The following paragraph does not apply to any country where such provisions are inconsistent with local law: LEXMARK
INTERNATIONAL, INC., PROVIDES THIS PUBLICATION “AS IS” WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESS OR
IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A
PARTICULAR PURPOSE. Some states do not allow disclaimer of express or implied warranties in certain transactions; therefore, this
statement may not apply to you.
This publication could include technical inaccuracies or typographical errors. Changes are periodically made to the information herein;
these changes will be incorporated in later editions. Improvements or changes in the products or the programs described may be made
at any time.
Comments about this publication may be addressed to Lexmark International, Inc., Department F95/032-2, 740 West New Circle Road,
Lexington, Kentucky 40550, U.S.A. In the United Kingdom and Eire, send to Lexmark International Ltd., Marketing and Services
Department, Westhorpe House, Westhorpe, Marlow Bucks SL7 3RQ. Lexmark may use or distribute any of the information you supply in
any way it believes appropriate without incurring any obligation to you. To obtain additional copies of publications related to this product,
visit the Lexmark Web site at www.lexmark.com.
References in this publication to products, programs, or services do not imply that the manufacturer intends to make these available in
all countries in which it operates. Any reference to a product, program, or service is not intended to state or imply that only that product,
program, or service may be used. Any functionally equivalent product, program, or service that does not infringe any existing intellectual
property right may be used instead. Evaluation and verification of operation in conjunction with other products, programs, or services,
except those expressly designated by the manufacturer, are the user’s responsibility.
Lexmark and Lexmark with diamond design, MarkVision, Optra, and Prebate are trademarks of Lexmark International, Inc., registered in
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Other trademarks are the property of their respective owners.
This software and any accompanying documentation provided under this agreement are commercial computer software and
documentation developed exclusively at private expense.
General information ............................................................................................................. 6
Paper and label Industry ..................................................................................................................................6
Print material testing ........................................................................................................................................ 6
Printing on labels ...........................................................................................................................................13
Duplexing paper labels .................................................................................................................................. 14
Optra C ........................................................................................................................................................ 109
Optra Color 1200 .........................................................................................................................................112
Optra E, Ep ..................................................................................................................................................114
Optra Es special media printer .................................................................................................................... 115
Optra K 1220 ............................................................................................................................................... 117
Optra N ........................................................................................................................................................ 120
Optra S ........................................................................................................................................................125
Optra T ......................................................................................................................................................... 132
Index .................................................................................................................................. 142
4
Overview
Lexmark has many years of experience in successful card stock and label testing and cross education programs with print
material vendors and converters.
This document provides guidelines to help you select appropriate print materials for the following Lexmark laser printers.
The information supplied here supersedes other information relating to card stock and labels included with your printer. See
other printer documentation for detailed information about the paper, envelopes, and transparencies suitable for your
printer.
In addition to printer-specific media recommendations, this document also explains design factors you should consider
when purchasing all types of print materials. The glossary on page 138 defines many industry terms. If you have specific
stock or design questions, talk with your print materials supplier.
See your printer documentation for general printing information and terms. See the printer registration card, information on
the printer CD, or visit our Lexmark Web site at www.lexmark.com/publications for technical assistance contact
numbers.
Always test print materials thoroughly before buying large quantities. Doing so will help you avoid unexpected problems
when you begin regular printing.
5
General information
Paper and label Industry
The paper and label industry includes several different types of businesses: manufacturers, converters, and distributors.
Manufacturers produce the base stock. If the base is for labels, manufacturers may ship it on large rolls or in a cut-sheet
form.
Converters take the base stock and convert it into cut-sheet products. Converters may work from rolls with or without the
adhesive applied, or they may take a base stock and convert it to meet their customers’ specifications.
The conversion process includes, but is not limited to, cutting the stock to size, perforating the stock, die-cutting, and
applying inks and topcoats. Converters work with their customers to convert the base material into a cut-sheet product
designed for use in laser printers.
Distributors generally are the direct link to the customer.
Distributors may work with different converters, and converters may work with different manufacturers, as their needs and
prices change. Most businesses follow accepted industry conventions, but specifications, standards, formulations, and
processes may vary with time or with different companies.
Note: Labels or papers that performed satisfactorily in the past may suddenly create printing problems
because of a change in material or process.
Some large businesses perform all three functions, from manufacturing to distribution. These companies may offer greater
expertise and product consistency than companies that concentrate on one facet of the process.
Print volumes
Printing numerous sheets of card stock or labels in a short period of time can create printing problems. Exclusive printing of
labels, for example, may result in more frequent service calls. Proper printer maintenance helps alleviate these problems.
(Look under “Maintenance procedures” in the index for specific information about maintaining your printer.)
Print material testing
Choosing print materials can seem complex. Unfortunately, it is not possible to write a simple “cookbook” explaining how to
select print materials, because there are too many variables you need to address for each specific application.
Be aware that critical factors at the vendor–such as the physical characteristics of the base stock and the manufacturing
processes–may change over time.
Print materials can significantly affect printer reliability and downtime. Using materials from converters or vendors who are
unfamiliar with laser printing may result in unsatisfactory print quality or other printing problems.
Note: Once you have a successful design, test the print material before placing a large order to avoid costly
mistakes.
Your print materials supplier should be able to help develop your application or solve a problem you have with an existing
application. In addition, Lexmark has worked with several suppliers and has business partners in this field. See the printer
6
Print material testing
registration card, information on the printer CD, or visit our Web site at www.lexmark.com\publications for technical
assistance contact numbers.
Design factors
Print materials all have measurable characteristics that you need to consider when selecting or designing forms for your
particular application.
Basis weight
Basis weight is a term used to describe the weight in pounds of 500 sheets of paper (one ream). However, the weight is
determined based on the standard size of the paper, which may not be the purchased size. For example, the standard size
of 20 lb Bond paper is 17 x 22 inches, and a ream of 17 x 22 inch 20 lb Bond paper weighs 20 lbs. If the 17 x 22 inch 20 lb
Bond paper was cut, creating four reams of 8.5 x 11 paper, each ream would be labeled 20 lb Bond paper but would only
weigh 5 lbs.
If the same paper weighed 24 pounds, it would be called 24 lb Bond. The 24 lb Bond paper is thicker, heavier, and more
dense than the 20 lb Bond. Thicker paper means less paper can be placed in a tray, and paper that is heavier and more
dense may cause paper jams or feed reliability problems in some printers. Check the printer media weight table located in
the printer User’s Guide to verify that the paper basis weight being used is acceptable.
