U.S. patent application number 16/844782 was filed with the patent office on 2021-10-14 for nano-fabrication system with cleaning system for cleaning a faceplate of a dispenser and method of cleaning the faceplate.
The applicant listed for this patent is CANON KABUSHIKI KAISHA. Invention is credited to Jason Battin, Craig William Cone, Antoine Dellinger, Hiroyuki Kondo, Roger R. Wenzel.
Application Number | 20210318609 16/844782 |
Document ID | / |
Family ID | 1000005866162 |
Filed Date | 2021-10-14 |
United States Patent
Application |
20210318609 |
Kind Code |
A1 |
Cone; Craig William ; et
al. |
October 14, 2021 |
NANO-FABRICATION SYSTEM WITH CLEANING SYSTEM FOR CLEANING A
FACEPLATE OF A DISPENSER AND METHOD OF CLEANING THE FACEPLATE
Abstract
A method of cleaning a dispenser including a faceplate,
comprises emitting light over the surface of the faceplate across
the width of the faceplate, measuring an intensity of the light at
a plurality of points on the surface of the faceplate after the
light has passed over the width, determining, based on the measured
light intensity, whether an amount of accumulated formable material
on the faceplate is greater than a predetermined value, and in a
case that the amount of accumulated formable material is greater
than a predetermined value, imparting a suction force on the
surface of the faceplate using the vacuum at a distance from the
faceplate to remove at least a portion of the accumulated formable
material from the surface of the faceplate.
Inventors: |
Cone; Craig William;
(Austin, TX) ; Wenzel; Roger R.; (Jarell, TX)
; Battin; Jason; (Pflugerville, TX) ; Dellinger;
Antoine; (Liberty Hill, TX) ; Kondo; Hiroyuki;
(Utsunomiya-shi, JP) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
CANON KABUSHIKI KAISHA |
Tokyo |
|
JP |
|
|
Family ID: |
1000005866162 |
Appl. No.: |
16/844782 |
Filed: |
April 9, 2020 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
A47L 9/2815 20130101;
G03F 7/0002 20130101 |
International
Class: |
G03F 7/00 20060101
G03F007/00; A47L 9/28 20060101 A47L009/28 |
Claims
1. A method of cleaning a dispenser including a faceplate, the
faceplate having a first end, a second end, a surface, a length
extending in an X dimension from the first end to the second end,
and a width extending in a Y dimension, the method comprising:
translating a light emitter along the X dimension across the length
of the faceplate; emitting light from the light emitter over the
surface of the faceplate along the Y dimension during the
translating of the light emitter; measuring an intensity of the
light at a plurality of points on the surface of the faceplate
along the X dimension after the light has passed over the surface
of the faceplate along the Y dimension; determining, based on the
measured light intensity, whether an amount of accumulated formable
material of at least one point of the plurality of points is
greater than a predetermined value; and in a case that the amount
of accumulated formable material at the at least one point of the
plurality of points is determined to be greater than a
predetermined value: translating a vacuum apparatus across the
faceplate along the X dimension, the vacuum apparatus being located
a distance from the surface of the faceplate; and imparting a
suction force on the surface of the faceplate using the vacuum
apparatus during the translating of the vacuum apparatus to remove
at least a portion of the accumulated formable material from the
surface of the faceplate.
2. The method of claim 1, further comprising: an additional
translating of the light emitter along the X dimension across the
length of the faceplate during the translation of the vacuum
apparatus; an additional emitting of light from the light emitter
over the surface of the faceplate along the Y dimension during the
additional translating of the light emitter; an additional
measuring of an intensity of the light at another plurality of
points on the surface of the faceplate along the X dimension after
the light has passed over the faceplate along the Y dimension
during the additional emitting; determining whether to adjust a
position of vacuum apparatus relative to the surface of the
faceplate based on the additional measured light intensity; and in
a case that it is determined to adjust the position of the vacuum
apparatus, adjusting the position of the vacuum apparatus relative
to the faceplate.
