Gripping Technology Research Articles

Design, Analysis and Fabrication of Pick and Place Robotic Arm with Multipurpose

Abstract: This project is to design, develop and fabricate a "pick and place robotic arm" using Raspberry pi controller. It will pick and place an object from source to destination safely. This robot has a gripping technology that is used to lift, hold, grasp, and replace materials from one place to another. This robotic has revolute joints that allow the angular movement of the adjacent joint. The objective of this project is to design and build a more compact, usable and cheaper pick and place robotic arm for educational purpose. It uses Raspberry pi as the control system to control all the activities. Inputs to the Robotic arm are predefined. In the project we are applying this concept to the design of pick and place robotics system using SolidWorks Soft motion software. The software is used to design a Cartesian robot and an articulated industrial robotic arm with different grippers. The robot was designed using the SolidWorks’ 3D CAD software to shorten the robot development time, and improve the speed and quality of the robot design.

Research on Visual Localization and Gripping Technology of Robotic Arm Based on Deep Learning

With the continuous development of industrial automation, robotic arms are more and more widely used in production lines. In order to realize the autonomous positioning and grasping function of robotic arm, this paper studies the visual positioning and grasping technology of robotic arm based on deep learning. The deep learning algorithm processes and analyzes the image, realizes the automatic identification and localization of the target object, and then guides the robotic arm to carry out accurate grasping. The experimental results show that this technology can effectively improve the positioning accuracy and grasping success rate of the robotic arm, which provides strong support for the intelligent upgrade of industrial automation production lines.

Research progress of automatic grasping methods for garment fabrics

Purpose The purpose of this paper is to gain an in-depth understanding into the research progress, hot spots and future trends in smart gripping technology in the field of apparel smart manufacturing.Design/methodology/approach This work scrutinised the current research status of the five automatic grasping methods for garment fabrics including the pneumatic suction grasping, the electrostatic grasping, the intrusive grasping and the dexterous grasping. Specifically, the principles, characteristics, main devices and the impact on garment production were discussed.Findings In particular, soft finger of the dexterous grasping method has good flexibility and adaptability in the process of fabric grasping, which provides a new solution for garment production automation. Up to now, the reviewed method in general exhibit good grasping speed, high grasping stability and flat grasping process. However, in the face of complex fabric materials which are thin and flexible and do not return their original shapes when deformed in practical applications, the gripper for automatic fabric grasping need new technological breakthroughs in the positioning accuracy, grab efficiency and flexible grasping.Originality/value The outcomes offered an overview of the research status and future trends of the automatic grasping methods for garment fabrics in the field of apparel intelligent manufacturing. It could not only provide scholars with convenience in identifying research hot spots and building potential cooperation in the follow-up research but also assist beginners in searching core scholars and literature of great significance.

Optimization of Outer Diameter Bernoulli Gripper with Cylindrical Nozzle

Gripping and manipulating objects using non-contact and low-contact technologies is becoming increasingly necessary in manufacturing. One of the promising contactless gripping technologies is Bernoulli gripping devices for industrial robots. They have many advantages, but when changing the nozzle geometry, it is difficult to find the optimal parameters of the outer diameter of the gripper and its operating parameters. Therefore, the article presents a model for numerical simulation of the dynamics of airflow in the nozzle of the Bernoulli gripping device and in the radial gap between its active surface and the surface of the object of manipulation. Reynolds-averaged Navier–Stokes equations of viscous gas dynamics, SST-model of turbulence, and γ-model of laminar-turbulent transition were used for this purpose. The technical requirements for the design of the nozzle of Bernoulli jet gripping nozzles are determined and variants of their constructive improvement are offered. According to the results of numerical simulation in the Ansys-CFD software environment, the optimal diameter of the Bernoulli gripping device and the influence of the geometric parameters of the nozzle on the nature of the pressure distribution in the radial gap and its lifting force were determined. Determined the optimal parameters of the height of the gap between the object of manipulation and the Bernoulli gripping device using C—Factor, which will allow efficient operation of Bernoulli gripping devices during automated handling operations using industrial robots.

