.8. Averange : 0,307922 Min. : -0,13496 Max. : 0,79533 Practitioner-Trainer : Prasetya Adi Nugraha Lecturer : Alvian Iqbal Hanif Nasrullah Vehicle Dynamics Center of Excellence Construction & Vehicle Simulation (CoE CVS) Teknik Mesin UMM

Rail Vehicle Turning Simulation using universal mechanism software Curve simulation is a crucial aspect of the dynamics of rail vehicles, aimed at evaluating the performance and safety of the vehicle against derailment risks. The critical condition typically analyzed in this simulation is the presence of track twist on the curve, which can cause instability and increase the risk of accidents. Through curve simulation, engineers can identify and address potential issues in the design and operation of both the track and rail vehicles, thereby enhancing the safety and efficiency of the rail transportation system. The track twist value simulated is 5% with a small curve radius of 150 meters and a speed variation of 20 km/h. Rail Curve Specifications: L = 10 (Length of the curve segment) P11 = 40 (Curve angle in degrees) R = 150 (Curve radius of 150 meters) S = 120 (Superelevation of 120 mm) P12 = 30 (Transition curve angle or cant adjustment) H = profile (Track profile design) Dy = 0 (No vertical displacement of the track) RESULT It was obtained in the Y/Q table with 7004 parameters, with the average of the speed of 20km/h is at 0.309715, the minimum value is -0.13291, and the maximum is 0.711831. This value is still included in the Y/Q value range, which is Y/Q<0.8. Practitioner-Trainer : Prasetya Adi Nugraha Lecturer : Alvian Iqbal Hanif Nasrullah Vehicle Dynamics Center of Excellence Construction & Vehicle Simulation (CoE CVS) Teknik Mesin UMM

Papermaking in Science Technology Papermaking in science technology represents a dynamic field that integrates cutting-edge advancements to enhance efficiency, quality, and sustainability in paper industry. One key area of innovation is in the development of advanced papermaking machines equipped with state-of-the-art sensors, controls, and automation systems. These technologies enable precise monitoring and adjustment of variables such as pulp to perfection consistency, water content, and drying conditions, optimizing the paper production process for improved productivity and resource utilization. Furthermore, scientific research plays a vital role in exploring novel materials and additives that enhance paper properties, such as strength, brightness, and printability. Nanotechnology, for instance, has opened new avenues for creating nano-sized additives that enhance paper strength and reduce environmental impact. In terms of sustainability in paper industry, science technology are driving forces behind eco-friendly practices in papermaking. Efforts are underway to develop sustainable alternatives to traditional pulping methods, such as using enzymes or bio-based chemicals to reduce energy consumption and chemical waste. Moreover, digitalization and data analytics are transforming papermaking operations through real-time monitoring, predictive maintenance, and optimization of production parameters. This integration of science technology not only improves operational efficiency but also enables the paper industry to adapt to changing market demands and environmental regulations. In essence, papermaking in science technology represents a continuous journey of innovation, where research, experimentation, and technological advancements converge to shape a more sustainable and efficient paper industry.

Aspect Ratio in PCB design: Aspect Ratio: Aspect ratio is the ratio of the PCB thickness to the diameter of the smallest drilled hole (via). This parameter is essential for ensuring that vias are properly plated and reliable. Aspect Ratio Formula: Aspect Ratio = PCB Thickness/Hole Diameter Types of Aspect Ratios: 1.Low Aspect Ratio (< 5:1) Easier to manufacture.Ensures better plating consistency.Common in standard PCB designs. 2.High Aspect Ratio (> 10:1) Used in high-density interconnect (HDI) designs.Requires advanced manufacturing techniques.Increases the risk of plating defects. Importance of Aspect Ratio: Manufacturability: A higher aspect ratio can lead to difficulties in the plating process, potentially causing issues such as voids or insufficient copper coverage. Reliability: Ensuring an appropriate aspect ratio improves the mechanical strength of vias, reducing the risk of failures. Cost: Higher aspect ratios typically increase manufacturing costs due to the need for specialized equipment and processes. Design Tips: 1.Work with Manufacturers: Engage with your PCB manufacturer early to align on capabilities and limitations, optimizing your design for production. 2.Plan Your Stack-Up: Consider overall board thickness and via sizes carefully, balancing electrical requirements with manufacturability. Aspect Ratio table: PCB thickness Hole Dia Aspect Ratio (mm) (mm) 1.6 0.4 4:1 low aspect ratio 1.6 0.2 8:1 Moderate aspect ratio 2.0 0.2 10:1 high aspect ratio 3.2 0.2 16:1 high aspect ratio Understanding and optimizing the aspect ratio in your PCB design is critical for achieving a balance between performance, reliability, and cost. By taking aspect ratio into account, you can ensure your PCBs are both high-quality and manufacturable. Syrma SGS Technology Limited RIKUN MANUFACTURING PVT LTD Tata Electronics Pvt. Ltd. Tata electric.39 Valeo Bosch India InSemi Technology TI Mobility Ather Energy Volvo Energy