3. The method of claim 2, wherein adjusting the position of the
vacuum apparatus relative to the faceplate comprises performing a
calibration method to optimize the position of the vacuum apparatus
relative to the surface of the faceplate.
4. The method of claim 2, further comprising: generating a set of
baseline data representing measured light intensity at the
plurality of points in the X dimension of the faceplate when the
faceplate is free of accumulated formable material, wherein the
determining of whether to adjust the position of the vacuum
apparatus relative to the surface of the faceplate is further based
on a comparison between the additional measured light intensity and
the baseline data.
5. The method of claim 4, further comprising: determining an actual
location in the X dimension of the first end of the faceplate and
the second end of the faceplate based on the baseline data; and
determining a measured location in the X dimension of the first end
of the faceplate and the second end of the faceplate based on the
additional measured light intensity, wherein the determining of
whether to adjust the position of the vacuum apparatus relative to
the surface of the faceplate is further based on a comparison
between the actual location of the first end of the faceplate and
the second end of the faceplate with the measured location of the
first end of the faceplate and the second end of the faceplate.
6. The method of claim 1, further comprising: prior to translating
the light emitter along the X dimension across the length of the
faceplate, performing a calibration method to optimize a position
of the vacuum apparatus relative to the surface of the
faceplate.
7. The method of claim 6, wherein the performing of the calibration
method comprises: optimizing an angle of the vacuum apparatus
relative to the surface of the faceplate; optimizing a distance
between the vacuum apparatus and the surface of the faceplate; and
optimizing an angle of a direction of travel of the vacuum
apparatus relative to the surface of the faceplate.
8. The method of claim 7, wherein optimizing the angle of the
vacuum apparatus relative to the surface of the faceplate,
comprises: (a) setting an initial selection for each of the angle
of the vacuum apparatus relative to the surface of the faceplate,
the distance between the vacuum apparatus and the surface of the
faceplate, and the angle of the direction of travel of the vacuum
apparatus relative to the surface of the faceplate; (b) additional
translating of the light emitter along the X dimension across the
length of the faceplate; (c) additional emitting of the light from
the light emitter over the surface of the faceplate along the Y
dimension during the further translating of the light emitter; (d)
additional measuring an intensity of the light at the plurality of
points on the surface of the faceplate along the X dimension after
the light has passed over the surface of the faceplate along the Y
dimension; (e) adjusting the position of the angle of the vacuum
apparatus relative to the surface of the faceplate while
maintaining the initially selected distance between the vacuum
apparatus and the surface of the faceplate, and while maintaining
the initially selected angle of the direction of travel of the
vacuum apparatus relative to the surface of the faceplate; and (f)
repeating steps (b) to (e) until the measured light intensity
indicates that an optimal selection of the angle of the vacuum
apparatus relative to the surface of the faceplate has been
achieved.
9. The method of claim 7, wherein optimizing the distance between
the vacuum apparatus and the surface of the faceplate, comprises:
(a) setting an initial selection for each of the angle of the
vacuum apparatus relative to the surface of the faceplate, the
distance between the vacuum apparatus and the surface of the
faceplate, and the angle of the direction of travel of the vacuum
apparatus relative to the surface of the faceplate; (b) additional
translating of the light emitter along the X dimension across the
length of the faceplate; (c) additional emitting of the light from
the light emitter over the surface of the faceplate along the Y
dimension during the further translating of the light emitter; (d)
additional measuring an intensity of the light at the plurality of
points on the surface of the faceplate along the X dimension after
the light has passed over the surface of the faceplate along the Y
dimension; (e) adjusting the selection of the distance between the
vacuum apparatus and the surface of the faceplate while maintaining
the initially selected angle of the vacuum apparatus relative to
the surface of the faceplate, and while maintaining the initially
selected angle of the direction of travel of the vacuum apparatus
relative to the surface of the faceplate; and (f) repeating steps
(b) to (e) until the measured light intensity indicates that an
optimal selection of the distance between the vacuum apparatus and
the surface of the faceplate has been achieved.
