Mechanical Engineering Inspirational Quotes

PayPal to a confident CEO who commands the respect of thousands. “I think there are ways he has dramatically improved over time,” said Thiel. Most impressive to Thiel has been Musk’s ability to find bright, ambitious people and lure them to his companies. “He has the most talented people in the aerospace industry working for him, and the same case can be made for Tesla, where, if you’re a talented mechanical engineer who likes building cars, then you’re going to Tesla because it’s probably the only company in the U.S. where you can do interesting new things. Both companies were designed with this vision of motivating a critical mass of talented people to work on inspiring things.

Life is like a gas turbine, After every compressor, there is always a turbine!

Initially working out of our home in Northern California, with a garage-based lab, I wrote a one page letter introducing myself and what we had and posted it to the CEOs of twenty-two Fortune 500 companies. Within a couple of weeks, we had received seventeen responses, with invitations to meetings and referrals to heads of engineering departments. I met with those CEOs or their deputies and received an enthusiastic response from almost every individual. There was also strong interest from engineers given the task of interfacing with us. However, support from their senior engineering and product development managers was less forthcoming. We learned that many of the big companies we had approached were no longer manufacturers themselves but assemblers of components or were value-added reseller companies, who put their famous names on systems that other original equipment manufacturers (OEMs) had built. That didn't daunt us, though when helpful VPs of engineering at top-of-the-food-chain companies referred us to their suppliers, we found that many had little or no R & D capacity, were unwilling to take a risk on outside ideas, or had no room in their already stripped-down budgets for innovation. Our designs found nowhere to land. It became clear that we needed to build actual products and create an apples-to-apples comparison before we could interest potential manufacturing customers. Where to start? We created a matrix of the product areas that we believed PAX could impact and identified more than five hundred distinct market sectors-with potentially hundreds of thousands of products that we could improve. We had to focus. After analysis that included the size of the addressable market, ease of access, the cost and time it would take to develop working prototypes, the certifications and metrics of the various industries, the need for energy efficiency in the sector, and so on, we prioritized the list to fans, mixers, pumps, and propellers. We began hand-making prototypes as comparisons to existing, leading products. By this time, we were raising working capital from angel investors. It's important to note that this was during the first half of the last decade. The tragedy of September 11, 2001, and ensuing military actions had the world's attention. Clean tech and green tech were just emerging as terms, and energy efficiency was still more of a slogan than a driver for industry. The dot-com boom had busted. We'd researched venture capital firms in the late 1990s and found only seven in the United States investing in mechanical engineering inventions. These tended to be expansion-stage investors that didn't match our phase of development. Still, we were close to the famous Silicon Valley and had a few comical conversations with venture capitalists who said they'd be interested in investing-if we could turn our technology into a website. Instead, every six months or so, we drew up a budget for the following six months. Via a growing network of forward-thinking private investors who could see the looming need for dramatic changes in energy efficiency and the performance results of our prototypes compared to currently marketed products, we funded the next phase of research and business development.

Within just a few thousand years-a millisecond in evolutionary time-humans had developed much more complex tools, and the intellectual theories to support them. Newtonian physics, the industrial revolution, and the nineteenth century age of enlightenment spurred tremendous technological development and transformed our social mores. A consequence of this paradigm shift, however, was that humanity's view of the world changed from an organic to a mechanistic one. Early engineers saw the potential of breaking up any system into components and rearranging the parts. Innovations in machinery and materials led to mass production: making thousands and then millions of exactly the same forms out of flat metal plates and square building blocks. However, for all its positive impact on the economics and culture of the era, the industrial revolution's orientation was shortsighted. In the rush to understand the world as a clockwork mechanism of discrete components, nature's design genius was left behind-and with it the blueprints for natural, nontoxic, streamlined efficiency. A new set of values emerged, such that anything drawn from nature was dismissed as primitive in favor of human invention. Just as the pharmacology of the rain forests, known to indigenous people for millenia, has been largely lost to modern science, so too were the simple rules of natural design obfuscated. A our societies became more urban, we went from living and working in nature and being intimately connected with its systems, to viewing nature as a mere warehouse (some might say, whorehouse) of raw materials waiting to be plundered for industrial development.