Karla: A Simple and Affordable 3-D Printed Body-Powered Prosthetic Hand with Versatile Gripping Technology

Losing a hand can significantly impact an individual’s physical and emotional well-being. Prosthetic hands can help restore some function and independence for individuals who have lost a hand. However, the prosthetic hands available on the market are prohibitively expensive, especially for developing countries, such as Indonesia. Commercial electronically powered prosthetic hands can be expensive, having prices ranging from $25,000 to $75,000 and annual maintenance costs ranging from $500 to $3000. In contrast, body-powered prosthetic hands are generally cheaper, ranging from $2000 to $10,000, but are still considered expensive for many people in developing countries. To make prosthetic hands more accessible, we have designed a body-powered prosthetic hand, “Karla”, using affordable materials and with as few components as possible. This report presents our proposed designs, the innovations, the parts in detail, and experiences using the designed prosthetic hand. The highlight of our design is a novel whippletree-like mechanism that utilizes the 3-D space to contract the fingers of the prosthetic hand.

Design of Parts Flexible Palletizing System

Part palletizing packaging is an important part of the logistics industry. Traditional manual palletizing can no longer meet today’s order volume. In order to improve the production efficiency of the palletizing process, a part flexible palletizing system was designed. The S7-1200 PLC was used as the controller, and the high-precision altimeter and length measurement photoelectric sensors were used to check the parts in real time, and the manipulator and the end actuator were used for grasping and stacking. The end actuator with multi-axis synchronous control technology is adopted to realize simultaneous grasping of multiple boxes of different specifications, which greatly improves the production efficiency and automation level of part palletizing. This flexible palletizing system and robotic gripping technology greatly improves the efficiency of gripping small objects and also allows for extended applications in the field of FAST disassembly and handling robots.

Boosting productivity with tech

Boosting productivity with tech

Marine Robotics for Deep-Sea Specimen Collection: A Systematic Review of Underwater Grippers.

The collection of delicate deep-sea specimens of biological interest with remotely operated vehicle (ROV) industrial grippers and tools is a long and expensive procedure. Industrial grippers were originally designed for heavy manipulation tasks, while sampling specimens requires dexterity and precision. We describe the grippers and tools commonly used in underwater sampling for scientific purposes, systematically review the state of the art of research in underwater gripping technologies, and identify design trends. We discuss the possibility of executing typical manipulations of sampling procedures with commonly used grippers and research prototypes. Our results indicate that commonly used grippers ensure that the basic actions either of gripping or caging are possible, and their functionality is extended by holding proper tools. Moreover, the approach of the research status seems to have changed its focus in recent years: from the demonstration of the validity of a specific technology (actuation, transmission, sensing) for marine applications, to the solution of specific needs of underwater manipulation. Finally, we summarize the environmental and operational requirements that should be considered in the design of an underwater gripper.

Soft Grippers for Automatic Crop Harvesting: A Review.

Agriculture 4.0 is transforming farming livelihoods thanks to the development and adoption of technologies such as artificial intelligence, the Internet of Things and robotics, traditionally used in other productive sectors. Soft robotics and soft grippers in particular are promising approaches to lead to new solutions in this field due to the need to meet hygiene and manipulation requirements in unstructured environments and in operation with delicate products. This review aims to provide an in-depth look at soft end-effectors for agricultural applications, with a special emphasis on robotic harvesting. To that end, the current state of automatic picking tasks for several crops is analysed, identifying which of them lack automatic solutions, and which methods are commonly used based on the botanical characteristics of the fruits. The latest advances in the design and implementation of soft grippers are also presented and discussed, studying the properties of their materials, their manufacturing processes, the gripping technologies and the proposed control methods. Finally, the challenges that have to be overcome to boost its definitive implementation in the real world are highlighted. Therefore, this review intends to serve as a guide for those researchers working in the field of soft robotics for Agriculture 4.0, and more specifically, in the design of soft grippers for fruit harvesting robots.

