Design & Manufacturing Guidelines & Capabilities
*Note: This document is intended
to highlight design and manufacturing guidelines and capabilities
in order to illustrate what the company can produce. This is not
an all encompassing document! Please contact ebm-papst Industries,
Inc. for further information: (860.674.1515 or sales@us.ebmpapst.com )
Contents
1. Design Standards
2. CAD capabilities
3. Tolerances
4. Materials
5. Plating and Finishing
6. Tooling
7. Fabrication
8. Assembly
9. First Article Inspections
1. Design Standards
All inner radii
on sheetmetal designs are formed using metric sizes. 1mm inner
bend radii are, by far, the most common size. As material gets
thicker and softer, larger bend radii must be used. We require
2mm and 3mm radius tooling for aluminum thicker than 18 gage,
(.040), to prevent cracking. We have a large stock of 1mm bend
tools, but a smaller selection of 2mm and 3mm tools. There may
be a lead time associated with certain 2 and 3mm bend tools.
Large, punched
grill-style openings, (finger guards), are difficult to keep flat.
Specifically, openings greater than 6” distorts the metal
such that the resulting “oil-canning” can make it
impossible to reliably control the height of the surface to within
.030”. Design alternatives include screw-on wire guards
and spot-welded perforated metal sheet.
In thin material
such as 18 and 20 gage material, countersinking screws should
be avoided if possible. There is not enough material thickness
to accept the height of the screw head such that the head of the
screw will be flush with the fastened surface. Rivets can be made
flush, even in thin material, and should be considered. (ebm-papst is
working with PEM engineers to develop a custom PEM nut design
that will remove this limitation, but until this is available,
avoid the countersunk screws if possible.)
Any cut-out
feature, (holes, rectangles, obrounds), will have distorted edges
if those edges are placed too close to a bend. A recommended distance
for cut-outs is 4 times the material thickness away from a bend.
A pressed inserted
component, such as a stand-off or a PEM nut, needs to be a certain
distance away from a bend to allow clearance for the insertion
tool. Typically the minimum distance from a stand-off centerline
to a bend is ½”, and .290” is the minimum distance
for a nut.
The silk-screening
process for labels is typically done after forming. It is therefore
important to allow silkscreens to be located on the outside of
a box rather than the inside. As an alternative, many customers
are switching to overlays (labels) as silk-screening is an expensive,
“art” work center.
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2. CAD Capabilities
We use Pro/Engineer
version 2001 as our primary CAD software. All modeling in Pro/Engineer
is performed in a sheetmetal-specific, solids-based environment
using integrated functionality for flat pattern generation. We
can read any version of Pro/Engineer files. For greatest efficiency,
the customer should model their products in the sheetmetal environment,
and should design using the 1mm bend radius standard.
Ideally, ebm-papst
will receive CAD files in Pro/Engineer, which we consider our
native CAD format. Models received in Pro/Engineer format will
be used directly, and will typically require little to no remodeling.
In addition, we are able to convert any of the 3D neutral file
formats, such as IGES, STEP, ACIS SAT, Parasolid X_T, directly
into a 3D model. Formats such as DXF, DWG, .pdf, are almost exclusively
a 2D representation, and would need to be completely modeled from
scratch.
In addition,
we have a seat of both SolidWorks 2001 and SolidEdge version 9.
We can receive native files from these systems and convert the
files into Cadkey or Pro/Engineer.
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3. Tolerances
Tolerances must
be assigned to components with consideration as to what is reasonable,
what is practical, and what the manufacturing machines are capable
of producing. We should keep in mind, when discussing capabilities,
that our equipment is new, state-of-the-art equipment, and our
shop floor leaders have been involved with sheetmetal manufacturing
for many years. The manufacturing tolerances that we can achieve
are as good as any other state-of-the-art sheetmetal manufacturer.
Single-punch
hole size tolerances are largely a function of the punch and die
used to create them. In general, there is very little variation
from one hole to the next. We are able to achieve a tolerance
of +/-.003” on holes. We can hold +.003/-.000” on
holes which require a pressed component, such as a PEM nut. Keep
in mind that the diameter is what will pass through the hole,
and not the “rim size”, which may be slightly different.
Hole to Hole
/ Hole to Edge tolerances are controlled by the CNC Punch Presses,
and are therefore executed during the flat pattern stage. We expect
to hold flat pattern geometry to +/-.010”. Although the
punch presses can at times hold up to +/-.004”, flexing
in the material, and distortion due to the amount of holes on
a surface make tight tolerances unreliable.
Hole to Fold
/ Fold to Fold tolerances are controlled during the bending stage
on the Press Brakes. Although our press brakes can repeat to .001”,
the error is greatly compounded by variations in material thickness
(as much as +/-.007”), and the variation in the flat pattern,
(+/-.010”). We can meet a tolerance of +/-.020” on
bends. A tolerance of +/-.010” can be held, but should only
be specified when absolutely necessary.
