How Sustainable Construction Boosts Employee Health and Productivity

Sustainable construction has a strong impact on employee well-being by creating healthier, safer, and more comfortable workspaces. Using eco-friendly materials, better air ventilation, natural lighting, and energy-efficient systems helps reduce stress, improve mood, and boost overall health. Employees working in green buildings often feel more energized and focused, which leads to better performance and less sick leave. Expert Majid Hedayati explains that sustainable construction not only protects the environment but also supports the physical and mental health of workers. When companies invest in green buildings, they show they care about both the planet and their people—creating a positive, productive place to work.

How to build AI security without slowing innovation?

In the latest episode of the Devico Breakfast Bar Podcast, Oleg Sadikov — CEO and co-founder of Devico and DeviQA — sits down with Mateo Rojas-Carulla, co-founder of Lakera, to explore what it really takes to secure AI systems in today’s rapidly evolving tech landscape.

The conversation touches on everything from the viral success of Gandalf, Lakera’s AI-powered game that exposed prompt injection vulnerabilities, to the infrastructure challenges of protecting GenAI applications at scale. Mateo shares firsthand insights into why GenAI security demands a new playbook — one that breaks away from traditional cybersecurity assumptions.

Listeners will also gain practical strategies for scaling development with dedicated teams and making the most of software outsourcing services — without compromising on speed, safety, or control.

Listen here: https://www.deviqa.com/podcasts/mateo-rojas-carulla/

Highlights:

How GenAI is changing the rules of digital security

Why Gandalf went viral—and what it revealed

Key differences between AI security and classic cybersecurity

The role of distributed teams and time-zone-resilient collaboration

How smart outsourcing enables fast, secure AI product development

This episode is a must for tech leaders, AI builders, and anyone thinking about secure innovation at scale.

Drive MEP Excellence as Project Engineer - HVAC | Join Job24by7 for Dynamic Projects

Job24by7 is hiring an Project Engineer HVAC to lead cutting-edge construction projects in the MEP industry. If you’re passionate about designing, executing, and optimizing HVAC systems for commercial and industrial spaces, this is your chance to step into a leadership role and make a lasting impact.

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Revolutionizing Mechanics: A Critical Review of Emerging Technologies in Mechanical Engineering

1. Introduction

Mechanical engineering, a cornerstone of innovation, is undergoing a transformative phase as emerging technologies redefine traditional practices. As the backbone of industrial development, mechanical engineering has always evolved to meet societal needs. Today, advancements such as additive manufacturing, robotics, and sustainable energy systems are promising to revolutionize the way industries operate. These technologies not only enhance efficiency and productivity but also align with global sustainability goals (Kulkov et al.,2024). This critical review explores these cutting-edge advancements and their implications for professionals seeking to navigate and thrive in this rapidly evolving landscape.

2. Critical review

2.1. Additive Manufacturing (3D Printing)

Additive manufacturing, also known as 3D printing, is transforming mechanical engineering by allowing the creation of intricate geometries that were once impossible to achieve. This technology is characterized by its ability to build structures layer by layer, minimizing material waste and enabling unprecedented customization. In the aerospace industry, lightweight lattice structures have significantly reduced aircraft weight, leading to improved fuel efficiency. Similarly, in healthcare, multi-material printing allows for the production of integrated components, such as prosthetics and implants, that cater to individual patient needs.

The flexibility and precision of additive manufacturing have expanded its applications across various domains, driving innovation and reducing costs. As research progresses, advancements like bioprinting and metal 3D printing are set to redefine possibilities (Kanyilmaz et al.,2022).

2.2. Automation and Robotics

The fusion of artificial intelligence (AI) and robotics ushers in a new era for manufacturing. Automation has been a key focus, but AI-driven robotics takes it to the next level by enabling machines to learn and adapt to dynamic environments. Collaborative robots, or cobots, are designed to work alongside humans, enhancing safety and efficiency on assembly lines (Keshvarparast et al.,2024). These robots excel in repetitive and precise tasks, allowing human workers to focus on complex problem-solving activities.

Real-time monitoring and predictive maintenance are additional benefits. AI-powered systems analyze data to predict potential failures, minimizing downtime and maintenance costs. For example, automotive assembly plants have adopted cobots for intricate tasks like welding and painting, ensuring consistency and speed.

2.3. Sustainable Energy Solutions

With the growing emphasis on sustainability, mechanical engineers are playing a crucial role in developing renewable energy technologies. From designing efficient wind turbines to optimizing energy storage systems, the field is at the forefront of addressing global energy challenges. Thermoelectric materials, which convert heat into electricity, are gaining traction as a promising solution for waste heat recovery. Similarly, hydrogen fuel cells are emerging as a clean and efficient energy source for vehicles and industrial applications.