Variable stiffness soft pneumatic grippers augmented with active vacuum adhesion

Soft pneumatic grippers (SPGs), made of highly stretchable elastomer materials with internal fluidic channels, are a popular soft robotic gripping technology, and have been configured as soft bending fingers for passively compliant grasping applications. It is challenging, however, for current SPGs to grip both flat, concave, and convex surfaces. Controllable adhesion augmented SPGs are promising solutions. We aim to develop a composite gripper structure that could enable SPGs with the capability to lift flat, concave, and convex surfaces using pneumatic inputs only. To this end, we present PneuIVAVS, a layer-jamming induced active vacuum adhesion (VA) augmented and variable stiffness (VS) fiber-reinforced SPG. This integrated PneuIVAVS design has enabled the gripper to generate a VA force without the requirement that all suction units should work. Also, a VA force analytical model and a shape-locking model of the PneuIVAVS design were developed and experimentally validated. In addition, the PneuIVAVS gripper presented good performance on gripping both flat, concave and convex objects with a range of contacting areas. According to the load capacity test, the gripper could grasp a maximum of approximately 470 g, 683 g, and 268 g when handling flat, concave, and convex surfaces respectively. Besides, the gripper could grasp curved surfaces with a minimum radius of curvature between 30 and 40 mm. The PneuIVAVS concept, design, and results in this work have potential to promote the applications of SPGs and VA grippers in various material handling and robotics tasks.

Electroadhesion Technologies for Robotics: A Comprehensive Review

Electroadhesion (EA) is an electrically controllable adhesion mechanism that has been studied and used in fields including active adhesion and attachment, robotic gripping, robotic crawling and climbing, and haptics, for over a century. This is because EA technologies, compared to other existing adhesion solutions, facilitate systems with enhanced adaptability (EA is effective on a wide of range of materials and surfaces), reduced system complexity (EA systems are both mechanically and electrically simpler), low energy consumption, and less-damaging to materials (EA, combined with soft materials, can be used to lift delicate objects). In this survey, we comprehensively detail the working principle, modeling, design, fabrication, characterization, and applications of EA technologies employed in robotics, aiming to provide guidance and offer potential insights for future EA researchers and applicants. Joint and collaborative efforts are still required to promote the in-depth understanding and mature employment of this promising adhesion and gripping technology in various robotic applications.

Conceptual exploration of a gravity-assisted electrorheological fluid-based gripping methodology for assistive technology

Gripping devices help patients carry out everyday tasks and increase their independence. However, there seems to be a lack of bionic gripping technologies that can fully adapt to any possible shape, as the use of artificial fingers and predetermined grip settings limits the operating space. The development of a more agile device, which is operated by a simple control paradigm, could greatly benefit users. An electrorheological (ER) fluid system should be able to adapt to the shape of an object and then hold that configuration. The aim of this study was to explore if a conceptual prototype of an ER system could hold a geometric shape when it is activated. A test rig was constructed with a moving part (set in different silicone oils) that could be displaced using a tensometer. Silica particles were dispersed in the silicone oils, and a field with a voltage of 4 kV mm−1 was generated to activate the fluid. The results show that the developed system can support an increased force when activated and hold a simple geometric position without any noticeable delay. This outcome provides an initial proof of concept for a possible new (gravity-assisted) gripping approach using smart fluids, which could be developed with materials that are biocompatible and widely available.

Bioinspired Photodetachable Dry Self-Cleaning Surface.

Geckos have adapted to the complicated natural environment with its excellent climbing ability. Current artificial gecko-inspired synthetic adhesives (GSAs) mimic gecko's attach-detach mechanism by creating anisotropic and hierarchical structures. Easy detachment and high self-cleaning capability are still the unsolved problems in GSAs. This study presents an unprecedented photodetachable mechanism of making bioinspired smart surfaces utilizing carbon dot (CD)-doped polydimethylsiloxane (PDMS) composites. Under ultraviolet (UV) irradiation, it could be triggered up to 80.46% reduction of adhesion force between PDMS-CDs bioinspired surfaces and contaminating particles. A load-drag-pull (i.e., LDP) test mimicking gecko's locomotion was adopted to test the dry self-cleaning capabilities of these bioinspired surfaces, where the falling rate of the model contaminates (PS micropellets; average size in diameter ∼8 μm) can reach up to 54.83% after seven repeated steps under UV irradiation. The significantly improved dry self-cleaning capability is attributed to the photothermal effect of CDs inside the PDMS matrix. The mechanism proposed in this work will find its applications in the realms of climbing robots, space adhesive devices, and self-cleaning, advanced gripping technologies for pick and place or assembly.

