Robotic finger mimics human digits as it is heated and cooled

The team says the robotic finger could help to overcome some of the challenges encountered by researchers working in the ocean depths （Credit： Florida Atlantic University）

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Scientists at Florida Atlantic University have employed a novel thermal training technique to give robotic fingers a natural look and feel. With the ability to curve and straighten as it is heated and cooled， the researchers are hopeful their lifelike new creation will be put to use in underwater robotics and eventually， advanced prosthetic devices.

The researchers began with a 3D CAD model of a human finger. From this， they created a model of the digit and then 3D printed inner and outer molds， between which they placed a flexor and extensor actuator made from shape memory allow （SMA）， along with a position sensor.

The flexor actuator was trained to take the shape of a bent human finger when heated， while the extensor was trained to straighten out when heated. So by alternately heating and cooling the two actuators， the finger in could be made to bend and straighten. This was done through a process called Joule heating， which sees electrical currents pass through a heat-generating conductor.

One problem the researchers encountered was the time it takes for each actuator to cool again and resume its natural shape after being heated. Because of this， they are looking to undersea robotics as the finger‘s first port of call. In an underwater environment， thermal insulators fitted to the tip of the finger can allow water to flow throughout the cavity and more efficiently cool the actuators， which the researchers say greatly improves the operational speed of the device.

Eventually it is hoped that the approach can be used fin the development of better prostheses.

“We have been able to thermomechanically train our robotic finger to mimic the motions of a human finger like flexion and extension，” says Erik Engeberg， assistant professor at FAU. “Because of its light weight， dexterity and strength， our robotic design offers tremendous advantages over traditional mechanisms， and could ultimately be adapted for use as a prosthetic device， such as on a prosthetic hand.”

The research was published in the journal Bioinspiration & Biomimetics.

自動(dòng)翻譯僅供參考

機(jī)械手指能夠模仿人類手指受熱和手冷時(shí)的情形 Robotic手指模仿人類的？？數(shù)字，因?yàn)樗患訜岷蚦ooled

該小組說(shuō)，機(jī)器人的手指可以幫助克服一些研究人員在海洋深處工作所遇到的挑戰(zhàn)（圖片來(lái)源：佛羅里達(dá)大西洋大學(xué)）

科學(xué)家在佛羅里達(dá)大西洋大學(xué)已經(jīng)采用了一種新的熱訓(xùn)練技術(shù)給機(jī)器人的手指一個(gè)自然的外觀和感覺(jué)。隨著和拉直，因?yàn)樗患訜岷屠鋮s能力曲線，研究人員希望他們的栩栩如生的新的創(chuàng)造將投放水下機(jī)器人，最終，先進(jìn)的假肢裝置使用。

研究人員開始了與人類的三維CAD模型手指。從這一點(diǎn)，他們創(chuàng)建的數(shù)字的一個(gè)模型，然后三維印刷內(nèi)和外模，在它們之間它們置于一個(gè)屈肌和伸肌激勵(lì)器由形狀記憶制成允許（SMA），還有一個(gè)位置傳感器。

屈致動(dòng)器被訓(xùn)練采取彎曲的人的手指的形狀，當(dāng)加熱，而伸肌被訓(xùn)練理順加熱時(shí)。因此，通過(guò)交替地加熱和冷卻所述兩個(gè)致動(dòng)器，所述手指可以作出彎曲和伸直。這是通過(guò)一個(gè)稱為焦耳加熱過(guò)程，看到的電流通過(guò)發(fā)熱導(dǎo)體完成。研究者遇到

一個(gè)問(wèn)題是它需要對(duì)每個(gè)致動(dòng)器，以再次冷卻，加熱后恢復(fù)其自然形狀的時(shí)間。正因?yàn)槿绱?，他們正在尋找?guó)際海底機(jī)器人呼叫的手指的第一個(gè)端口。在水下環(huán)境中，熱絕緣體裝配到指尖可以允許水流在整個(gè)腔和更有效地冷卻所述致動(dòng)器，其中，研究人員表示極大地提高了裝置的運(yùn)行速度。

最終，它希望該方法可用于散熱片更好的假體的發(fā)展。

“我們已經(jīng)能夠熱機(jī)械訓(xùn)練我們的機(jī)器人手指模仿人類手指的動(dòng)作就像屈伸，”埃里克Engeberg說(shuō)，副教授FAU。 “由于其重量輕，靈巧和力量，我們的機(jī)器人設(shè)計(jì)提供了極大的優(yōu)勢(shì)，比傳統(tǒng)的機(jī)制，最終可能適于用作假肢裝置，如一個(gè)假手?！?/p>

這項(xiàng)研究發(fā)表在雜志Bioinspiration和放大器; 。仿生學(xué)