Over the next couple of years, we built and tested a series of prototypes, started dialogues with leading manufacturers, and added business development and technical staff to our team, including mechanical and aerospace engineers. Our plan was that PAX scientific would be an intellectual-property-creating R & D company. When we identified appropriate market sectors, we would license our patents to outside entrepreneurs or to our own, purpose-built, subsidiaries. Given my previous experience on the receiving end of hostile takeovers, we were determined to maintain control of PAX Scientific and its subsidiaries in their development stages. Creating subsidiaries that were market specific would help, since new investors could buy stock in a more narrowly focused business, without direct dilution of the parent company. We were introduced to fellow Bay Area resident Paul Hawken. A successful entrepreneur, author, and articulate advocate for sustainability and natural capitalism, Paul understood our vision of a parent company that concentrated on research and intellectual property, while separate teams focused on product commercialization. With his own angel investment backing, Paul established a series of companies to market computer, industrial, and automotive fans. PAX assigned worldwide licenses to these companies in exchange for up-front fees and a share of revenue; Paul hired managers and set off to sell fan designs to manufacturers.

The lotus is one of the most commercially successful sources of inspiration for biomimetic products. Apart from their intoxicating, heavenly fragrance, lotus plants are a symbol of purity in some major religions. More than two thousand years ago, for example, the Bhagavad Gita, one of India's ancient sacred scriptures, referred to lotus leaves as self-cleaning, but it wasn't until the late 1960s that engineers with access to high-powered microscopes began to understand the mechanism underlying the lotus' dirt-free surface. German scientist Dr. Wilhelm Barthlott continued this research, finding microstructures on the surface of a lotus leaf that cause water droplets to bead up and roll away particles of mud or dirt. Like many biomimics, this insight came quickly, while its commercialization took many years more. The "Lotus Effect"-short for the superhydrophobic (water-repelling) quality of the lotus leaf's micro to nanostructured surface-has become the subject of more than one hundred related patents and is one of the premier examples of successfully commercialized biomimicry.

Carson’s writing inspired a new, much more radical generation of environmentalists to see themselves as part of a fragile planetary ecosystem rather than as its engineers or mechanics, giving birth to the field of Ecological Economics. It was in this context that the underlying logic of extractivism—that there would always be more earth for us to consume—began to be forcefully challenged within the mainstream.

Whether it’s my manager or my coworker, when I find myself in an organic/mechanic conflict, I think this:“A purely mechanical organization lacks inspiration. A purely organic organization is total chaos. ”Organics fill mechanical blind spots with their intuition and their passion while mechanics create a healthy, solid home where nutty organics can run into things at speed. It’s a team thing.

In a now-famous experiment, he and his colleagues compared three groups of expert violinists at the elite Music Academy in West Berlin. The researchers asked the professors to divide the students into three groups: the “best violinists,” who had the potential for careers as international soloists; the “good violinists”; and a third group training to be violin teachers rather than performers. Then they interviewed the musicians and asked them to keep detailed diaries of their time. They found a striking difference among the groups. All three groups spent the same amount of time—over fifty hours a week— participating in music-related activities. All three had similar classroom requirements making demands on their time. But the two best groups spent most of their music-related time practicing in solitude: 24.3 hours a week, or 3.5 hours a day, for the best group, compared with only 9.3 hours a week, or 1.3 hours a day, for the worst group. The best violinists rated “practice alone” as the most important of all their music-related activities. Elite musicians—even those who perform in groups—describe practice sessions with their chamber group as “leisure” compared with solo practice, where the real work gets done. Ericsson and his cohorts found similar effects of solitude when they studied other kinds of expert performers. “Serious study alone” is the strongest predictor of skill for tournament-rated chess players, for example; grandmasters typically spend a whopping five thousand hours—almost five times as many hours as intermediatelevel players—studying the game by themselves during their first ten years of learning to play. College students who tend to study alone learn more over time than those who work in groups. Even elite athletes in team sports often spend unusual amounts of time in solitary practice. What’s so magical about solitude? In many fields, Ericsson told me, it’s only when you’re alone that you can engage in Deliberate Practice, which he has identified as the key to exceptional achievement. When you practice deliberately, you identify the tasks or knowledge that are just out of your reach, strive to upgrade your performance, monitor your progress, and revise accordingly. Practice sessions that fall short of this standard are not only less useful—they’re counterproductive. They reinforce existing cognitive mechanisms instead of improving them. Deliberate Practice is best conducted alone for several reasons. It takes intense concentration, and other people can be distracting. It requires deep motivation, often self-generated. But most important, it involves working on the task that’s most challenging to you personally. Only when you’re alone, Ericsson told me, can you “go directly to the part that’s challenging to you. If you want to improve what you’re doing, you have to be the one who generates the move. Imagine a group class—you’re the one generating the move only a small percentage of the time.” To see Deliberate Practice in action, we need look no further than the story of Stephen Wozniak. The Homebrew meeting was the catalyst that inspired him to build that first PC, but the knowledge base and work habits that made it possible came from another place entirely: Woz had deliberately practiced engineering ever since he was a little kid. (Ericsson says that it takes approximately ten thousand hours of Deliberate Practice to gain true expertise, so it helps to start young.)