Soft-Acting, Noncontact Gripping Method for Ultrathin Wafers Using Distributed Bernoulli Principle

The handling of ultrathin wafers ( $ thickness) is a challenging task since these are among the thinnest and most fragile materials. This paper provides a soft-acting and noncontact gripping technology for ultrathin wafer based on the distributed Bernoulli principle, and also proposes an experimental measurement method for evaluating the performance. A distributed Bernoulli gripper for ultrathin wafers is designed, and the characteristics of the gripper are studied via theoretical analysis and experiments. Three performance indices for evaluating the properties of the soft gripping: deformation, vibration, and stress are presented. Through measurement experiments, the effects of the key operational parameters consisting of air flow rate and gap height on the performance indices are investigated. Based on the experimental data, the appropriate parameters settings are obtained. The comparison to present grippers reveals that the proposed gripping technology is superior in soft gripping thin and fragile materials. This paper provides guidance for implementing the distributed Bernoulli principle in practical applications of soft-acting and noncontact gripping for thin and fragile materials. Note to Practitioners —This research of developing a new soft-acting and noncontact gripper was motivated by the problem of gripping of fragile workpieces like ultrathin wafers. The traditional contact handling method often leads to defective products including cracks, contact contamination, or mechanical wears, and the existing Bernoulli gripper has the shortcoming of resulting in large deformation as the impact of center negative pressure force, and the collision of wafer onto the gripper as the sharp lifting force curve. In this paper, we propose a soft-acting and noncontact gripper for ultrathin wafer based on the distributed Bernoulli principle. A systematic approach which consists of modeling, measurement, and evaluation is provided for the gripping techniques. We present three performance indices for evaluating the characteristics of soft gripping, and experimentally study the effect of supply flow rate and the gap height on the performance of deformation, vibration, and stress in the thin and fragile wafers. It is found that an optimal value exists. We then verify the merit in gripping ultrathin wafers softly with a small deformation or stress via comparison with two Bernoulli grippers and a combined gripper. The new gripper plays an important role in handling thin and fragile materials.

Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration

AbstractSoft robotic grippers have gained a growing interest due to their inherent compliance which passively adapts to a variety of object shapes and electroadhesion (EA) has attracted particular attention due to its versatile, low impact adhesion. EA shows potential for the precise manipulation of thin and flexible substrates such as plastic films, which is crucial to the advancement of flexible electronics fabrication. However, the rapid release of substrates is a challenge with EA due to the residual charge and relatively slow dielectric natural relaxation time that exists when the applied voltage switched off. Here, a novel soft gripping technology that integrates a dielectric elastomer actuator with an EA into a soft, monolithic structure to achieve rapid de‐adhesion is presented. This inherently compliant device exploits resonant excitation to minimize the release period to a range of 100–500 ms, which is an improvement of at least two orders of magnitude compared with conventional EA release. The developed end effector demonstrates rapid and robust adhesion/de‐adhesion performance in a lightweight and compact form, with simplified control and low energy consumption and hence has wide application to a variety of robotic manipulation tasks.

Evaluation of a New Stapler with Unique Surface Gripping Technology

Evaluation of a New Stapler with Unique Surface Gripping Technology

Strength and Fracture Behavior of Ultrathin Pt Wires

Ultrathin metallic wires having defects may show much lower strength compared to the strength of the wire material. To characterize ultrathin Pt wires having the nominal diameter of 625 nm, tensile test of the wires was performed by developing a testing platform and a gripping technology. Fracture stress determined by the tensile test showed much higher value compared with that of bulk Pt. However, the fracture stress of some of the wires was lower than the yield stress of the wire determined by the bending test. From the observation of the fracture surfaces, it was found that the lower fracture stress of the wires was due to the defects in the wires and such wires showed brittle fracture behavior.

Artificial muscles and soft gripping: a review of technologies and applications

PurposeThe purpose of this paper is to describe a range of artificial muscle and soft gripping technologies for robotic applications.Design/methodology/approachFollowing a short introduction, this paper first discusses the role of air muscles and other pneumatic actuation technologies. It then considers electroactive polymer and shape‐memory alloys and finally discusses the prospects for various classes of electrohydrodynamic fluids.FindingsThis paper shows that a technologically diverse range of novel actuation techniques exist, or are under development, which can act as artificial muscles and soft grippers. They are based on pneumatics, shape changing materials and electrohydrodynamic fluids and have prospects to impart robots with improved or unique capabilities.Originality/valueThe paper provides an insight into developments in artificial muscle and soft gripping technologies. These are expected to play a vital role in future robot generations.