The integration of these technologies into existing infrastructure requires innovative design and engineering solutions. For instance, offshore wind farms are utilizing advanced mechanical systems to withstand harsh environmental conditions while maximizing energy output.

2.4. Advanced Materials

The emergence of advanced materials has paved the way for new possibilities in mechanical engineering. Smart materials, such as shape-memory alloys, can respond to external stimuli like temperature or stress, making them ideal for aerospace and biomedical applications. Self-healing polymers, another innovative material, have the ability to repair themselves when damaged, enhancing the longevity and reliability of mechanical systems.

In the automotive industry, these materials contribute to lighter and more fuel-efficient vehicles, while in robotics, they enable the development of flexible and adaptive components (Zhang et al.,2023). As research advances, these materials are expected to become even more versatile, fostering innovations across multiple sectors.

2.5. Digital Twin Technology

Digital twin technology is revolutionizing the way engineers design, monitor, and maintain mechanical systems. By creating virtual replicas of physical systems, digital twins enable real-time analysis and optimization. For instance, in power plants, digital twins are used to simulate operational scenarios, predict equipment failures, and enhance performance.

This technology is instrumental in lifecycle management, reducing costs and downtime. Industries ranging from manufacturing to healthcare are adopting digital twins to improve efficiency and innovation. As computational power grows, the applications of digital twins are expected to expand further, integrating seamlessly with IoT and AI technologies.

3. Challenges and Future Directions

Despite the potential of these emerging technologies, challenges remain. High implementation costs and skill gaps hinder widespread adoption (Zuo et al.,2023). Additionally, regulatory frameworks often lag behind technological advancements, creating barriers to innovation. Addressing these issues requires interdisciplinary collaboration, targeted training programs, and supportive policies.

Looking ahead, the integration of quantum computing and bio-inspired designs into mechanical engineering holds exciting prospects. These advancements promise to unlock new levels of efficiency, functionality, and sustainability, further transforming the field.

4. Conclusion

Emerging technologies in mechanical engineering are reshaping industries, driving efficiency, and promoting sustainability. Additive manufacturing, robotics, renewable energy solutions, advanced materials, and digital twin technology represent the cutting edge of this transformation. By embracing these innovations, engineers can address global challenges and unlock unprecedented opportunities. The journey of revolutionizing mechanics is ongoing, ensuring a future of limitless possibilities.

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Code Commits Are Not a Measure of Software Success—Customer Delight Is

More commits don’t always mean better software. Measuring success by lines of code or commit frequency can lead to inefficiencies and missed opportunities. True success lies in how well your software delights customers, solves real problems, and drives business value. In this blog, we explore why shifting the focus from developer output to user impact leads to better products and happier customers.

IC vs. Management is an Outdated Framework: How to Future-Proof Your Tech Career in an AI-Driven World

If you’ve been in tech for a while, you’re probably starting to feel it.

The industry is shifting—fast.

AI is changing how work gets done. Companies are restructuring. And suddenly, the old career paths—IC vs. management—don’t feel as stable anymore.

So where do you go from here?

Most tech career advice still assumes a binary choice:

Stay an IC and focus on execution

Move into management to climb the ladder

But this was never designed—it was a reaction to a workforce that didn’t want to be forced into leadership. Now, it’s an outdated framework that doesn’t fit the way the industry is evolving.

🔥 The Real Career Risk: AI is Changing the Game

The biggest unspoken shift in tech careers today?

AI isn’t replacing engineers—it’s replacing engineers who don’t adapt.

Right now, junior-level execution work is being automated faster than most people realize.

Which means the real question isn’t “Should I be an IC or a manager?” It’s “What makes me irreplaceable?”

That’s where your real career insurance comes in.

🛠 How to Future-Proof Your Tech Career (IC, Manager, or Otherwise)

No matter what path you’re considering, the key is to develop high-leverage, hard-to-automate skills.

🔹 If You Want to Stay Technical & Increase Job Security: ✅ Level up to Staff+ roles (Staff Engineer, Principal Engineer, Architect) ✅ Learn AI-assisted development—so you stay ahead, not behind ✅ Shift from execution to influence—get involved in cross-team decision-making ✅ Think in systems, not just features—be the person who optimizes execution, not just participates in it

🔹 If You’re Considering Management: ✅ Try a hybrid role first—Tech Lead, EM, or Staff+ with mentoring responsibilities ✅ Understand what leadership actually means—strategy, influence, and high-leverage decision-making ✅ Make sure you want it for the right reasons—not just for salary bumps ✅ Use management as an income boost while keeping a strong technical foundation

🔹 If You’re Unsure & Want to Keep Your Options Open: ✅ Develop pivotable skills—strategy, architecture, and influence (valuable in both IC and management roles) ✅ Position yourself as an AI-augmented problem solver—not just a coder ✅ Experiment with leadership without committing—lead projects, mentor juniors, influence stakeholders ✅ Focus on what will be hardest to replace in 5 years—decision-making, problem-solving, high-level strategy

🔮 The 5-Year Outlook: What’s Coming Next?