Keep in mind
that exceedingly tight tolerances force additional labor in sorting
and inspection. The result of tolerances that are too tight is
simply higher costs and lower productivity. Correctly toleranced
parts still have excellent fit and function, with the added benefit
of efficiency.
If extremely
tight tolerances are truly required, (ie. +/-.005” or less),
and the tolerances exceed the capabilities of our manufacturing
machines, then we are forced to consider dedicated tooling and
custom processes.
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4. Materials
The cold rolled
steel, (CRS), that ebm-papst uses is ASTM-A366, which contains a carbon
content of .10 and a temper of #2 or #3, which improves welding
and forming. Steel is much easier to spot weld than aluminum.
It is also much cheaper, although adding corrosion protection,
(plating and painting), may consume much of the cost savings.
Thickness can vary as much as +/-.007”.
The aluminum
that ebm-papst uses is 5052-H32, it has has been strain hardened and
stabilized by low temperature heating and is 1/4 hard. Its main
alloy is magnesium. 5052-H32 is a very strong aluminum, yet can
be formed with a reasonable bend radius. All aluminum will crack
along a bend if a tight bend radius is used. An inner bend radius
of 1 to 1 ½ material thickness minimum is required. Corrosion
and weldability of 5052-H32 is considered very good.
In cases where
aluminum is being substituted for steel, the material thickness
will need to be approximately 40% thicker in aluminum to have
the same strength. However, since aluminum is 1/3 the weight,
the aluminum version of the sheetmetal will still be ½
the weight of a steel version.
The stainless
steel that ebm-papst uses is 304. It is the most widely used of the
stainless steel and heat resisting steels. It offers good corrosion
resistance to many chemical corrodents as well as industrial atmospheres.
It has very good formability and can be readily welded by all
common methods.
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5. Plating and Finishes
Steel is often
purchased with a galvanized coating to prevent rusting. It is
important to remember that certain plated materials such as Aluminized
Steel can’t be safely TIG welded.
Plating that
is applied after forming and welding is done by an external supplier.
Standard powder-coat
paint is applied in-house. Designers are required to compensate
for the material build-up, and typically use .005” thickness
per surface as a rule. This is usually the reason why ebm-papst’s
drawings have dimensions that are .010” less than what the
customer has specified. Excessive masking of surfaces is expensive
and labor intensive. Powder Paint with a substrate of Zinc Chromate
is not recommended because out gassing will cause pitting of the
paint surface.
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6. Tooling
The punch press
department has a large inventory of tools for round and rectangular
cut-outs. For formed features, there is an inventory of tools
that were ordered for specific jobs. On new jobs that require
form tooling, if a special tool has to be ordered, there typically
is a 4-6 week lead time. The maximum offset height of a formed
feature is 3/8”.
For hex pattern
finger guard cutouts, we have currently have tooling for 5/32”
x .035 web, ¼” x .040/.048” web, 5/16”
x .060” web, 3/8” x .060 web, ½” x .06
web. Other sizes may have to be ordered.
If possible,
avoid selecting an air mover that is on the edge of the CFM requirement,
so that special finger guards or punch patterns are required.
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7. Fabrication
We prefer spot
welding over TIG welding if there is a clear functional choice.
It reduces labor content and tends to be more repeatable. We like
to avoid fillet welding to cosmetically seal box corners. We have
an alternative design for “tab through and TIG weld construction”
which avoids the cosmetic grinding after weld.
POP rivets and
screws become the only options to fasten together two components
that have been plated. In general, POP rivets are cheaper than
screws, and the labor content is less, but rivet construction
makes the unit much less servicable.
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8. Assembly
Through bolting
fans to the sheet metal housing with a blind PEM stand off is
the most common way of fastening the fans to the chassis. Using
pressed or thermal inserts in the fans should be last resort,
as well as loose nuts and bolts.
Fan tolerance
stack up is critical, especially when dealing with impellers.
Typical clearance between impellers and inlet rings is between
.060” and .090”. Thought needs to be put into lead
exit and routing so that it does not rub when space is limited.
We typically
use in-line torque fastening equipment. Place fasteners perpendicular
to the work surface if possible.
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9. First Article Inspections
A First Article
Inspection will be performed on at least one unit for all prototype
builds. No product will be released to production without a satisfactory
First Article Inspection. The Quality Department is responsible
to perform dimensional, component and workmanship inspection in
accordance with customer drawings and specifications. In cases
where the customer hasn’t provided ebm-papst with drawings that
detail critical dimensions, then ebm-papst must provide the customer
with an inspection drawing, which the customer must approve.
If a unit fails
First Article Inspection, a manager may release the unit for shipment
upon notification to and approval by the customer. A failed First
Article Inspection triggers a review meeting in which a determination
is made as to the cause of failure, and corrective action is taken.
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