Technology Focus: Wellbore Tubulars (June 2012)

Technology Focus We wear small bands on our fingers for many reasons. The rings have many meanings; the wedding ring may be the most common. This band, signifying no beginning or end, represents a union or reminds the wearer that he or she is married. It is traditionally worn on the left hand, on the vena amoris, the digit that the Romans believed was connected directly to the heart. Puzzle rings, or gimmel bands, are another type of ring used as wedding bands that has dual meanings. The word “gimmel” comes from the Latin gemellus and means “twin” or “paired.” Engaged couples would each wear one piece of the puzzle ring and, upon marriage, join the two bands with another provided by the priest. Once joined, the bands formed a puzzle that, if removed, was difficult to piece back together. Deceit that led to infidelity was made more difficult because the wearer might not be able to put the puzzle back together. Wedding rings have different traditions in eastern and western cultures, but they always hold a strong mental connection for the wearers. Rings also tie us to our accomplishments or recollections. School rings and championship rings can tie us to a collegiate career or a significant athletic accomplishment. The purpose of these rings is to remember. I have always been inspired by a tradition that many Canadian engineers have of wearing an iron ring. The ring is worn on the little finger of the engineer’s dominant hand so that, when writing or tasking with the dominant hand, the engineer is reminded of his or her obligations. The tradition holds that the iron in the ring came from a bridge that failed and cost many lives. The ring is small and is designed to be a constant reminder. The tradition continues when the engineer retires; the ring is returned to service as an “experienced ring.” Preventing failures in our field is imperative for safety and economic operation. Learning from these failures, properly documenting and remembering them, is important for avoiding catastrophes. We may engineer a process, a method, or a particular part to reduce failures and enhance operations. Solid-expandable-tubular technology is a fairly new technology that is gaining more promising and important applications in oil- and gas-wellbore design. Constant improvements to the deployment of this technology are increasing its reliability and number of applications. Heat treatment of the expansion-cone material used in an expanding tubular is one such modification. The drillpipe-connection phase of the drilling operation can be one of the greater opportunities for failures and mishaps. An improperly handled connection procedure can damage drillpipe; stick a drillstring; and, in the case of managed-pressure drilling, induce an unwanted influx. One of the selected papers reviews a database of drillpipe-connection damage, and another reviews a method for making connections in the managed-pressure environment. Recommended additional reading at OnePetro: www.onepetro.org. SPE 147747 Quantification of Drillstring-Integrity-Failure Risk Using Real-Time Vibration Measurements by Yezid Arevalo, Schlumberger, et al. SPE 146959 Stability Analysis of Pipe With Connectors in Horizontal Wells by Guohua Gao, Shell, et al. SPE 146344 Development of Ball-and-Pocket Gripping Technology To Overcome Slip Handling Limitations by Justin Jarski, Canrig Drilling Technology, et al. SPE 148516 Post-Expansion Characterization of Expandable Tubular: Progress and Challenges by T. Pervez, Sultan Qaboos University, et al.

Flexible gripping technology for the automated handling of limp technical textiles in composites industry

A high level of cost-intensive manual tasks in the manufacturing process of composite parts impedes a further propagation of those innovative structures in important German industrial branches like the automotive sector or aviation. Especially the handling of semi-finished goods in several key process-chains could not be automated efficiently so far due to a great variety of materials and part contours as well as difficult handling properties of the limp, textile parts. Hence within the presented work a highly-flexible gripper system based on low-vacuum-suction is introduced, which is the result of a methodical investigation in the ideal gripping principle. Special actuators and an intelligent control strategy are combined into a selective gripping technology, which allows an automatic adaption of the pressure based holding force to different contours and materials, by closing certain apertures of a perforated plate. The experimental validation of a realized robotic end-effector shows that the challenging requirements of modern composite production could be fulfilled as the structural integrity of the technical textiles is preserved during the handling processes.