thumb|300px|The flow of air causes a lifting force on the object, allowing for non-contact adhesion
A '''Bernoulli grip''' is a subtype of the Air-Flow (Air-Jet) type of the pneumatic gripping devices,<ref name="mykhailyshyn2022systematic">{{Cite journal | last1 = Mykhailyshyn | first1 = R. | last2 = Savkiv | first2 = V. | last3 = Maruschak | first3 = P. | last4 = Xiao | first4 = J. | title = A Systematic Review on Pneumatic Gripping Devices for Industrial Robots | year = 2022 | volume = 37 | number = 3 | pages = 201–231 | journal = Transport | doi = 10.3846/transport.2022.17110 | url = https://doi.org/10.3846/transport.2022.17110| doi-access = free }}</ref> which uses airflow to lift an object without physical contact. Such grippers rely on the Bernoulli airflow principle. While an accelerating, increasing speed, airstream has a low downstream static pressure, the sharp turn from linear to radial flow is the cause of a region of very low pressure around the blower exit hole. This is the cause of a net force on the object in the direction normal to the side with higher local pressure. A Bernoulli gripper takes advantage of this by maintaining this negative pressure at the gripper face compared to the ambient pressure below the sample, while maintaining an air gap between the gripper and the object being held. There are two main subtypes of Bernoulli grippers that have the greatest differences in both design and characteristics: nozzle with a developed surface of the end face ''(Bernoulli gripping device with a cylindrical nozzle)'' and the ''Ejection Bernoulli gripping device''.
{{gallery |title=Subtypes of Bernoulli grippers |width=320 |height=240 |File: Cylindrical Bernoulli.png|Diagram of a nozzle with a developed surface of the end face (Bernoulli gripping device with a cylindrical nozzle), where 1 - gripper body, 2 - object, and 3 - friction elements. |File: Ejection Bernoulli.png|Diagram of the Ejection Bernoulli gripping device, where 1 - gripper body, 2 - conical insert, 3 - circular nozzle, and 4 - object. }}
[[File:Jet_gripper_air-flow.jpg|thumb|300px|Smoked air-flow of modified Bernoulli-based gripper for grasping textile materials <ref name="mykhailyshyn2022gripping">{{Cite journal | last1 = Mykhailyshyn | first1 = R. | last2 = Savkiv | first2 = V. | last3 = Majewicz Fey | first3 = A. | last4 = Xiao | first4 = J. | title = Gripping device for textile materials | year = 2023 | volume = 20 | number = 4 | pages = 2397–2408 | journal = IEEE Transactions on Automation Science and Engineering | doi = 10.1109/TASE.2022.3208796 | bibcode = 2023ITASE..20.2397M | url = https://doi.org/10.1109/TASE.2022.3208796| url-access = subscription }}</ref> <ref name="mykhailyshyn2025vibration">{{Cite book | last1 = Mykhailyshyn | first1 = R. | last2 = Romancik | first2 = J. | last3 = Harada | first3 = K. | last4 = Majewicz Fey | first4 = A. | chapter = Vibration Vanquished: Enhancing Grasping of Deformable Objects with Jet Gripper Technology | title = 2025 IEEE 21st International Conference on Automation Science and Engineering (CASE) | year = 2025 | pages = 2874–2880 | chapter-url = https://doi.org/10.1109/CASE58245.2025.11164006 | location = Los Angeles, CA, USA | doi = 10.1109/CASE58245.2025.11164006 | isbn = 979-8-3315-2246-9 }}</ref>. By redirecting air flows, it is possible to eliminate vibration of materials during their grasping and manipulation by robots.]]
==Applications== Commercially available Bernoulli grips are commonly used to handle rigid sheet like material such as silicon wafers in circuit board manufacturing, or photovoltaic cell components.<ref>{{Cite book | last1 = Brun | first1 = X.F. | last2 = Melkote | first2 = S.N. | title = 2006 IEEE 4th World Conference on Photovoltaic Energy Conference | chapter = Evaluation of Handling Stresses Applied to EFG Silicon Wafer using a Bernoulli Gripper | publisher = George W. Woodruff Sch. of Mech. Eng.; Georgia Inst. of Technol., Atlanta, GA | date = May 2006 | pages = 1346–1349 | location = Waikoloa, HI | doi = 10.1109/WCPEC.2006.279680 | isbn = 1-4244-0017-1 }}</ref><ref>{{Cite web | last = Osborne | first = Mark | title = New Product: Bernoulli Gripper from Festo enables contactless handling | publisher = PVTech | date = 8 February 2010 | url = http://www.pv-tech.org/product_reviews/new_product_bernoulli_gripper_from_festo_enables_contactless_handling }}</ref> Since the grip is contactless, this form of gripping lends itself to handling sterile material to prevent chemical and/or biological contamination. Research has been done into using Bernoulli grippers to transport sample sheet foodstuffs in a food processing context,<ref name="grimsby">{{Cite web | title = Airflow (Bernoulli) Grippers for Flat Sheet Foods | publisher = Food Refrigeration & Process Engineering Research Centre, The Grimsby Institute of Further & Higher Education | url = http://www.grimsby.ac.uk/documents/frperc/projects/airflow.pdf | accessdate = 25 May 2011}}</ref> although this work found difficulties as the flexible foods would vibrate against the gripper, deforming and alternately blocking the gripper and/or being blown away from the airway. However, the addition of an anti-vibration grid to the gripper design allowed the use of this technology for grasping textile objects.<ref name="mykhailyshyn2022gripping"/> Further, the surface of the anti-vibration grid was optimized to increase the lifting force and completely remove the vibration of the grasping material.<ref name="mykhailyshyn2025vibration"/> The Bernoulli grip is also being investigated as a non-contact adhesion mechanism for wall-climbing robots.<ref>{{Cite magazine | last = Ackerman | first = Evan | title = Robot Uses Supersonic Jets of Air to Stick to Almost Anything | magazine = IEEE Spectrum | date = 24 May 2011 | url = https://spectrum.ieee.org/robot-uses-supersonic-jets-of-air-to-stick-to-almost-anything | access-date = 25 May 2011}}</ref>
==References== {{reflist|2}}
Category:Aerodynamics Category:Fluid dynamics