10. The method of claim 7, wherein optimizing the angle of the
direction of travel of the vacuum apparatus relative to the surface
of the faceplate, comprises: (a) setting an initial selection for
each of the angle of the vacuum apparatus relative to the surface
of the faceplate, the distance between the vacuum apparatus and the
surface of the faceplate, and the angle of the direction of travel
of the vacuum apparatus relative to the surface of the faceplate;
(b) additional translating of the light emitter along the X
dimension across the length of the faceplate; (c) additional
emitting of the light from the light emitter over the surface of
the faceplate along the Y dimension during the further translating
of the light emitter; (d) additional measuring an intensity of the
light at the plurality of points on the surface of the faceplate
along the X dimension after the light has passed over the surface
of the faceplate along the Y dimension; (e) adjusting the position
of the angle of the direction of travel of the vacuum apparatus
relative to the surface of the faceplate while maintaining the
initially selected distance between the vacuum apparatus and the
surface of the faceplate, and while maintaining the initially
selected angle of the vacuum apparatus relative to the surface of
the faceplate; and (f) repeating steps (b) to (e) until the
measured light intensity indicates that an optimal selection of the
angle of the direction of travel of the vacuum apparatus relative
to the surface of the faceplate has been achieved.
11. The method of claim 7, wherein the calibration method is
performed either prior to accumulating any formable material on the
surface of the faceplate or after removing any accumulated formable
material on the surface of the template.
12. The method of claim 11, wherein the performing of the
calibration method further comprises: after optimizing the angle of
the vacuum apparatus relative to the surface of the faceplate,
after optimizing the distance between the vacuum apparatus and the
surface of the faceplate, and after optimizing the angle of the
direction of travel of the vacuum apparatus relative to the surface
of the faceplate: generating a set of baseline data representing
measured light intensity at the plurality of points in the X
dimension of the faceplate when the faceplate is free of
accumulated formable material.
13. The method of claim 1, wherein the vacuum apparatus comprises
an orifice facing the surface of the faceplate.
14. The method of claim 13, wherein the orifice extends in the Y
dimension across the surface of the faceplate.
15. The method of claim 13, wherein the light emitter is configured
to direct the emitted light across the orifice.
16. The method of claim 1, further comprising increasing the
suction force when the vacuum apparatus reaches a predetermined
position in the X dimension.
17. The method of claim 16, further comprising maintaining the
increased suction force until the vacuum apparatus reaches the
second end of the faceplate.
18. The method of claim 1, further comprising: generating a set of
baseline data representing measured light intensity at the
plurality of points in the X dimension of the faceplate when the
faceplate is free of accumulated formable material; after imparting
the suction force on the surface of the faceplate: additional
translating of the light emitter along the X dimension across the
length of the faceplate; additional emitting of light from the
light emitter over the surface of the faceplate along the Y
dimension during the second translating of the light emitter;
additional measuring of an intensity of the light at an additional
plurality of points on the surface of the faceplate along the X
dimension after the light has passed over the faceplate along the Y
dimension during the additional emitting; and determining whether
the at least a portion of the accumulated formable material was
removed from the faceplate based on a comparison of the additional
measured light intensity and the baseline data.
19. A dispensing system, comprising: a dispenser including a
faceplate, the faceplate having: a first end; a second end; a
surface; a length extending in an X dimension from the first end to
the second end; and a width extending in a Y dimension; a vacuum
apparatus facing the faceplate and located a distance from the
faceplate; a light emitter; a light receiver; a translating
mechanism; one or more processors; and one or more memories storing
instructions, when executed by the one or more processors, causes
the dispensing system to: actuate the translating mechanism to
translate the light emitter along the X dimension across the length
of the faceplate; actuate the light emitter to emit light over the
surface of the faceplate along the Y dimension during the
translating of the light emitter; actuate the light receiver to
measure an intensity of the light at a plurality of points on the
surface of the faceplate along the X dimension after the light has
passed over the surface of the faceplate along the Y dimension;
determine, based on the measured light intensity, whether an amount
of accumulated formable material of at least one point of the
plurality of points is greater than a predetermined value; and in a
case that the amount of accumulated formable material at the at
least one point of the plurality of points is determined to be
greater than a predetermined value: actuate the translating
mechanism to translate the vacuum apparatus across the faceplate
along the X dimension; and impart a suction force on the surface of
the faceplate using the vacuum apparatus during the translating of
the vacuum apparatus to remove at least a portion of the
accumulated formable material from the surface of the
faceplate.
