biomimetics

简明释义

[baɪɒmɪˈmetɪks][baɪɒmɪˈmetɪks]

n. 生体模仿学

英英释义

Biomimetics is the study and design of systems or materials that are inspired by biological processes and structures found in nature.

仿生学是研究和设计受自然界中生物过程和结构启发的系统或材料的学科。

单词用法

biomimetics in engineering

工程中的生物仿生学

biomimetics in design

设计中的生物仿生学

biomimetics and sustainability

生物仿生学与可持续性

the field of biomimetics

生物仿生学领域

principles of biomimetics

生物仿生学原理

applications of biomimetics

生物仿生学的应用

同义词

biomimicry

仿生学

Biomimicry has led to innovations in sustainable architecture.

仿生学推动了可持续建筑的创新。

bioinspiration

生物启发

Bioinspiration can be seen in various fields, from engineering to medicine.

生物启发在从工程到医学的各个领域都能看到。

biologically inspired design

生物启发设计

Biologically inspired design often mimics natural processes.

生物启发设计通常模仿自然过程。

反义词

artificiality

人工性

The artificiality of the materials used in the product raised concerns about its environmental impact.

产品中使用的材料的人工性引发了对其环境影响的担忧。

synthetic

合成的

Synthetic fibers are often less breathable than natural ones, affecting comfort.

合成纤维通常不如天然纤维透气,影响舒适度。

例句

1.Scientists from Leeds University and from Swedish Biomimetics 3000 reported on these propellant abilities in the April issue of Physics World.

科学家从利兹大学和来自瑞典3000个仿生学家在2005年4月发行的物理世界上报告了这些推进剂能力。

2.But a team led by Iain Anderson, the head of the Auckland Bioengineering Institute's Biomimetics Lab, has built an entire menagerie of muscle-powered motors.

不过奥克兰生物工程研究所仿生学实验室主任伊恩·安德森iain Anderson领导的团队已经制造出了一大批生物肌肉动力电机。

3.With the marriage of biomimetics and robotics, there has been a new revolution in structure design and selection of robotic gaits. It enlarges the field of robotic application.

仿生技术与机器人技术的结合,使机器人从结构设计到运动模式的选择都有了新的进展,这大大扩大了机器人的应用领域。

4.The researchers, Evan Ulrich, Darryll Pines, and Sean Humbert from the University of Maryland, have published their study on the robotic samaras in a recent issue of Bionspiration &Biomimetics

研究者,伊万乌尔里奇, 达利 派恩斯,和肖恩亨伯特(他们来自马里兰大学)已经发表了他们关于机器翼果的研究报告在最新一期的 生物灵感和仿生学 上。

5.The results, just published in Bioinspiration and Biomimetics, show not only that flying snakes are surprisingly good aviators but also that they employ some complex aerodynamic tricks.

不久前在生物灵感和仿生学上发布的结果显示:飞蛇的飞行不仅令人叹为观止,并且飞行过程中使用了一些在空气动力方面的很复杂的技巧。

6.The researchers, Evan Ulrich, Darryll Pines, and Sean Humbert from the University of Maryland, have published their study on the robotic samaras in a recent issue of Bionspiration &Biomimetics

研究者,伊万乌尔里奇, 达利 派恩斯,和肖恩亨伯特(他们来自马里兰大学)已经发表了他们关于机器翼果的研究报告在最新一期的 生物灵感和仿生学 上。

7.Created by: Mark Cutkosky at Stanford University's Biomimetics and Dextrous Manipulation lab.

创造者:马克·库特考斯基,斯坦福大学,仿生灵活操控实验室。

8.In architecture, biomimetics 仿生学 can lead to buildings that are more energy-efficient and environmentally friendly.

在建筑学中,仿生学可以促使建筑物更加节能和环保。

9.The design of the new adhesive was inspired by the principles of biomimetics 仿生学 found in gecko feet.

新型粘合剂的设计灵感来源于壁虎脚部的仿生学原理。

10.Researchers are exploring biomimetics 仿生学 to create more efficient solar panels that mimic the way leaves capture sunlight.

研究人员正在探索仿生学,以创造更高效的太阳能电池板,模仿叶子捕捉阳光的方式。

11.The study of biomimetics 仿生学 has led to breakthroughs in materials science, such as self-healing materials.

仿生学的研究带来了材料科学的突破,例如自愈材料。

12.The field of biomimetics 仿生学 draws inspiration from nature to solve complex engineering problems.