Title:Embracing Renewable Energy: Paving the Way for a Sustainable Tomorrow In our quest for a sustainable future, the significance of renewable energy cannot be emphasized enough. With the global climate crisis looming large and the finite nature of fossil fuels becoming increasingly apparent, transitioning to renewable energy sources is not merely a choice but an urgent imperative. Renewable energy, sourced from abundant and inexhaustible natural elements such as sunlight, wind, and water, offers a beacon of hope in our fight against climate change. By harnessing these clean and renewable resources, we can drastically reduce greenhouse gas emissions, mitigate environmental degradation, and safeguard the planet for future generations. Beyond its environmental benefits, renewable energy holds the key to fostering economic prosperity and energy independence. Embracing renewable technologies presents opportunities for job creation, innovation, and economic growth, while simultaneously reducing our reliance on imported fossil fuels and volatile energy markets. Moreover, decentralizing energy production through renewables empowers communities to take control of their energy destiny, promoting resilience and equity in the energy sector. As we stand at the crossroads of environmental stewardship and economic progress, prioritizing renewable energy is not just a moral obligation but a strategic investment in a brighter, more sustainable future for all. TalentServe

❓ Can you really train an industrial robot with human movements ❓ 💡 When Georgia based chemical engineering firm, Isotec International, Inc.®, wanted to streamline the application of their patented Acrylobond® product they knew that any solution they provided needed to be adaptable and easy to program for their end users. Their technology search naturally led them right to Nordbo Robotics and our Mimic product. 💡 Acrylobond® is used as an environmentally friendly alternative to polyester resins and is used in, amongst other things, hot tub production. The application of this compound involves manipulating heavy spraying equipment connected to cumbersome tubes, all while wearing full protective gear. It’s a hard position to find workers for. 💡 By Integrating the Mimic software onto an industrial FANUC robot, we are not only automating the job completely, but also ensuring that the coverage on the units is totally consistent. 💡 Our partnership with Isotec® began only last October when they approached us with their challenges. Isotec®’s client was facing exactly these issues and we’re thrilled that our partnership has led us to a solution for their client in such a short period of time. We look forward to seeing the other ways in which Isotec® will continue to integrate our Mimic product into solutions for their end user clients. 👏 👏 👏 FANUC America Corporation Chuck Knight - Isotec Nicky Vølund Abdullah Hassan Ritish Singh Dorte Hostrup Pedersen Forest Knight Monty Hepner

Implementing a new magnetic flywheel technology to reduce motor amperage in a variable load scenario, such as crude jack pump oil production, involves several steps: 1. **Assessment of Load Variation**: Understand the typical range and pattern of load variation in the crude jack pump oil production process. This includes analyzing factors such as changes in oil viscosity, pump resistance, and flow rate fluctuations. 2. **Design and Integration**: Develop a magnetic flywheel system tailored to the specific requirements of the motor used in the jack pump setup. This involves selecting suitable magnets, designing the flywheel structure, and integrating it into the motor system. 3. **Control System Implementation**: Develop and deploy a control system that monitors the motor's operating conditions in real-time and adjusts the interaction between the motor and the magnetic flywheel accordingly. This control system should optimize energy transfer to minimize amperage spikes during load variations. 4. **Testing and Optimization**: Conduct thorough testing of the magnetic flywheel system in a simulated environment to validate its effectiveness in reducing motor amperage under variable load conditions. Fine-tune the control algorithms and system parameters to optimize performance. 5. **Deployment and Monitoring**: Install the magnetic flywheel technology in the crude jack pump oil production setup and monitor its performance over time. Continuously assess its impact on reducing motor amperage, energy consumption, and overall system efficiency. 6. **Maintenance and Upkeep**: Establish a maintenance schedule to ensure the magnetic flywheel system remains in optimal condition. This includes regular inspections, lubrication of moving parts, and replacement of worn components. By following these steps, you can effectively implement a new magnetic flywheel technology to reduce motor amperage in a variable load environment, such as crude jack pump oil production, leading to improved energy efficiency and operational stability. intrested please contact for more technology details thanks. Gujarat technology ahemdabad Gujarat india