20. A method of making an article, comprising: cleaning a dispenser
including a faceplate, the faceplate having a first end, a second
end, a surface, a length extending in an X dimension from the first
end to the second end, and a width extending in a Y dimension, the
cleaning including: translating a light emitter along the X
dimension across the length of the faceplate; emitting light from
the light emitter over the surface of the faceplate along the Y
dimension during the translating of the light emitter; measuring an
intensity of the light at a plurality of points on the surface of
the faceplate along the X dimension after the light has passed over
the surface of the faceplate along the Y dimension; determining,
based on the measured light intensity, whether an amount of
accumulated formable material of at least one point of the
plurality of points is greater than a predetermined value; and in a
case that the amount of accumulated formable material at the at
least one point of the plurality of points is determined to be
greater than a predetermined value: translating a vacuum apparatus
across the faceplate along the X dimension, the vacuum apparatus
being located a distance from the surface of the faceplate; and
imparting a suction force on the surface of the faceplate using the
vacuum apparatus during the translating of the vacuum apparatus to
remove at least a portion of the accumulated formable material from
the surface of the faceplate; dispensing a portion of the formable
material onto a substrate using the dispenser; forming a pattern or
a layer of the dispensed formable material on the substrate; and
processing the formed pattern or layer to make the article.
Description
BACKGROUND
Field of Art
[0001] The present disclosure relates to a nano-fabrication system
having a cleaning system for cleaning a faceplate of a dispenser
and a method of cleaning the faceplate.
Description of the Related Art
[0002] Nano-fabrication includes the fabrication of very small
structures that have features on the order of 100 nanometers or
smaller. One application in which nano-fabrication has had a
sizeable impact is in the fabrication of integrated circuits. The
semiconductor processing industry continues to strive for larger
production yields while increasing the circuits per unit area
formed on a substrate. Improvements in nano-fabrication include
providing greater process control and/or improving throughput while
also allowing continued reduction of the minimum feature dimensions
of the structures formed.
[0003] One nano-fabrication technique in use today is commonly
referred to as nanoimprint lithography. Nanoimprint lithography is
useful in a variety of applications including, for example,
fabricating one or more layers of integrated devices by shaping a
film on a substrate. Examples of an integrated device include but
are not limited to CMOS logic, microprocessors, NAND Flash memory,
NOR Flash memory, DRAM memory, MRAM, 3D cross-point memory, Re-RAM,
Fe-RAM, SU-RAM, MEMS, and the like. Exemplary nanoimprint
lithography systems and processes are described in detail in
numerous publications, such as U.S. Pat. Nos. 8,349,241, 8,066,930,
and 6,936,194, all of which are hereby incorporated by reference
herein.
[0004] The nanoimprint lithography technique disclosed in each of
the aforementioned patents describes the shaping of a film on a
substrate by the formation of a relief pattern in a formable
material (polymerizable) layer. The shape of this film may then be
used to transfer a pattern corresponding to the relief pattern into
and/or onto an underlying substrate.
[0005] The patterning process uses a template spaced apart from the
substrate and the formable material is applied between the template
and the substrate. The template is brought into contact with the
formable material causing the formable material to spread and fill
the space between the template and the substrate. The formable
liquid is solidified to form a film that has a shape (pattern)
conforming to a shape of the surface of the template that is in
contact with the formable liquid. After solidification, the
template is separated from the solidified layer such that the
template and the substrate are spaced apart.