Not all basis weights are related to the same standard sheet size: for example; 70 lb material can be lighter than 40 lb
material if it is based on larger base size paper (see the Card stock weights comparison guide on page 11). For a more
consistent way to compare weights, see the metric measurement of grams per square meter (g/m2). The metric
measurement of grams per square meter has been standardized by the International Organization for Standardization
(ISO).
Your printer can accept a wide range of stock weights, but materials either too light or too heavy can cause printing
problems. Heavy and/or thicker materials may not heat quickly enough in the fuser, resulting in poor print quality. They may
also feed less reliably or skew due to their weight or rigidity. Conversely, lighter materials can wrinkle and jam in the printer
due to low beam strength (stiffness).
Depending on the orientation of the stock as it feeds through the printer, you may need to request that heavier materials be
cut grain short or grain long to provide flexibility in paper path turns. See the specifications for each printer for more precise
recommendations.
Dimensions
All printers have print material dimension limitations. See the printer documentation shipped with your printer for details.
You can sometimes redesign forms to overcome these limitations. For example, if you use forms that are shorter than the
minimum length supported by your printer, you may be able to link two forms together when printing multiple forms. An
optional Universally Adjustable Tray designed for the Optra S, Optra T, and Lexmark T printer families prints on a range of
paper sizes including A6 and 3-inch by 5-inch index cards, 3-inch by 7-inch punch cards, and 4-inch by 6-inch postcards.
Environment
Lexmark printers meet or exceed all industry emission regulations and standards. Continuous printing on some papers or
other media may create fumes that are not a problem with occasional printing. Make sure your printer is located in a
well-ventilated area.
Temperature and humidity can have a major impact on printing. Even small changes (such as from day to night) can greatly
affect feed reliability if the print material is just within the range of acceptability.
We recommend that you condition stock while it is still in the original wrapper. To condition stock, store it in the same
environment as the printer for 24 to 48 hours before printing to let the stock stabilize at the new conditions. You may need
to extend this time several days if the storage or transportation environment is very different from the printer environment.
Thick stock may also require a longer conditioning period because of the mass of the material.
7
Print material testing
If you remove the wrapper from the stock before you’re ready to load it in the printer, the stock may develop uneven
moisture content that can cause curl. Prior to loading your stock, we recommend that curl not exceed 3 mm (0.125 in.).
Lighter materials, such as paper labels and some integrated forms, are more likely to have printing problems if curl is
present.
Most label manufacturers recommend printing in a temperature range of 18 to 24°C (65 to 75°F) with relative humidity of 40
to 60%. Lexmark printers are designed to operate in a temperature range of 15.5 to 32°C (60 to 90°F) with relative humidity
of 8 to 80%. Printing in an environment outside these recommendations may cause jams, feeding problems, reduced print
quality, and predispensing (peeling) labels.
Inks (preprinted stock)
Preprinted stock introduces semi-liquid and volatile components to the high temperatures and pressure used in the laser
printing process. Preprinted inks and colorations must withstand a fuser temperature up to 225°C (437°F) and pressure up
to 25 psi without contaminating the printer or creating hazardous fumes.
Thermography inks are not recommended. Thermography inks have a waxy feel and the printed image appears raised
above the surface of the print material. These inks can melt and damage the fuser assembly.
Preprinted inks must also be abrasion resistant to reduce ink dust and ink contamination in the printer. If you are printing
over a preprinted area, the ink must be receptive to toner to ensure adequate fusing.
All preprinted inks must be thoroughly dry before using printed materials. However, we do not recommend using offset
powders or other foreign materials to speed drying. Check with your converter, or the manufacturer or vendor of the ink you
plan to use, to determine if the ink is compatible with laser printers that heat the ink to 225°C (437°F).
Perforations and die-cuts
If your form has perforations, the perforation line should stop 1.6 mm (0.06 in.) from each edge of the form to avoid
separating the form in the printer path, resulting in a jam. The location of the perforation affects initial pick strength.
Perforations closer to the edge may increase the number of jams. For pressure-sensitive materials such as labels,
minimize the number of perforations that go through the backing material, or liner, since these can also affect the strength
of the form.
Perforations should be ironed so the print material lies flat, reducing nesting of forms. Edges should be smooth and clean
with no roll-over. Laser-perfs (also known as micro-perfs or data-perfs) provide greater stability and are preferred. These
smaller perforations do not normally nest or create excessive paper dust and debris. Make sure paper chaff and dust
created during the conversion process are removed before packaging.
If perforations tent, or crease at the perforation line, the perfs may break, causing a paper jam. Tenting may increase skew,
cause double sheet-feeding, or smear the toner on the print material before fusing, resulting in poor print quality. To reduce
tenting, use micro-perfs. If the print material is lightly snapped as it moves through the printer, the perforations should hold
without breaking.
Die-cutting is used to create shapes in a label or a card stock design. When designing labels, round all corners to prevent
delamination of the labels, and avoid cuts through the liner (anvil cuts). Back splits and pop-out windows are also not
recommended.
If perforations or die-cuts are part of the design of the print material, ties are recommended. These small uncut areas
(approximately 1.6 mm or 0.06 in.) help stabilize the form and prevent tearing at perforations and die-cuts during printing.
For areas with die-cuts or perforations that create a small end product, or where die-cuts or perforations intersect, ties on
the corners of the design provide added stability. Ties may be located anywhere along perforations or die-cuts. For
pressure-sensitive products, ties help prevent the labels from peeling off the liner while in the printer. Ties cannot, however,
be used to compensate for inadequate release strength of the adhesive in label designs.
Note: For specific perforation and die-cut guidelines for your printer, see the appropriate topic under Printer
specifications on page 22.
8
Print material testing
Debossing and embossing
Avoid debossing and embossing materials. Embossing leads to nesting and double sheet feeds, and the fusing process
significantly reduces the height of the raised image. Printing too close to embossments results in poor print quality and poor
fuse grade.
Metallics
We do not recommend using metallics in forms, whether in inks or other materials, due to their conductivity and their ability
to bleed charge. This can interfere with toner transfer and cause poor print quality.
Basic form design
When designing forms, include a non-print area of 8.38 mm (0.33 in.) at the top and bottom of the form and 6.35 mm (0.25
in.) on both sides of the form.
In general, portrait orientation is the preferred layout, especially if you are printing bar codes. If your forms require
landscape orientation, be aware that variations in paper path speed may produce spacing variations when printing bar
codes.