仿生学领域从自然中汲取灵感,以解决复杂的工程问题。

作文

Biomimetics, or biomimicry, is an interdisciplinary field that seeks to understand and emulate the designs and processes found in nature. This innovative approach has gained significant attention in recent years as researchers and engineers look for sustainable solutions to modern challenges. By studying how organisms have adapted to their environments over millions of years, we can uncover strategies that can be applied to human technology and design.One of the most compelling examples of biomimetics (仿生学) in action is the development of Velcro. The invention was inspired by the way burrs stick to animal fur. Swiss engineer George de Mestral noticed this phenomenon during a walk in the woods and sought to replicate the mechanism. His observations led to the creation of a hook-and-loop fastening system that is now widely used in clothing, shoes, and various other products. This simple yet effective design showcases how nature can inspire practical solutions to everyday problems.Another fascinating application of biomimetics (仿生学) is found in the field of architecture. The Eastgate Centre in Zimbabwe is a prime example of how natural cooling systems can be integrated into building design. Inspired by the way termites regulate temperature in their mounds, architect Mick Pearce designed this shopping center without traditional air conditioning. Instead, it utilizes natural ventilation and thermal mass to maintain a comfortable indoor climate, significantly reducing energy consumption. This project highlights the potential for biomimetics (仿生学) to create environmentally friendly structures that minimize our ecological footprint.In the realm of medicine, biomimetics (仿生学) has led to groundbreaking advancements in drug delivery systems. Researchers have studied the unique properties of certain animals, such as the ability of geckos to adhere to surfaces using microscopic hairs on their feet. This understanding has inspired the development of new adhesive materials that can be used in medical applications, such as sutures and bandages that adhere better to the skin while minimizing discomfort. This intersection of biology and technology exemplifies the power of biomimetics (仿生学) in improving healthcare outcomes.Furthermore, biomimetics (仿生学) plays a crucial role in the advancement of robotics. Engineers are increasingly looking to nature for inspiration when designing robots capable of navigating complex environments. For instance, the study of bird flight has led to the development of drones that mimic the flapping motion of wings, resulting in improved maneuverability and efficiency. By emulating the intricate movements of animals, researchers can create machines that perform tasks more effectively than traditional designs.The implications of biomimetics (仿生学) extend beyond individual inventions; they represent a fundamental shift in how we approach problem-solving. As we face pressing global issues such as climate change, resource depletion, and public health crises, the lessons learned from nature become increasingly relevant. By adopting a mindset that values sustainability and innovation, we can harness the wisdom embedded in the natural world.In conclusion, biomimetics (仿生学) offers a promising pathway toward developing solutions that are not only effective but also environmentally responsible. By studying and emulating the strategies employed by nature, we can create technologies that harmonize with the ecosystem rather than exploit it. As we continue to explore this fascinating field, the potential for transformative change in various industries becomes clear. Embracing the principles of biomimetics (仿生学) may very well be the key to building a sustainable future for generations to come.

仿生学是一个跨学科领域,旨在理解和模仿自然界中发现的设计和过程。近年来,这种创新方法引起了广泛关注,因为研究人员和工程师正在寻找可持续解决现代挑战的方案。通过研究生物体如何在数百万年中适应其环境,我们可以发现可以应用于人类技术和设计的策略。仿生学的一个引人注目的例子是魔术贴的开发。这项发明受到植物刺果粘附动物毛发的启发。瑞士工程师乔治·德·梅斯特拉尔在一次森林散步中注意到了这一现象,并试图复制这种机制。他的观察导致了钩环固定系统的创建,该系统现在广泛用于服装、鞋子和各种其他产品。这一简单而有效的设计展示了自然如何激发日常问题的实用解决方案。仿生学的另一个迷人应用出现在建筑领域。津巴布韦的东门中心就是自然冷却系统如何融入建筑设计的典范。受白蚁在其巢穴中调节温度的方式启发,建筑师米克·皮尔斯设计了这座购物中心,而没有使用传统的空调。相反,它利用自然通风和热质量来维持舒适的室内气候,显著降低了能源消耗。该项目突显了仿生学创造环保结构以最小化生态足迹的潜力。在医学领域,仿生学推动了药物输送系统的突破性进展。研究人员研究了某些动物的独特特性,例如壁虎通过脚上的微观毛发附着在表面的能力。这一理解激发了新型粘合材料的发展,可用于医疗应用,如缝合线和能够更好地附着于皮肤的绷带,同时减少不适感。这种生物与技术的交集示范了仿生学在改善医疗结果方面的力量。此外,仿生学在机器人技术的进步中也发挥着至关重要的作用。工程师们越来越多地寻求自然界的灵感,以设计能够在复杂环境中导航的机器人。例如,对鸟类飞行的研究促使开发出模仿翅膀拍打运动的无人机,从而提高了机动性和效率。通过模仿动物的复杂运动,研究人员可以创建比传统设计更有效地执行任务的机器。仿生学的影响不仅限于个别发明;它代表了我们解决问题方法的根本转变。随着我们面临气候变化、资源枯竭和公共卫生危机等紧迫全球问题,从自然中获得的经验教训变得越来越相关。通过采用重视可持续性和创新的思维方式,我们可以利用自然界中蕴含的智慧。总之,仿生学为开发不仅有效而且环境负责任的解决方案提供了一条有希望的路径。通过研究和模仿自然所采用的策略,我们可以创造与生态系统和谐共存的技术。随着我们继续探索这一迷人的领域,各个行业变革的潜力变得显而易见。拥抱仿生学的原则可能是为后代建立可持续未来的关键。