[0006] The substrate and the solidified layer may then be subjected
to additional processes, such as etching processes, to transfer an
image into the substrate that corresponds to the pattern in one or
both of the solidified layer and/or patterned layers that are
underneath the solidified layer. The patterned substrate can be
further subjected to known steps and processes for device (article)
fabrication, including, for example, curing, oxidation, layer
formation, deposition, doping, planarization, etching, formable
material removal, dicing, bonding, and packaging, and the like.
[0007] The nano-fabrication technique involves dispensing the
formable material from a dispenser onto the substrate. Over many
dispensing cycles, the formable material may begin to accumulate on
a faceplate of the dispenser. Eventually, the amount of
accumulation can interfere with the production and needs to be
cleaned. It desirable for a cleaning system and method that does
not require physical contact with the faceplate.
SUMMARY
[0008] A method of cleaning a dispenser including a faceplate, the
faceplate having a first end, a second end, a surface, a length
extending in an X dimension from the first end to the second end,
and a width extending in a Y dimension, the method comprising:
translating a light emitter along the X dimension across the length
of the faceplate, emitting light from the light emitter over the
surface of the faceplate along the Y dimension during the
translating of the light emitter, measuring an intensity of the
light at a plurality of points on the surface of the faceplate
along the X dimension after the light has passed over the surface
of the faceplate along the Y dimension, determining, based on the
measured light intensity, whether an amount of accumulated formable
material of at least one point of the plurality of points is
greater than a predetermined value, and in a case that the amount
of accumulated formable material at the at least one point of the
plurality of points is determined to be greater than a
predetermined value: translating a vacuum apparatus across the
faceplate along the X dimension, the vacuum apparatus being located
a distance from the surface of the faceplate, and imparting a
suction force on the surface of the faceplate using the vacuum
apparatus during the translating of the vacuum apparatus to remove
at least a portion of the accumulated formable material from the
surface of the faceplate
[0009] A dispensing system, comprising a dispenser including a
faceplate, the faceplate having: a first end, a second end, a
surface, a length extending in an X dimension from the first end to
the second end, and a width extending in a Y dimension, a vacuum
apparatus facing the faceplate and located a distance from the
faceplate, a light emitter, a light receiver, a translating
mechanism, one or more processors, and one or more memories storing
instructions, when executed by the one or more processors, causes
the dispensing system to: actuate the translating mechanism to
translate the light emitter along the X dimension across the length
of the faceplate, actuate the light emitter to emit light over the
surface of the faceplate along the Y dimension during the
translating of the light emitter, actuate the light receiver to
measure an intensity of the light at a plurality of points on the
surface of the faceplate along the X dimension after the light has
passed over the surface of the faceplate along the Y dimension,
determine, based on the measured light intensity, whether an amount
of accumulated formable material of at least one point of the
plurality of points is greater than a predetermined value, and in a
case that the amount of accumulated formable material at the at
least one point of the plurality of points is determined to be
greater than a predetermined value: actuate the translating
mechanism to translate the vacuum apparatus across the faceplate
along the X dimension, and impart a suction force on the surface of
the faceplate using the vacuum apparatus during the translating of
the vacuum apparatus to remove at least a portion of the
accumulated formable material from the surface of the
faceplate.
[0010] A method of making an article, comprising cleaning a
dispenser including a faceplate, the faceplate having a first end,
a second end, a surface, a length extending in an X dimension from
the first end to the second end, and a width extending in a Y
dimension, the cleaning including: translating a light emitter
along the X dimension across the length of the faceplate, emitting
light from the light emitter over the surface of the faceplate
along the Y dimension during the translating of the light
emitter,
measuring an intensity of the light at a plurality of points on the
surface of the faceplate along the X dimension after the light has
passed over the surface of the faceplate along the Y dimension,
determining, based on the measured light intensity, whether an
amount of accumulated formable material of at least one point of
the plurality of points is greater than a predetermined value, and
in a case that the amount of accumulated formable material at the
at least one point of the plurality of points is determined to be
greater than a predetermined value: translating a vacuum apparatus
across the faceplate along the X dimension, the vacuum apparatus
being located a distance from the surface of the faceplate, and
imparting a suction force on the surface of the faceplate using the
vacuum apparatus during the translating of the vacuum apparatus to
remove at least a portion of the accumulated formable material from
the surface of the faceplate, dispensing a portion of the formable
material onto a substrate using the dispenser, forming a pattern or
a layer of the dispensed formable material on the substrate, and
processing the formed pattern or layer to make the article.