Note: We do not warrant uninterrupted or error-free operation of a product. Warranty service does not
include repair of failures caused by:
•modification or attachments
•accidents or misuse
•unsuitable physical or operating environment
•maintenance by anyone other than Lexmark or a Lexmark authorized servicer
•operation of a product beyond the limit of its duty cycle
•failure to have installed a maintenance kit as specified (if applicable)
•use of printing media outside of Lexmark specifications
•use of other than Lexmark supplies (such as toner cartridges, inkjet cartridges, and ribbons)
•use of other than Lexmark product or component
9
Card stock
Card stock is a rigid, stiff material that can have a wide variety of constructions. Orientation of paper fibers (grain direction),
moisture content, thickness, texture, and other properties can significantly impact printing, as can preprinting, perforation,
creasing, and other features common to forms. For example, preprinting introduces semi-liquid, volatile components that
must withstand the high temperatures used in laser printing. Perforation and creasing may cause nesting, or interlocking,
which can cause paper jams and double sheet feeds.
The following sections describe some of the basic characteristics of card stock. In general, we recommend a single-ply
construction of 100% chemically-pulped wood with a vellum finish. Before purchasing large quantities of card stock, make
sure you test samples of the print material in your printer.
Weight
The weight of card stock plays a significant role in the print quality and feed reliability of the stock. Confusion often arises
when specifying the basis weight of a stock; see Basis weight on page 7 for more information. The basis weight is a term
used to describe the weight in pounds of 500 sheets of paper (one ream). Since the sheet size varies from one type of
stock to another, the basis weights are not always easily comparable. For example, an office supply store has 8.5 x 11 size
cover stock (80 lb Bristol) and 8.5 x 11 size card stock (90 lb Index) side by side on the shelf. Both papers are manufactured
by the same company, and a basis weight comparison indicates the card stock (90 lb Index) is heavier than the cover stock
(80 lb Bristol). In this example, the cover stock (80 lb Bristol) is actually heavier than the card stock (90 lb Index).
The reason the cover stock is heavier is because before the two types of paper were cut into 8.5 x 11 size pages, the card
stock was a larger sheet size than the sheet size of the cover stock. When the papers were cut during the manufacturing
process into 8.5 x 11 size pages, more reams (500 sheets) of paper were received from the card stock sheets than from the
cover stock sheets. This makes the weight of the cover stock heavier than the weight of the card stock.
2
It is easier to compare the cover stock metric weight (g/m
weights of the two stocks in the previous example, it is immediately evident that 80 lb Bristol cover stock (176 g/m
heavier than 90 lb Index card stock (163 g/m2).
Not all printers are able to print on cover stock. This is because cover stock is usually thicker and not able to make the turns
in the printer paper path. This causes paper jams and sometimes causes the paper to feed incorrectly. Also, when using a
laser printer, toner is pulled onto the paper through an electrical charge. If the paper is too thick, there may not be enough
voltage to pull the toner on the paper properly and can cause poor print quality.
To determine if your printer is able to print on cover stock, go to Printer specifications on page 22, locate your printer, and
review the supported paper type information. You can also view the supported media in the printer User’s Guide.
) against card stock metric weight (g/m2). If you look at the metric
2
) is
10
Grain orientation
Use the following table to compare the weights of various types of card stock.
Card stock weights comparison guide
Basis weight (lbs/ream)
Printing
Bond
Metric
equivalent
2
)
(g/m
752050–––50
902460––––
1052870––––
10829–40–––
118318 0––––
12032–––6774
1313590––––
13536–50–––
431.8 x
558.8 mm
(17 x 22 in.)
Offset
635 x
965.2 mm
(25 x 38 in.)
Cover
508 x
660.4 mm
(20 x 26 in.)
Bristol
571.5 x
889 mm
(22.5 x 35 in.)
Index
Bristol
647.7 x
774.7 mm
(25.5 x 30.5 in.)
Tag
609.6 x
914.4 mm
(24 x 36 in.)
14839100––––
16343–60–90100
1764712065–––
19953––110110–
20354––––125
Card stock weights may vary ± 5%.
Depending on the printer, material thicker than 0.30 mm (0.012 in.) may present feed reliability problems, and material
thicker than 0.17 mm (0.007 in.) may reduce print quality. Contact your supplier to determine the weight of any card stock
you currently use.
See the individual printer specifications in this document for more information about the card stock weights your printer
supports.
Grain orientation
Grain refers to the alignment of the paper fibers in a sheet of paper. Grain is either grain short, running the width of the
paper, or grain long, running the length of the paper.
The orientation of the grain contributes to the rigidity of card stock and affects feed reliability. The recommended grain
orientation depends on the weight of the stock and whether the printer feeds the stock short-edge first or long-edge first.
For lighter card stocks, grain long is recommended to reduce potential curl problems. Curl may decrease the ability of the
form to move reliably through the printer.
Most printers feed paper short-edge first. If your printer supports larger paper sizes, such as 11x17 in. or A3, it may feed
some paper sizes long-edge first. See your printer documentation for more information.
11
For materials fed short edge first:
Coatings
Grain short is recommended for stock heavier
than 135 g/m2
Feed
direction
Grain
direction
For materials fed long edge first:
Grain long is recommended for stock heavier
than 135 g/m2
Feed
direction
Grain long is recommended for stock lighter
than 135 g/m2
Feed
direction
Grain
direction
Grain short is recommended for stock lighter
than 135 g/m2
Feed
direction
Grain
direction
See the individual printer specifications in this document for more information about the recommended grain direction for
card stock you use with your printer.
Grain
direction
Coatings
Surface texture and coatings on card stock significantly affect toner adhesion (fuse grade), print quality, and feed reliability.
We recommend a vellum finish for the best printing performance. We do not recommend glossy coatings and slick surfaces
or surfaces that mimic laid finishes (glossy paper, not glossy card stock, is acceptable for some printers). Paper
smoothness also affects print quality. If the paper is too rough, the toner does not fuse to the paper properly; if the paper is
too smooth, it can affect feed reliability. We recommend smoothness to be between 100 and 400 Sheffield points (150 to
250 is optimal). Using media higher than 300 Sheffield could result in printing degradation.
Offset powders
We do not recommend using offset powders or other foreign materials to speed drying. Offset powders are used by print
shops to prevent printed pages from sticking together. Powder is usually sprayed on the printed page right before it reaches
the stacker on the offset printing press. This powder provides an intermediate layer between two sheets of paper,
preventing ink transferring from one sheet to another.
12
Labels
Labels (also called pressure-sensitive materials) are multi-ply materials consisting of a “sandwich” of various combinations
of face sheets (printable stock), adhesives, and removable protective backings (liners). The multiple layers can result in
thick, difficult-to-handle materials.
