案例分析
“开箱即用”- 通过使用 OAV 空气轴承精确测量陷阱颚蚁下颌骨撞击产生的能量。
OAV 创始人 Murat Erturk 最喜欢的表达方式,“outside the box”,与 Murat 在其从事航空航天相关技术的工程生涯后创办的公司联系起来恰如其分。 事实上,OAV 的许多工程师都专注于思考在与客户交谈或开发新的空气轴承以解决现有制造和行业范围内的问题时,“开箱即用”。与 LED 技术取代白炽灯泡的方式大致相同,无摩擦空气轴承正在迅速取代标准滚轮和直线轴承,这不仅要归功于行业对更高效率和节能的需求,而且还要归功于对更高精度和长期成本节约的需求。
Justin Jorge 是杜克大学 Sheila Patek 博士实验室的博士生,他最近的任务是测量从一只蚂蚁的下颌骨释放的能量,准确地说,是陷阱颚蚁。 Jorge 意识到当前的传感器和能量测量技术无法在陷阱颚蚁下颌骨撞击的大小和时间尺度上发挥作用,并着手创建一种基于摆锤的新型测量系统。经过长时间的设计和测试,豪尔赫得出结论,用于精确测量从下颌骨释放的能量的传统钟摆技术(包括利用现有滚子轴承的基于钟摆的测量系统)严重不足且不准确。事实上,由于陷阱颚蚁下颌骨的大小、速度和加速度,任何测量尝试都变得极其困难——考虑到下颌骨尖端的加速速度比普通手枪发射的子弹的速度更快,这是一个可以理解的结论. 下颌骨在其目标上产生的能量无法通过使用标准方法和普通旋转轴承的普通技术准确确定。 获取的数据在测试组件的早期设计中,由于克服传统轴承的初始摩擦和惯性矩所需的能量而受到影响。
Jorge 在杜克大学 Patek 博士的实验室工作,他希望设计一种新型的基于摆锤的测量设备,该设备需要减少或无摩擦的旋转点。 跳出框框思考,他着陆了将一项新技术——空气轴承——作为可能的解决方案。 在与 OAV 的工程师进行了一系列设计和应用讨论之后,他知道自己走在了正确的轨道上。随后的测试证明他是正确的。
通过用 OAV 空气滚子轴承替换双刚性摆测试组件支点处的传统滚子轴承,Jorge 能够克服传统轴承在收集质量测试数据方面存在的障碍。 His结论很明确:“摩擦对这些尺度(微焦耳)的能量测量有很大影响……而且……使用 OAV 空气轴承测量的能量至少是我们使用传统滚珠轴承时的六倍。”_cc781905 -5cde-3194-bb3b-136bad5cf58d_这个结论的明确推论是传统轴承旋转运动明显损失能量,使用空气轴承比传统轴承具有长期优势。 Jorge 还得出结论,虽然空气轴承显然比传统轴承更昂贵,但可以通过消除测试和精确之间的维护来“证明(它的使用)节省了时间”传统轴承无法实现的离子和精度。” OAV 的工程师同意。 空气轴承的使用最初可能成本更高,但它们通过以下方式降低了长期成本更少的维护和停机时间(以及相关的人工)成本,更高的长期可靠性和准确性。
OAV 工程师在他们为大学和企业研究人员提供的大部分支持工作中都有类似的故事。无论是测试陷阱颚蚁下颌撞击产生的能量,还是普通家蝇翅膀产生的能量,OAV 都在努力为未来提供解决方案。
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Jorge, JF、Bergbreiter, S. 和 Patek, SN (2021)。基于摆锤的测量揭示了陷阱颚蚂蚁规模的冲击动力学。 J Exp Biol jeb.232157。
本材料基于美国陆军研究实验室和美国 592 陆军研究办公室支持的工作,合同/授权编号为 W911NF-15-1-0358.
OAV founder Murat Erturk’s favorite expression, “outside the box", is appropriately associated with the company Murat started after his engineering career in aerospace and aviation related technologies. Indeed, many of OAV’s engineers focus on thinking “outside the box” when speaking with clients and customers or when developing new air bearings to solve existing manufacturing and industry wide problems. In much the same way that LED technology has come to replace incandescent light bulbs, frictionless air bearings are rapidly replacing standard roller and linear bearings, thanks not only to the industry’s need for greater efficiency and energy reduction, but also due to the need for greater precision and long-term cost savings.
Justin Jorge, a PhD student in the laboratory of Dr. Sheila Patek at Duke University, was recently tasked with measuring the energy released from the mandibles of an ant, the trap-jaw ant to be precise. Jorge realized that the current sensors and energy measurement techniques did not work at the size and time scales of a trap-jaw ant mandible strike and set out to create a novel pendulum-based measurement system. After an extended period of design and testing, Jorge came to the conclusion that conventional techniques for creating a pendulum (including a pendulum-based measurement system utilizing existing roller bearings) for accurately measuring the energy released from the mandibles were grossly insufficient and inaccurate. Indeed, any attempts at a measurement was made exceedingly difficult due to the size, speed, and acceleration of the trap-jaw ant’s mandibles – an understandable conclusion given the tips of the mandibles accelerate at a speed greater than a bullet fired from a common handgun. The energy generated by the mandibles on their target could not be accurately determined through the use of common technologies using standard methods with a common rotational bearing. Data taken was compromised by the energy required to overcome initial friction and moment of inertia of the traditional bearings in earlier designs of the test assembly.
Working in Dr. Patek’s laboratory at Duke University, Jorge’s hope was to design a novel pendulum-based measurement device that required a reduced or frictionless point of rotation. Thinking “outside the box”, he landed upon a new technology – air bearings – as a possible solution. Following a series of design and application discussions with the engineers at OAV, he knew he was on the right track. Subsequent tests have proven him correct.
By replacing the traditional roller bearing at the fulcrum of the dual rigid pendulum test assembly with the OAV Air Roller Bearing, Jorge was able to overcome the hurdle presented by traditional bearings in collecting quality test data. His conclusions were clear: “friction has a large effect on energy measurement at these scales (micro-joules) …and…the amount of energy measured using the OAV air bearings is at least six times greater than when we used traditional ball bearings.” The clear corollary to this conclusion is the obvious loss of energy lost to the traditional bearings rotational motion and the long-term advantages of utilizing air bearings over traditional ones. Jorge also concluded that while the air bearing is clearly more costly than traditional bearings, one can “justify (it’s use) with savings in time by eliminating maintenance between tests and the precision and accuracy that is impossible with traditional bearings.” OAV’s engineers concur. The use of air bearings may be more costly initially but they reduce long term costs through less maintenance and down time (and associated labor) costs, increased long term reliability, and accuracy.
OAV engineers have similar stories in much of their supportive work for University and corporate based researchers. Whether one is testing the energy generated by the trap jaw ant mandible strike or the energy generated by the wings of a common house fly, OAV is working to supply solutions for the future.
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Jorge, J. F., Bergbreiter, S. and Patek, S. N. (2021). Pendulum-based measurements reveal impact dynamics at the scale of a trap-jaw ant. J Exp Biol jeb.232157.
This material is based on work supported by the U.S. Army Research Laboratory and the U.S. 592 Army Research Office under contract/grant number W911NF-15-1- 0358.