If you want to stay relevant in tech, you need to think beyond the next promotion.

Here’s what’s most likely coming: 🚀 AI will handle most junior-level execution work. 🚀 The highest-paid, most secure jobs will focus on: ✔ AI-augmented decision-making (not just coding) ✔ High-level strategy & technical leadership ✔ Cross-functional influence & systems optimization

So the real question isn’t “IC or manager?” It’s “How do I create maximum leverage in my career?”

📌 Where to Go from Here

If you’re thinking about your next career move, here’s what you can do right now:

🔹 Explore Staff+ roles if you want to stay technical. 🔹 Try Tech Lead responsibilities before fully switching to management. 🔹 Start integrating AI into your workflow—before it integrates you. 🔹 Join communities discussing the future of tech leadership.

The old career playbook? It’s breaking down. The key isn’t to follow it—it’s to write your own.

📌 What are your thoughts on this shift? Are you staying technical or exploring leadership? Let’s talk in the comments.

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𝗕𝗲𝘀𝘁 𝗩𝗲𝗻𝘂𝗲 𝗣𝗮𝗿𝘁𝗻𝗲𝗿 𝗼𝗳 𝗕𝗣𝗨𝗧 𝗧𝗘𝗖𝗛 𝗖𝗔𝗥𝗡𝗜𝗩𝗔𝗟 𝟮𝟬𝟮𝟰

We are elated to announce that 𝑹𝒂𝒂𝒋𝒅𝒉𝒂𝒏𝒊 𝑬𝒏𝒈𝒊𝒏𝒆𝒆𝒓𝒊𝒏𝒈 𝑪𝒐𝒍𝒍𝒆𝒈𝒆 [𝑹𝑬𝑪], 𝑩𝒉𝒖𝒃𝒂𝒏𝒆𝒔𝒘𝒂𝒓 has been honored as the 𝗕𝗲𝘀𝘁 𝗩𝗲𝗻𝘂𝗲 𝗣𝗮𝗿𝘁𝗻𝗲𝗿 𝗼𝗳 𝗕𝗣𝗨𝗧 𝗧𝗘𝗖𝗛 𝗖𝗔𝗥𝗡𝗜𝗩𝗔𝗟 𝟮𝟬𝟮𝟰!

This prestigious recognition reflects our dedication, state-of-the-art infrastructure, and unwavering commitment to excellence in hosting events of global standards. The vibrant energy of the carnival, the overwhelming participation, and the innovative spirit showcased by all involved made this achievement possible.

#ProudMoment#BPUTTechCarnival2024#BestVenuePartner#RECExcellence#InnovationHub#EngineeringLeadership#RECCommunity#GlobalStandards#FutureOfEducation#CelebratingSuccess

This award celebrates outstanding contributions to aerospace engineering, honoring innovation in design, propulsion, materials, systems, and sustainability. Awardees set new benchmarks in innovation, leadership, and impact on the future of flight and space exploration.

New Scientists Awards

Nomination Link: https://newscientists.net/award-nomination/?ecategory=Awards&rcategory=Awardee

Web Visitors: https://newscientists.net/

For Enquiry: [email protected]

#sciencefather #scientist #scienceinnovation #researchexcellence #scientificbreakthrough #newscientistsawards #AerospaceEngineering #AerospaceAward #EngineeringExcellence #InnovationInFlight #FutureOfAerospace #SpaceExploration #AviationInnovation #EngineeringLeadership #FlightEngineering #NextGenAerospace #AerospaceInnovation #STEMAwards

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Losses Aren’t Just Numbers.

They’re the Hidden Language of Pumping Systems.

Most engineers classify head losses—whether static, friction, or velocity—as simple design constants. But in critical water systems, losses are more than numbers; they’re real-time indicators of system performance, efficiency shifts, and potential operational risks.

Let’s redefine how we interpret losses.

◾ Static Head: Often viewed as stable, yet in systems with variable tank levels or tidal influence, this "stability" can mask dynamic shifts—altering pressure distribution over time.

◾ Friction Losses: They rarely stay constant. Internal scaling, sediment buildup, or even biofilm accumulation can lead to creeping inefficiencies that go unnoticed.

◾ Velocity Head: Commonly neglected. In undersized systems or poorly balanced loops, even modest velocity surges can drastically elevate energy costs.

Here’s the deeper insight:

When the differential pressure (ΔP) across a pump increases without an increase in flow, that’s not coincidence—it’s a message.

◾ Early-stage internal fouling?