Labels are among the most difficult print materials for any printer to reliably feed and print. The heat, pressure, and paper
paths required by laser printers create a particularly difficult environment for printing labels. Temperatures near 225°C
(437°F) [temperatures vary between printers; check the section for your specific printer] and pressures to 25 psi can be
necessary for the fusing process. Heavy label stock can absorb heat, which in turn affects toner adhesion and print quality
and causes problems such as delamination.
Note: To prevent labels peeling off or delaminating, make sure the release strength of the labels you use is
sufficient to withstand the temperature and pressure extremes generated during printing.
Label characteristics
The materials used to construct labels have a wide range of properties that can affect printing. In addition to volatile
components in adhesive, volatiles are also in some label materials. We recommend that volatile emissions from the label,
up to 160°C (320°F), should be a minimal amount. These low boiling point volatiles can produce emissions when they are
heated in the fuse,r and they can potentially produce vapors which can cause damage to the printer. Preprinted inks can
also cause printer contamination, and may be present on one or both sides of the label sheet.
Observing recommended label design guidelines can minimize contamination as well as prevent other critical problems,
such as labels peeling off and causing jams in the printer, or the label or adhesive melting if the sheet stops in the fuser
during a paper jam.
Review label designs with a converter or vendor who is knowledgeable about labels and laser printer characteristics to
ensure you use labels suitable for your application.
Note: Before purchasing large quantities of labels, make sure you extensively test the labels with your
printer.
Printing on labels
Use full label sheets only. Partial sheets (with areas exposed by missing labels) can cause labels to peel off during printing,
resulting in a paper jam. Partial sheets can also contaminate your printer and cartridge with adhesive and can void the
printer and cartridge service warranties.
Do not feed labels through the printer more than once. Doing so may result in adhesive contamination to the cartridge and
other components.
Depending on your printer model and the number of labels you print, printing labels may require special printer
maintenance. (Look under “printer maintenance” in the index of your User’s Guide, publications CD, or Software and Documentation CD for specific information about maintaining your printer.)
If you print large quantities of labels or other glossy print media on a Lexmark™ C750 or C752, replace the fuser housing
with a web oiler field upgrade kit (P/N 12G6307 for a 115 V printer, P/N 12G6308 for a 220 V printer).
13
Duplexing paper labels
Duplexing paper labels
Due to the special construction of labels, they are not typically duplexed. However, if certain design, construction, and
usage guidelines are followed, you can print on both sides of the label sheet successfully.
When developing a paper label for duplexing, the converter should ensure the label design protects against contamination
or buildup. Contamination adversely affects paper feeding and causes paper jams in the printer.
We recommend labels used for duplexing have a non-adhesive border around the label area. In addition, make sure the
release strength is sufficient to withstand temperatures of 225°C (437°F) and pressures to 25 psi. This is particularly
important with a duplex application since the label is subjected to these extremes twice. Use label ties whenever possible.
These small uncut areas (approximately 1.6 mm or 0.06 in.) help stabilize the label sheet and prevent tearing at
perforations and die-cuts during printing. In addition, using ties helps prevent the labels from predispensing in the printer.
The slits and cuts in the labels expose the adhesives to the printer. For best results when duplexing labels, position the
label sheet so the slits and cuts are not aligned with the ribs in the duplex or redrive areas of the printer. (Figure 1 and
Figure 2 on page 15 illustrate the rib locations for the Optra S and the Optra T, respectively.) This eliminates any contact
points between the label adhesive and the printer, thereby preventing any adhesive contamination in the printer.
Other steps to ensure optimal printing include orienting the label in the tray so the label end is fed into the printer first and
using long grain paper. Long grain paper tends to feed more reliably than short grain paper, which tends to curl more easily.
As with any industry, product changes and improvements are constantly being developed. Therefore, if a converter
develops a short grain sheet for use with duplexed labels, test the sheet to make sure it performs satisfactorily. We
recommend testing any material with your application and printer before purchasing large quantities.
To use the duplex label application, you must install a special fuser wiper.
PrinterFuser wiper part number
S1855, T612, T614, T520, and T52299A1082
T620 and T62218A1467
T630, T632 and T63456P2109
T64x, X644e, and X646e40X2666
The wiper makes it possible to print on both sides of paper labels specifically designed for duplexing. In addition, you can
use the wiper to simplex paper labels and duplex paper in the same printer. When ordering a new cartridge, be sure to
order the cartridge that includes the correct fuser wiper.
20 mm
21 mm
27 mm
22 mm
15.5 mm
21.5 mm
28 mm
26 mm
17 mm
15 mm
Reference
plate
Figure 1. Optra S rib locations (rib width = 2mm)
14
Label components
16 mm
11 mm
15 mm
13 mm
16 mm
17 mm
Figure 2. Optra T and Lexmark T rib locations (rib width = 2mm)
26 mm
18 mm
12 mm
20 mm
15 mm
12 mm
4.02 mm
Reference
Plate
Label components
Labels are composed of three basic parts: the liner, the adhesive, and the face sheet. Labels may also have topcoats that
affect printing. Choosing appropriate materials for each of these label components will help ensure reliable printing.
Liners
The liner, also known as the carrier or backing, is the material onto which the label is attached. The liner carries the label
through the printer and directly affects feed reliability. Liner weights and construction vary based on the printable face stock
used. (See Face sheet (printable stock) on page 16.) Tissue-backed, plain bond, or bond-like, porous, lay-flat liners are
preferred. Liners constructed for use in high speed laser printers (50 or more pages per minute) may not produce
acceptable results.
A liner should bend easily and snap back to its original flat state when released. If the form remains bent, it may cause
paper jams or damage to the edge of the sheet, particularly in earlier printer models using a corner buckler rather than an
auto compensator to separate the sheets. The following table shows which printers use a corner buckler and which use an
auto compensator.
Note: If your printer is not listed here, contact your Lexmark representative to verify which method your
printer uses to separate sheets of labels.
Printers using a corner bucklerPrinters using an auto compensator
Some liner materials used in pressure-sensitive constructions are called label papers. Label papers are either M.F.
(machine finish) or E.F. (English finish) papers that are calendered, supercalendered, or coated on one side. Machine
finishes have varying degrees of surface smoothness. The smoothness is determined by the number of times the paper
passes through the rollers (wet or dry) during manufacturing. An English finish is uncoated and low gloss in appearance.
Label papers may also be used as the face sheet for pressure-sensitive paper products, such as the materials used in dual
web forms construction.
