Key Factors for Building a Robotic End-of-Arm-Tool
Richard Petz, PE, General Manager for >SAS< Automation

"We need our robot to do more - handle multiple tasks, precision placement or awkward parts, but don't know where to begin." How many times have you heard that concern? It is a reality that efficient automation is the key to cost effective manufacturing in today's global economy. While robots certainly can reduce costs and speed production, the key that is often overlooked, is the value that the robotic end-of-arm tooling brings to your production line.

Simply, the End-of-Arm Tool must compliment the robot. When designing or building an EOAT, the overall results will depend on: 

1. How well the EOAT secures, manipulates, holds, and handles the part throughout the robot motion
2. How consistent the operation performs.
3. The reliability of each individual component on the EOAT.

When it comes to being cost effective, the proper combination of capital investment, labor content and the speed of operation will provide the best result. Although most times the EOAT is a relatively small investment compared to the other components of a work cell, the proper design and construction can make a big difference. Thus, it is the ease, consistency and flexibility, versus people, that provides the motivation behind the EOAT to move and assemble parts.

End-of-Arm Tooling specialists have the ability to match your EOAT to your robot cost effectively. This assistance can come from helping you to select the proper components for a less complicated EOAT to build in-house, or by purchasing a custom EOAT for more complex jobs. Specialists will have proven concepts for manipulating parts for many operations. Robot companies can be limited to tools just for their robot and distributors typically offer only a partial segment of EOAT parts or usually are lacking in technical support.

To be successful in your EOAT building and application, keep the following factors in the forefront:

Basic EOAT Configuration Requirements

The proper use of components and design will have a major impact on the total project's cost savings, as a well designed EOAT will perform many functions. When choosing the End-of-Arm Tool, the following four concepts are imperative to success:

Modular components - Allow for standard, off-the-shelf components and spare parts; no need to build your own custom parts when approximately 2500 different stock components already exist. 

Weight - Don't overload the robot. Lightweight tooling will reduce robot wear and maintenance costs, as well as allow maximum traverse speeds on robots. 

Flexible - Allows for multiple fine adjustments along slotted frames, slotted and rotational clamps 

Rigid/durable - Extruded aluminum profiles provide long life, low maintenance and repeatable accuracy along with lightweight.

Interfacing with the Robot 

Building a modular EOAT component system begins with the interface with the robot. The use of quick change chucks, which can be mounted directly to the robot arm with mounting hole patterns to match the robotic arm, are used for short runs and fast changeover time. A mating dovetail plate on the EOAT quickly slides into the chuck and locks and locates into place. This method will have quick disconnect fittings that plug into the chuck for air and vacuum lines. A "smart" junction box may also be used for the electrical interface with LED's to assist troubleshooting. Long run tools can be bolted directly to the robot arm with the proper plate. 

Constructing the EOAT 

Whether long run or short run, the next step is to mount the rigid extruded, aluminum profile to the dove tail plate based on the dimensions and weight required for the EOAT. Keep in mind that the payload includes both the EOAT and the part being manipulated. Gripping components can then be added to the frame with a variety of standard adjustable clamps. The combination of the frame, clamps and grippers should allow for adjustment in three axis. Secure locking nuts in the framework will ensure long term repeatability 

Gripping Solutions 

Gripping components, such as pneumatic gripper fingers vacuum cups and air grippers are the components that will be mounted on the frame to securely hold the part to be manipulated. 

The use of vacuum cups will provide the simplest and least expensive solution where the application presents a suitable part surface for a vacuum grip. The cups also come in various sizes, shapes, materials. Polyurethane, for example, is the choice for high abrasion and wear resistance, silicone or viton for higher heat applications and nitrile for good overall performance in a wide variety of conditions. Oval cups are useful when the part is long and narrow or if the work piece has raised ribs or edges. Flat vacuum cups are used for flat part with smooth to slightly textured surfaces. In general, they have a wide range of diameters for different-sized part. They also hold up best to shear when a perpendicular load is applied and have faster response time than the bellows-style cups. Bellows vacuum cups provide a flexible sealing lip for parts with irregular, smooth or contoured surfaces. They also work well with slightly flexible surfaces. 

Special cups are also available for more porous surfaces (such as corrugated or deeply grained) or non-marking applications (such as plastic Class A surfaces on auto parts). 

Pneumatic grippers are normally used for applications requiring more grip force or hard to reach areas on a part. Applications of both grippers and vacuum cups used together would be to pull large plastic parts from an injection mold or a high speed palletizing application. 

Custom End-of-Arm Tooling 

Many times parts need to be manipulated during material handling or packaging operations. In order to accomplish this, the modular component system must integrate various types of (1) pneumatic cylinders to perform desired motions such as rotary cylinders, slide table cylinders, and parallel cylinders, (2) special contoured nests or (3) cutting tools. 

When reviewing your overall robotic project, custom design and / or build should be considered under these conditions: (a) the complexity is beyond the in house ability, (b) overall labor hours are not available, (c) timing is short. 

A Robot is only as good as its EOAT! 

As the robot and EOAT are required to multi-task, they must compliment each other. The EOAT requires the robot to be repeatable, while the robot must have the EOAT grip, hold or position consistently as needed in the automation cell. The more you can do with an EOAT, the less that will be required of auxiliary operations and robotic movements. The ability of a robotic cell to function efficiently depends as much on the EOAT as it does on the robot. 

SAS Automation LLC 
>SAS< is a leading supplier of modular EOAT components & robotic gripper systems - capable of servicing any part and any robot. >SAS< manufactures in the USA "get a grip!", and distributes "nip it!" Nile sprue nipper line, and "GRIP IT!" Asian chucking/gripper line. >SAS< is ISO 9001:2000 Quality Certified. Specialists in robotic end-of-arm tooling & gripper systems, custom tools, automation cells, sprue nippers, CNC degating & Insert Mold tooling for manufacturing, packaging & plastics industries. Sales, service and support to: USA, Canada, Mexico, Europe.

Email: getagrip@sasgripper.com 
Web: www.sasgripper.com 
Toll Free: 888-727-EOAT (3628) 
Author: Richard Petz, PE is the General Manager for SAS Automation. R. Petz oversees all of the engineering, new product development, manufacturing and sales of robotic end-of-arm tooling. Petz is a professional engineer with a mechanical engineering degree from Clarkson University and MBA from the University of Dayton.

Published by Manufacturing Technology