Determine
Robot Interfaces
Robots have a standard mounting hole pattern for
mounting the gripper or EOAT, usually a
bolt-hole-patterned configuration of tapped
holes. You can bolt your EOAT with a flat plate,
or take advantage of a manual quick change chuck,
which requires shutdown and lockout of the
robotic system. These chucks, featuring quick
pneumatic and electrical connectors as well as
tightening levers, allow EOAT change out without
tools. Also available are fully automatic
hands-free chucks. A J-Box provides the
electrical interface, indicating, terminating
and troubleshooting gripper sensors, or
combining sensor inputs into one output, which
employs a logic sequence to assess sensor
readings. A robotic valve box may be needed for
containment of additional vacuum and air
circuits.
Configure the
Gripper Footprint
From your chosen form of interface, you'll need
to construct the framework or footprint for the
grippers, allowing them to reach various
securing points of a blank or part. First,
determine stability and flexibility of the work
piece, what obstructions are present during
pick-up, what secondary operations are needed
and method of drop-off. Critical is the part
weight, cell layout, robot payload capacity and
reach. Recommended is a lightweight, modular,
aluminum framework easily adjustable to
accommodate changes required during trial runs.
Construct the framework with various brackets
and connectors configured to the outside
dimension of your part to allow for securing all
sides of the part. Once EOAT is refined and
proven, any extra framework can be reduced or
eliminated.
Mount Clamps,
Brackets and Extensions
With your framework complete, choose adjustable
clamps and brackets for mounting to all sides of
the partframe profile. This provides maximum
flexibility. Then choose tubular arms or
extensions that allow for height and angle
adjustments to reach every possible area of the
part for optimal gripping. Whatever type of
gripper you choose, incorporate the proper types
of mounting mechanisms-mechanical adapters,
brackets or manifolds-for that gripper.
Select the
Part-Securing Method-Grippers or Fingers
This describes the actual mechanical
means-pneumatic grippers, pliers or fingers-by
which your newly constructed part handler
contacts the part. Grippers normally are
required for heavy and very flexible parts or
when a large pulling force is necessary.
Grippers
also find use on parts or sheet with holes or
porosity, making vacuum-cup usage impractical.
For most applications, however, vacuum-cup
securing is most cost-effective. Most surfaces,
even textured, can be secured by specifying the
proper type and size of vacuum cup. At times,
vacuum cups are the initial and primary means of
part pick-up, then gripper fingers flip behind
the part for added support while moving parts
overhead or at high speeds.
Select the
Right Vacuum Cup
Some common vacuum-cup shapes include oval,
flat, 11/2-bellows, and 21/2-bellows. Oval cups
are useful when the work piece is long and narrow
or if the work piece has raised ribs or edges.
Flat vacuum cups (Fig. 1) are used for flat work
pieces with smooth to slightly textured
surfaces. They hold up best to shear when a
horizontal load is applied and offer a faster
response time than bellows-styled cups.
| The
11/2-bellows vacuum cups (Fig. 2) provide
a flexible sealing lip for work pieces with
irregular, smooth or contoured surfaces.
In addition, they work well with slightly
flexible surfaces. The bellows provide
dampening and help protect sensitive work
pieces. The 21/2-bellows vacuum cup
(Fig. 3) is used for maximum part
compliance and dampening. Vacuum cups are
made from a variety of materials, each
with specific properties. (See table for
characteristics of each.) For high
abrasion and wear resistance, choose
polyurethane. For higher heat applications,
choose silicone or Viton. Nitrile provides
good overall performance in a variety of
conditions. Once you've chosen the style
and material based on environmental and
work piece conditions, you can size your
vacuum cups and determine the lift
capacity using the following basic
formulas. An irregularly shaped work piece
or one subjected to high accelerations can
adversely affect lift capacity. |
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Sizing Vacuum
Cup Diameter
Diameter of vacuum cup (cm) = D = 2 x v(A ÷ p)
where:
A = Vacuum cup area (cm2) = [(m ÷ n) x 10 x S]
÷ P
m = Mass (N)
n = Number of vacuum cups
P = Vacuum pressure (kPa)
S = Safety factor (use 1 for theoretical,
8 for horizontal lift and 4 for vertical lift)
For example:
Workpiece mass = m = 50 lb. = 50 x 4.45 = 222.5
N
P = -80.6 kPa
n = 4
S = 1
A = [(222.5 ÷ 4) x 10 x 1] ÷ 80.6 = 6.9 cm2
D = 2 x v(6.9 ÷ p) = 2.96 cm = 29.6 mm
29.6 mm is the theoretical minimum
vacuum-cup diameter.
Lift Capacity of
Vacuum Cups
Theoretical lift per pad (N) = [(P x A) ÷ 101]
x S x 10.13 where:
P = Vacuum pressure (kPa)
A = Area of vacuum cup (cm2)
S = Safety factor (use 1 for theoretical,
8 for horizontal lift and 4 for vertical lift)
For example:
Vacuum pressure = P = -80.6 kPa
Area of vacuum cup = A = 176.7 cm2 (for a
150-mm-dia. cup)
Safety Factor = S = 1
Lift = [(P x A) ÷ 101] x S x 10.13 = [(-80.6 x
176.7) ÷ 101] x 1 x 10.13 = 1428 N
1428 N ÷ 4.45 = 321 lb.
These formulas are based upon actual test data.
Due to varying accelerations of the workpiece,
they should be used for reference only.
Put It All
Together
With these basics of modular tooling
construction, the next step is sourcing
individual components or gripper kits, which
simplify EOAT configuration by providing
preselected parts and requiring minimal layout
or machining. If time and resources are short,
select a provider to build the robotic tool
built. This option is best for more complex
applications. Then, plan for the actual tooling
installation, ideally in a period of scheduled
machinery shutdown. Assemble all vital parties
such as the press supplier, the tool-and-die
maker, robot supplier, gripper supplier and
maintenance personnel who will be responsible
for keeping the line running. MF |