Supercalendering produces high gloss surfaces that may be slick. Some supercalendered liners are difficult for printers to
pick and feed reliably. We do not recommend using supercalendered liners designed for high-speed laser printers (50 or
more pages per minute).
Some pressure-sensitive constructions use Kraft liners or bleached Kraft liners. Kraft liners are made from sulfate pulp and
are M.F. or M.G. (machine glazed). Most machine glazed papers have a high gloss appearance. High gloss, glazed
surfaces may increase skew and are more difficult for the printer feed mechanism to handle reliably. Some Kraft liners may
produce acceptable results; however, we strongly recommend extensive testing of pressure-sensitive constructions using
Kraft liners.
Tissue-backed or plain bond liners reduce toner contamination inside the printer and improve feed performance. Slick, nonporous liners are harder to feed and increase toner buildup in the fuser and on the backup roll. Rough backings, on the
other hand, can increase paper path friction, which can cause skew and paper jams. The face material of the liner needs to
have a melt temperature that can also withstand the fuser temperatures of nearly 225°C (437°F). Since there is a stripped
area of a maximum of 3 mm, this can expose the face material to these temperatures and could cause melting or
contamination in the fuser.
Excessive paper dust or chaff associated with the liner may affect print quality. If a liner material produces excessive paper
dust or chaff during the conversion process, some of this debris may be packaged with the material and end up in the
printer. Liner materials that produce excessive paper dust or chaff as they feed through the printer may also affect print
quality.
Your forms supplier can provide additional information on liners.
Adhesives
There are three basic types of label adhesives: removable, permanent, and semi-permanent (cold temp). All types, with
proper design, can be used with your printer. Acrylic-based adhesives are generally preferred for cut sheet label printers.
The major adhesive-related printing problem is printer and cartridge contamination. The adhesives are semi-liquid and may
contain volatile components. If the sheet jams in the fuser, the adhesive can melt, thereby contaminating parts of the printer
or releasing fumes. To avoid exposing adhesive to the paper path guides, drive rollers, charge roller, photoconductor drum,
transfer roller, and detack fingers, use full label sheets.
Zone coating means placing the adhesive only where needed. Paper labels and integrated forms typically use zone
coating. In addition, a non-adhesive border of 1 mm (0.04 in.) around the outside edge of the label sheet generates good
results. Check with your adhesive manufacturer or forms supplier for more information about designing labels for your
printer.
A stripped edge matrix along the outer border of the stock, combined with adhesive that does not ooze, helps prevent
adhesive contamination. This design requires a stiffer backing material to prevent damage when the sheet is aligned on the
reference edge. Generally, vinyl and polyester labels are well-suited for this design. Paper and dual web designs may
require testing to determine which backing produces good results. (See Label design guidelines on page 17 for more
information on matrices.)
Make sure the release strength is adequate so labels stay attached to the liner and do not peel off in the printer. Adhesives
must be able to withstand pressures to 25 psi and fuser temperatures of 225°C (437°F) without delaminating, creating
hazardous fumes, or oozing around edges of labels, perforations, or die-cuts. Shear strength should be strong enough to
prevent adhesive stringers. Contact your forms supplier for additional information.
Face sheet (printable stock)
Paper, vinyl, and polyester are the most common materials used for printable stock. Your forms supplier can provide
information on whether the printable stock you want to use can withstand temperatures of 225°C (437°F) [temperatures
16
Label design guidelines
vary between printers; check the section for your specific printer] and pressures to 25 psi. Carefully test the stock to ensure
it functions satisfactorily with your printer.
Topcoats
Topcoats for non-paper labels may be either water based or solvent based. Avoid topcoats containing chemicals that emit
hazardous fumes when heated or exposed to pressure. Topcoats affect the print quality, feed reliability, and adhesion of
toner to the face sheet. Topcoats must be able to withstand temperatures up to 225°C (437°F) [temperatures vary between
printers; check the section for your specific printer] and pressures up to 25 psi for 100 milliseconds to prevent fuser
damage.
Water-based topcoats tend to be more conductive than solvent-based topcoats and are more difficult to fuse. With some
water-based topcoats and heavy liners, the fuse grade may fall below acceptable levels. Solvent-based topcoats tend to be
lower in conductivity than water-based topcoats. With some solvent-based topcoats, fuse grade is within acceptable levels
when heavier liners are used.
Print quality may degrade when using topcoats on labels with heavier liners. Using a lighter liner may reduce the
appearance of splatter. Test forms carefully with your printer to be sure the topcoat used performs acceptably for your
application.
Label design guidelines
Labels with a stripped edge matrix have the area around the outer edge of the cut sheet removed. Labels with a total strip
matrix have the unneeded portion of the die-cut stock around the labels (including a portion between the labels) removed to
make it easier to peel the labels from the backing.
Butt cut labels are cut flush to one another, with no extra area between them. Avoid using butt cut labels without a stripped
edge matrix.
Die-cut labels are cut with a non-print area between each label. For best results, do not print within 2.3 mm (0.090 in.) of
the edge of the label, of the perforations, or of the die-cuts of the label.
If you are using a butt cut or die-cut label, make sure adhesive contamination does not occur. Labels use varying levels and
types of adhesive, as well as a variety of liner materials and face stocks. Adhesive can ooze with all label stocks. Make
sure die-cuts are free of adhesive stringers. Zone coating or pattern adhesive with a 1 mm (0.04 in.) or larger non-adhesive
border provides the greatest protection from adhesive contamination.
If zone coating is not used, we recommend a stripped edge matrix. The stripped edge matrix varies with the type of face
stock, liner, and adhesive materials. See the following table for stripped edge matrix guidelines. Measurements may vary
±0.5 mm.
Stripped edge matrix guidelines
Total weight
Face type
1
Paper
(Cut Sheet or
Dual Web)
Vinyl265—300 g/m
Polyester
and other face
materials
1
Use a non-oozing adhesive.
2
Must be 1.6 mm (0.0625 in.) in some circumstances. See Vinyl and polyester labels on page 21.
of label
140—180 g/m
Varies3.0 mm (0.125 in.)
2
2
Edge matrix
removal
1.6 mm (0.0625 in.)
1.6 mm (0.0625 in.)
3.0 mm (0.125 in.)
2.4 mm (0.094 in.)
2.4 mm (0.094 in.)