◾ Progressive valve degradation?

◾ Partial blockages?

All of these create hidden head losses that slowly erode efficiency and reliability—unless they’re actively monitored.

Field example:

In a coastal supply network, engineers observed a gradual 12% rise in differential pressure over several months—with stable flow conditions.

There was no direct alert, but historical trend data indicated a growing anomaly.

Upon inspection, biofilm buildup in an upstream pipeline segment was discovered—still in its early stage.

Timely intervention prevented further escalation and avoided service interruptions.

🔷️Recommended practice for professionals:

🔹️Log baseline ΔP readings during commissioning

🔹️Analyze long-term pressure trends, not just real-time values

🔹️ Utilize differential pressure sensors across key segments

🔹️ Integrate with system-level monitoring (e.g., SCADA or data acquisition platforms) to catch early drifts

🔹️View every head loss as a signal—not just a design number

✅ In advanced systems, head losses are not margins to tolerate.

They are silent indicators that, when understood, become powerful tools for decision-making.

#AdvancedPumps #HydraulicLosses #Sustainability #PressureMonitoring #SmartWaterSystems #EnergyEfficiency #DigitalTwin #MechanicalEngineering #PumpingSolutions #SmartMaintenance #WaterIndustry #WaterTechnology #PumpDiagnostics #Engineering #EngineeringLeadership #ProcessOptimization

Majid Hedayati's Blueprint for Leading Global A/E/C Firms to Success

Effective leadership in global Architecture, Engineering, and Construction (A/E/C) firms demands a unique combination of strategic vision and operational excellence. As industry expert Majid Hedayati demonstrates, top-performing leaders must master three critical dimensions: cross-border collaboration, cultural intelligence, and flawless project delivery. These firms thrive when leaders bridge the gap between technical precision and business strategy - implementing innovative solutions while navigating complex local regulations and diverse market conditions.

Hedayati's approach highlights the importance of building agile, multidisciplinary teams equipped with cutting-edge digital tools. His strategies focus on developing clear communication channels across time zones, investing in continuous talent development, and creating systems that maintain quality standards while accommodating regional differences. What sets successful global A/E/C leaders apart is their ability to balance standardized processes with localized adaptation - ensuring both operational efficiency and cultural relevance in every market they serve.

The most forward-thinking firms, following Hedayati's leadership model, are those that transform geographical challenges into competitive advantages. They achieve this by fostering knowledge-sharing networks, implementing robust risk management frameworks, and cultivating leadership pipelines that reflect the global nature of their operations. In today's rapidly evolving construction landscape, these strategies don't just drive project success - they redefine what's possible for firms operating on the world stage.

🦾Guest Lecture Series: Innovations in Mechanical Engineering

Purpose: To enhance students’ knowledge and understanding of current trends and innovations in mechanical engineering.

Organizing a Guest Lecture on Rapid Prototyping & Automation in Manufacturing Process Department of Mechanical Engineering Faculty of Engineering & Technology

🎙️Speaker: Mr. Tapas Jyoti Kalita, Asst. Prof., Don Vosco University, Guwahati, Assam

🗓️ Date: 7th & 8th Oct. 2024 ⏰ Time: 02:30 P.M. 📍 Venue: Room No.-110, Engineering Block

📄 Registration link: https://forms.gle/46ikavvMTSo7u1H36

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How is the curriculum of the M.Tech courses for civil engineering in Chandigarh?

The curriculum of M.Tech courses for Civil Engineering in Chandigarh is designed to provide students with in-depth knowledge and practical skills necessary for the civil engineering industry. The curriculum is designed to keep up with the latest trends and technology in the field, ensuring that students are equipped with the necessary skills to tackle real-world challenges. In this article, we will discuss the curriculum of M.Tech courses for Civil Engineering in Chandigarh in detail.

Listening to Anthony Fasano, P.E. speaking on Developing the Engineering Leader Inside Me. #PEcon17 #EngineeringLeadership (at Atlanta Marriott Marquis)

This award celebrates outstanding contributions to aerospace engineering, honoring innovation in design, propulsion, materials, systems, and sustainability. Awardees set new benchmarks in innovation, leadership, and impact on the future of flight and space exploration.

New Scientists Awards

Nomination Link: https://newscientists.net/award-nomination/?ecategory=Awards&rcategory=Awardee

Web Visitors: https://newscientists.net/

For Enquiry: [email protected]

#sciencefather #scientist #scienceinnovation #researchexcellence #scientificbreakthrough #newscientistsawards #AerospaceEngineering #AerospaceAward #EngineeringExcellence #InnovationInFlight #FutureOfAerospace #SpaceExploration #AviationInnovation #EngineeringLeadership #FlightEngineering #NextGenAerospace #AerospaceInnovation #STEMAwards

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