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Figure 1: Quick Change Chuck
Figure 2: “Smart” Junction Box
Figure 3: Framework
Figure 4a & 4b: Spring Loaded Vacuum Cup
Assembly and Gripper Finger Assembly
Figure 5: Rotary, Slide Table, and Parallel
Cylinders
Figure 6a and 6b: Sprue Plier Assembly and Sprue
Plier with Sensor Assembly
Figure 7: Sprue Cutter Assembly
Figure 8: Locator Pin Assembly and Photoelectric
Sensor Assembly
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Modular
End-of-Arm Tooling for Your Robot
By
John M. Westbeld, Design Manager >SAS<
Automation, LLC
Reprinted
with permission by Techologia Del Plastico, a
publication of B2Bportales. July/August 2002.
The success of
any robotics pick-and-place application depends
on how consistently its end-of-arm tooling
(EOAT) secures, manipulates, and releases the
parts and runner system. To build an EOAT that
suits your application and assure its success
you need a flexible system of modular
components. Modular components are preferred in
most cases because they are adjustable,
lightweight, and often-time less expensive.
The basis for any
modular system of EOAT components is how it
interfaces with the robot. Quick Change Chucks
can be mounted directly to the robot and can
facilitate quick EOAT changes (see figure 1).
The mating dovetail plate to the chuck is on the
EOAT and it quickly slides into the chuck and
locks and locates into place. The EOAT has quick
disconnect fittings that plug into the chuck for
your air and vacuum lines. Also, a
"smart" junction box is used for the
electrical interface with the robot (see figure
2). It has LED's to assist troubleshooting and
the inputs/outputs can be sinking (NPN),
sourcing (PNP), or dry contact.
The EOAT
framework consists of lightweight aluminum
extrusion and connectors that mount directly to
the dovetail plate (see figure 3). From this
framework you can mount the components used to
secure or manipulate the part.
Securing the
parts can be achieved by vacuum or some
mechanical means (see figures 4a and 4b).
Vacuum cups are
often the preferred method to secure the parts
(if they lend themselves to the application).
They are the least expensive option and most of
the time they secure parts best. The other most
common method to secure the parts is by means of
a mechanical gripper finger or parallel
cylinder. These are used in situations when
vacuum cups can't be used due to part contour or
texture. Some parts need to be manipulated to
remove them from the core, to get them out of
the press, or to interface with dunnage or a
fixture at part release. To do this the modular
component system must integrate various types of
pneumatic cylinders to perform desired motions
(see figure 5). Rotary cylinders, slide table
cylinders, and parallel cylinders are just a few
of the cylinders you have at your disposal to
manipulate the part.
As well as
securing the part you may have to secure the
runner system as well. Runner systems can vary
so it's a good idea to have the sprue pliers
adjustable (see figure 6a and 6b). As well, your
sprue plier can have a sensor in the jaw for
sprue/runner presence. With the sensor in the
jaw the size or integrity of the hot material is
not an issue. It will sense the sprue/runner
regardless.
Runner systems
may also need to be degated from the part. It is
desirable to do this with the EOAT whenever
possible to eliminate a downstream operation.
Sprue cutters can be incorporated into the EOAT
to cut various styles of gates (see figure 7).
Other modular
components that are useful in securing parts are
locator pins and photoelectric sensors (see
figure 8). The locator pins can be used to guide
the part while its ejected and to support the
part. Photoelectric sensors verify part or
runner presence or can be used to detect
obstacles.
A modular
component system for EOAT needs to be
lightweight so the total weight of the EOAT will
not exceed the operating payload of the robot.
Lighter EOAT also extends the performance and
life of the robot as well. By using lightweight
aluminum framework and components you don't have
to sacrifice strength for weight reduction.
Clamps can be made of injection molded plastic
composites to reduce weight also. The success of
any EOAT application depends on how well the
components perform their specified tasks and how
well the EOAT and robot work together. A modular
system designed specifically for plastic
injection molding will insure the greatest
possibility for success.
John Westbeld
is Design Manager for SAS Automation. He can be
reached at 937/372-5255.
Reprinted
with permission by Techologia Del Plastico, a
publication of B2Bportales. July/August 2002.
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