Location of strip
215.9 mm (8.5 in.) at leading edge
279.4 mm (11.0 in.) at driver edge
2
2
215.9 mm (8.5 in.) at leading edge
279.4 mm (11.0 in.) at driver edge
215.9 mm (8.5 in.) at leading edge
279.4 mm (11.0 in.) at driver edge
17
Label design guidelines
Using cut sheet labels with adhesive applied to the edge of the sheet will contaminate your printer and your cartridge and
could void your printer and cartridge warranties.
When using pressure-sensitive materials without zone coating, choose butt cut labels without any stringers and with a
stripped edge matrix. If a total strip matrix is in the design for the final product, print before removing the matrix. If the matrix
must be removed before printing, round all corners and make sure adhesive is not exposed.
Figure 3 on page 18 illustrates a recommended label design for Optra plus printers as well as the 4039, 4029, and 4019
laser printers. The Non-print area may vary, depending on the printer model.
Figure 4 on page 19 illustrates a recommended label design for Optra S, Optra T, and Lexmark T laser printers, which use
a different paper picking mechanism.
Leading edge
8.5 in.
215.9 mm
0.094 in.
2.4 mm
Liner edge
Stripped edge
0.125 in.
3 mm
Driver edge
11 i n .
279.4 mm
0.06 in.
1.6 mm
Perforation end
Liner edge
waste strip6.35 mm (0.25 in.)
waste strip
0.25 in.
6.35 mm
0.5 in.
12.7 mm
0.25 in.
6.35 mm
Non-print area
0.33 in.
8.38 mm
Top perforation
0.33 in.
8.38 mm
Non-print area
Non-print area Non-print area
(Not drawn to scale)
Figure 3. Design guidelines, vinyl label for Optra plus, 4039, 4029, and 4019
printers
18
0.094 in.
2.4 mm
Label design guidelines
Leading edge
8.5 in.
215.9 mm
Liner edge
Stripped edge
0.125 in.
3 mm
Driver Edge
11 i n .
279.4 mm
0.06 in.
1.6 mm
Perforation end
Liner edge
0.25 in.
6.35 mm
0.79 in.
20 mm
0.25 in.
6.35 mm
Non-print area
0.33 in.
8.38 mm
Top perforation
0.33 in.
8.38 mm
Non-print area
Non-print area Non-print area
(Not drawn to scale)
Figure 4. Design guidelines, vinyl label for Optra S, Optra T, and Lexmark T
printers
Cut sheet paper labels
Generally, cut sheet paper labels work well with your printer. Coating or sizing to make the paper liquid-resistant decreases
toner adhesion and increases the risk of toner contaminating the fuser. At a minimum, paper labels should be equivalent in
weight and rigidity to a 20 lb xerographic, bond paper.
19
Label design guidelines
Dual web forms
Constructing dual web forms involves joining together rolls of two different materials (usually pressure-sensitive paper and
bond paper) and then converting to a cut sheet product. This construction requires a stripped edge matrix. The liner must
be rigid enough to withstand the pick force of the printer.
The two materials must be thin enough for the sheet to lie flat in the paper tray. Orient the form in the tray so that the
pressure-sensitive area feeds into the printer first. The form should have no adhesive exposed in the overlay area or
anywhere along the front or back of the form. We recommend designing a non-adhesive strip with a minimum width of
1 mm (0.04 in.) along the edges of the overlay.
To help prevent material from slipping in the fuser, we recommend knurling, which roughens up the exposed silicon area at
the glue joint.
See Figure 5 on page 20 for an illustration of the recommended dual web form design. The Non-print area may vary,
depending on the printer model.
The face sheet of a dual web form is usually a paper pressure-sensitive product; therefore, the guidelines for paper labels
are applicable to dual web forms.
Leading edge
(8.5 in.)
Liner edge
Stripped edge
0.0625 in.
1.6 mm
Reference edge
(11 in.)
0.0625 in.
1.6 mm
0.25 in.
6.35 mm
Non-print area
Pressure-sensitive
Paper
(Not drawn to scale)
Non-print area
0.33 in.
8.38 mm
Overlay
Figure 5. Design guidelines, dual web form
20
Label design guidelines
Vinyl and polyester labels
Vinyl labels work well within specified design parameters. Vinyls are heat-sensitive, so the liners need to be thick enough to
absorb excess heat and prevent melting. A total strip matrix may cause adhesive contamination. Thin liners or weak pull
strength may lead to labels peeling off the form inside the printer, which will require printer servicing. See Figure 3 on page 18 for an illustration of a vinyl label design for Optra plus printers and Figure 4 on page 19 for Optra S, Optra T, and
Lexmark T printers.
As illustrated on page 19, a leading and trailing edge stripped area is recommended to be a maximum of 3 mm. This area
is recommended to prevent adhesive being close to the edge, which can contaminate your printer. Certain materials used
in label construction, which have liner face melt temperatures lower than the fuser temperature, may require the leading
and trailing edge stripped areas to be 1.6 mm maximum due to feeding problems. It is preferred that the liner face be
constructed with material that can withstand our fuser temperatures, which eliminates the need for changing the stripped
areas from 3 mm to 1.6 mm. If a 1.6 mm stripped area is used, it is very important that the 1.6 mm tolerance be held tightly.
With a stripped area of less than 1.6 mm, it is highly possible that adhesive contamination will occur.
Vinyls are non-absorbing, which leads to toner build-up in the fuser that requires special maintenance. See “maintenance
procedures” in the index for specific information about maintaining your printer. Vinyls may require a topcoat to ensure good
toner adhesion.
Polyester labels are less heat-sensitive but are also non-absorbing. Backings for polyester labels can be thinner, but
requirements for coatings and cleaning are similar to vinyl labels.
It is recommended that when you run vinyl labels, you install a special oil fuser cleaner, P/N 99A0725 or 40X2665. When
you order a new cartridge, be sure to order the cartridge that will include the correct fuser cleaner.
Integrated forms
To create integrated forms, the converter uses hot melt adhesives to apply the label adhesive and liner to a base material
(generally paper). Oil bleed, recognizable by a discolored face sheet, can be a problem with these forms. Oil may also
migrate from the top of the liner to the back surface of the liner while it is on the roll, before the conversion process takes
place. The forms created from this material may then be slick, and the pick mechanism of your printer may be unable to
successfully move all the sheets from the tray into the printer. Jamming and misfeeds increase when oil is present on the
back of the liner.
The adhesive on these forms is commonly patterned on two or four sides (that is, the forms have a non-adhesive border on
either two or four edges). We recommend designing a 1 mm (0.04 in.) non-adhesive border (zone coated) on all four sides.
When printing on integrated forms with a long grain base material, orient the form in the tray so the paper portion of the
form feeds into the printer first. Orient the pressure-sensitive portion of the form toward the portrait left edge. For integrated
forms with a short grain base material, orient the form in the tray so the pressure-sensitive portion feeds into the printer first.
Due to the unique construction of integrated forms, you may experience stacking problems in the output bin. Test some
forms before purchasing large quantities. Contact your Lexmark marketing representative if you experience stacking
problems with these forms.
21
Printer specifications
To locate your printer, select one of the links in the Models column or go to the page number.
Model seriesModels
C seriesLexmark C510 on page 63
E seriesLexmark E120 on page 85
Optra seriesOptra C on page 109
Lexmark C520, C522, C524 on page 51
Lexmark C530, C532, and C534 on page 29
Lexmark C720 on page 69
Lexmark C750 on page 71
Lexmark C752 on page 75
Lexmark C760, C762 on page 41
Lexmark C770, C772, C780, and C782 on page 33
Lexmark C910 on page 79
Lexmark C912 on page 61
Lexmark C920 on page 54
Lexmark C935 on page 25
Optra C710 on page 110
Lexmark E220 on page 81
Lexmark E230, E232, E234(n), E330, and E332n on page 84
Lexmark E238, E240, E240n, E340, E342n on page 40
Lexmark E250, E350, E450n on page 32
Lexmark E320, E322 on page 82
Lexmark E321, E323 on page 83
Optra E310, E312 on page 113
Optra E, Ep on page 114
Optra Es special media printer on page 115
Optra C710 on page 110
Optra Color 1200 on page 112
Optra E310, E312 on page 113
Optra E, Ep on page 114
Optra Es special media printer on page 115
Optra K 1220 on page 117
Optra M410, M412 on page 118
Optra N on page 120
Optra plus, 4039, 4029, 4019, WinWriter 600 printers on page 121
Optra S on page 125
Optra SC 1275 on page 131
Optra T on page 132
Optra W810 on page 137
T seriesLexmark T430 on page 86
Lexmark T420 on page 88
Lexmark T520, T522 on page 91
Lexmark T620, T622,
Lexmark T630, T632, T634 on page 101
Lexmark T640, T642, T644 on page 56
Optra T on page 132
W seriesOptra W810 on page 137
Lexmark W812 on page 106
Lexmark W820 on page 107
Lexmark W840 on page 60
Lexmark X422 on page 65
Lexmark X500 and X502n on page 27
Lexmark X644e, X646e on page 45
Lexmark X642e on page 36
Lexmark X850, X852e, X854e on page 49
Lexmark X940, X945 on page 24
23
Lexmark X940, X945
Lexmark X940, X945
Limit label printing to occasional use of A4 or letter size paper office labels
designed for laser printers. We do not recommend using vinyl or polyester
labels.
The Lexmark X940 and X945 support stocks up to 216 g/m2. Always feed
labels and card stock from trays 1, 2, or 3. When printing on card stock, we
recommend using grain long card stock.
The following table lists the maximum basis weights supported by the trays
and the multipurpose feeder.
Note: Scanning large quantities of labels is not recommended.
Lexmark X940 and X945: Overview of card stock and label support
Trays 1Trays 2, 3Multipurpose feeder
Labels105 g/m
Card stock105 g/m
2
2
216 g/m
216 g/m
2
2
216 g/m
216 g/m
2
2
Media specifications
LabelsWidth:210 to 216 mm (8.3 to 8.5 in.)
Length:279 to 356 mm (11 to 11.7 in.)
Weight: 120 to 128 g/m2
Thickness:0.13 to 0.20 mm (0.005 to 0.008 in.)
Smoothness:100 to 400 Sheffield*
* 150—250 Sheffield is optimal. Using media higher than 300 Sheffield could result in printing degradation.
Card stockWidth:210 to 216 mm (8.3 to 8.5 in.)
Length:279 to 356 mm (11 to 11.7 in.)
Weight: Up to 216 g/m
When printing on labels:
•Set the Paper Type to Labels in the Paper Menu.
•Do not use label sheets with a slick backing material.
•Do not print within 1 mm (0.04 in.) of the die cut, the edge of the label or the perforations, or between the die cuts.
•Use full label sheets. Partial sheets may cause labels to peel off during printing, resulting in a paper jam.
•Do not use label sheets that have adhesive to the edge of the sheet. We recommend zone coating of the adhesive
at least 1 mm (0.04 in.) away from the edges. Adhesive material may contaminate your printer and could void your
warranty.
When printing on card stock:
•Use grain long card stock, and set the Paper Type to Card Stock.
•Do not use card stock that is creased. It may cause paper jams.
2
24
Lexmark C935
Lexmark C935
Limit label printing to occasional use of A4 or letter size paper office labels designed
for laser printers. We do not recommend using vinyl or polyester labels.
The Lexmark C935 supports stocks up to 216 g/m2. Always feed labels and card
stock from trays 1, 2, or 3.
The following table lists the maximum basis weights supported by the trays and the
multipurpose feeder.
Lexmark C935: Overview of card stock and label support
Trays 1Trays 2, 3Multipurpose feeder
Labels105 g/m
Card stock105 g/m
2
2
216 g/m
216 g/m
Media specifications
LabelsWidth:210 to 216 mm (8.3 to 8.5 in.)
Length:279 to 356 mm (11 to 11.7 in.)
2
2
216 g/m
216 g/m
2
2
Weight: 120 to 128 g/m2
Thickness:0.13 to 0.20 mm (0.005 to 0.008 in.)
Smoothness:100 to 400 Sheffield*
* 150—250 Sheffield is optimal. Using media higher than 300 Sheffield could result in printing degradation.
Card stockWidth:210 to 216 mm (8.3 to 8.5 in.)
Length:279 to 356 mm (11 to 11.7 in.)
Weight: Up to 216 g/m
2
25
Lexmark C935
When printing on labels:
•Set the Paper Type to Labels in the Paper Menu.
•Do not use label sheets with a slick backing material.
•Do not print within 1 mm (0.04 in.) of the die cut, the edge of the label or the perforations, or between the die cuts.
•Use full label sheets. Partial sheets may cause labels to peel off during printing, resulting in a paper jam.
•Do not use label sheets that have adhesive to the edge of the sheet. We recommend zone coating of the adhesive
at least 1 mm (0.04 in.) away from the edges. Adhesive material may contaminate your printer and could void your
warranty.
When printing on card stock:
•Set the Paper Type to Card Stock.
•Do not use card stock that is creased. It may cause paper jams.
•We recommend the use of grain long card stock.
26
Lexmark X500 and X502n
Lexmark X500 and X502n
Limit label printing to occasional use of paper office labels
designed for laser printers. The Lexmark X500 and X500n
does not support vinyl or polyester labels.
The Lexmark X500 and X502 supports 24 to 55 lb (90 to
210 g/m
Tray 1, and Tray 2.
Tray 1 supports approximately 120 sheets of card stock and
tray 2 supports up to 250 sheets of card stock. The
following table lists the maximum basis weights supported.
Lexmark C500 and C500: Overview of card stock and label support
Card stock
(Grain short is preferred for papers over 135 g/m2)
Paper source
Tray 1 (standard tray)90 to 210g/m
Tray 2 (optional tray)90 to 210g/m
* Vinyl labels are not supported.
Index BristolTagCoverPaper
2
2
90 to 210g/m
90 to 210g/m
2
) stock. Card stock and labels are supported from
2
2
90 to 210g/m
90 to 210g/m
Labels*
2
2
180 g/m
180 g/m
Media specifications
LabelsWidth:76.2 to 216 mm (3 to 8.5 in.)
Length:123.8 to 355.6 mm (4.88 to 14 in.)
Weight:180 g/m2 (48 lb)
Thickness:0.13 to 0.20 mm (0.005 to 0.008 in.)
Smoothness:100 to 400 Sheffield*
*150—250 Sheffield is optimal. Using media higher than 300 Sheffield could result in printing degradation.
2
Card StockWeight: 163 g/m
163 g/m
Cover StockWeight: Up to 210 g/m
For more information on the supported media sizes, see the printer User’s Guide on the publications CD.
Index Bristol (90 lb)
2
Tag (100 lb)
2
27
Lexmark C500n
Lexmark C500n
Limit label printing to occasional use of paper office labels
designed for laser printers. The Lexmark C500n does not
support vinyl or polyester labels.
The Lexmark C500 supports 24 to 55 lb (90 to 210 g/m2)
stock. Card stock and labels are supported from Tray 1, and
Tray 2.
Tray 1 supports approximately 120 sheets of card stock and
tray 2 supports up to 250 sheets of card stock. The
following table lists the maximum basis weights supported.
Lexmark C500n: Overview of card stock and label support
Card stock
(Grain short is preferred for papers over 135 g/m2)
Paper source
Tray 1 (standard tray)90 to 210g/m
Tray 2 (optional tray)90 to 210g/m
* Vinyl labels are not supported.
Index BristolTagCoverPaper
2
2
90 to 210g/m
90 to 210g/m
Labels*
2
2
90 to 210g/m
90 to 210g/m
2
2
180 g/m
180 g/m
Media specifications
LabelsWidth:76.2 to 216 mm (3 to 8.5 in.)
Length:123.8 to 355.6 mm (4.88 to 14 in.)
Weight:180 g/m2 (48 lb)
Thickness:0.13 to 0.20 mm (0.005 to 0.008 in.)
Smoothness:100 to 400 Sheffield*
*150—250 Sheffield is optimal. Using media higher than 300 Sheffield could result in printing degradation.
2
Card StockWeight: 163 g/m
163 g/m
Cover StockWeight: Up to 210 g/m
For more information on the supported media sizes, see the printer User’s Guide on the publications CD.
Index Bristol (90 lb)
2
Tag (100 lb)
2
28
Lexmark C530, C532, and C534
Lexmark C530, C532, and C534
1
Limit label printing to occasional use of paper office labels
designed for laser printers. The Lexmark C530, C532, and
C534 does not support vinyl or polyester labels.
The Lexmark C530, C532, and C534 supports stocks up to
90 lb (163 g/m
2
). Card stock and labels are supported from
Tray 1, Tray 2, the manual feed slot, and the multipurpose
2
feeder.
Tray 1 supports approximately 120 sheets of card stock and
tray 2 supports approximately 250 sheets of card stock. The
multipurpose feeder supports approximately 50 sheets of
card stock or labels and the manual feed slot supports
accepts single sheets only. The following table lists the
maximum basis weights supported.
5
4
C532n
5
3
4
C530dn, C532dn,
3
C534n, and C534dn
Lexmark C530, C532, and C534: Overview of card stock and label support
Card stock
(grain long/grain short)
Paper source
Tray 1 (standard tray)120 g/m
Tray 2 (optional tray)120 g/m
Multipurpose feeder
Manual feed slot
* Vinyl labels are not supported.
Index BristolTagCoverPaper
120 g/m
2
/163 g/m
2
/163 g/m
2
/163 g/m
2
120 g/m2/163 g/m
2
120 g/m2/163 g/m
2
120 g/m2/163 g/m
2
135 g/m2/176 g/m
2
135 g/m2/176 g/m
2
135 g/m2/176 g/m
Labels*
2
2
2
131 g/m
131 g/m
131 g/m
Media specifications
LabelsWidth:76.2 to 216 mm (3 to 8.5 in.)
Length:123.8 to 355.6 mm (4.88 to 14 in.)
2
Weight:131 g/m
Thickness:0.13 to 0.20 mm (0.005 to 0.008 in.)
Smoothness:100 to 400 Sheffield*
*150—250 Sheffield is optimal. Using media higher than 300 Sheffield could result in printing degradation.
Card StockWeight: Up to 163 g/m
Up to 163 g/m
Cover StockWeight: Up to 176 g/m
For more information on the supported media sizes, see the printer User’s Guide on the publications CD.
(35 lb)
2
Index Bristol (90 lb)
2
Tag (100 lb)
2
29
Lexmark C530, C532, and C534
Pick roller technology
The Lexmark C530, C532, and C534 paper feeding mechanism uses advanced technology that enhances feeding
reliability. The Lexmark C530, C532, and C534 trays reliably feed all supported media.
The Lexmark C530, C532, and C534 uses an auto compensator to pick the media rather than the corner buckler system
used by earlier printer models.
The Lexmark C530, C532, and C534 trays have two rollers that touch the media in two places (see Figure 14 on page 76).
Avoid placing deep perforations in these areas since the media may nest, causing multiple sheet feeds. Perforations that
could cause nesting and tenting should fall outside the 0.31—1.05 in. area on the leading edge of the media. (This is
different from the 0.50 in. we recommend leaving at the top of the form for printers with a corner buckler system.) You may
want to use micro-perfs to avoid nesting problems. See Perforations and die-cuts on page 8 for more information.
Pick roller location
0.31 in.
1.05 in.
1.93 in.
4.84 in.
5.43 in.
Direction of feed
Figure 6. Location of pick rollers
1.34 in.
30
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