[0011] These and other objects, features, and advantages of the
present disclosure will become apparent upon reading the following
detailed description of exemplary embodiments of the present
disclosure, when taken in conjunction with the appended drawings,
and provided claims.
BRIEF DESCRIPTION OF DRAWINGS
[0012] So that features and advantages of the present disclosure
can be understood in detail, a more particular description of
embodiments of the disclosure may be had by reference to the
embodiments illustrated in the appended drawings. It is to be
noted, however, that the appended drawings only illustrate typical
embodiments of the disclosure, and are therefore not to be
considered limiting of its scope, for the disclosure may admit to
other equally effective embodiments.
[0013] FIG. 1 is an illustration of an exemplary nanoimprint
lithography system in accordance with an example embodiment.
[0014] FIG. 2 is an illustration of an exemplary template in
accordance with an example embodiment.
[0015] FIG. 3 is a flowchart illustrating an exemplary imprinting
method in accordance with an example embodiment.
[0016] FIG. 4A shows a perspective view of a cleaning system
oriented in a first operative position in accordance with an
example embodiment.
[0017] FIG. 4B shows a perspective view of the cleaning system of
FIG. 4A oriented in a second operative position in accordance with
an example embodiment.
[0018] FIG. 5A shows a side view of a dispenser in accordance with
an example embodiment.
[0019] FIG. 5B shows an underside view of the dispenser of FIG. 5A
in accordance with an example embodiment.
[0020] FIG. 5C shows an end view of the dispenser of FIG. 5A in
accordance with an example embodiment.
[0021] FIG. 6A shows a perspective view of a portion of the
cleaning system of FIGS. 4A and 4B in accordance with an example
embodiment.
[0022] FIG. 6B shows an exploded view of the portion of FIG. 6A in
accordance with an example embodiment.
[0023] FIG. 7 shows an underside view of the dispenser of FIGS. 5A
to 5C with portions omitted in accordance with an example
embodiment.
[0024] FIG. 8 shows a perspective exploded view of a vacuum
apparatus in accordance with an example embodiment.
[0025] FIG. 9A shows a perspective end view of a portion of the
cleaning system in a first orientation, with omissions, in
accordance with an example embodiment.
[0026] FIG. 9B shows a perspective end view of the portion of the
cleaning system of FIG. 9A, in a second orientation, with
omissions, in accordance with an example embodiment.
[0027] FIG. 10A shows a schematic representation of the impact of a
first guide rail angle on a position of the vacuum apparatus
relative to a faceplate of the dispenser, in accordance with an
example embodiment.
[0028] FIG. 10B shows a schematic representation of the impact of a
second guide rail angle on a position of the vacuum apparatus
relative to a faceplate of the dispenser, in accordance with an
example embodiment.
[0029] FIG. 11A shows end view of the cleaning system in a first
orientation, with omissions, in accordance with an example
embodiment.
[0030] FIG. 11B shows end view of the cleaning system in a second
orientation, with omissions, in accordance with an example
embodiment.
[0031] FIG. 12 shows end view of the cleaning system in another
orientation, with omissions, in accordance with an example
embodiment
[0032] FIG. 13 shows a flowchart of a calibration method in
accordance with an example embodiment.
[0033] FIG. 14 shows an example data chart representing light
intensity from data collected when a faceplate is free of
accumulated material, and a side view of the dispenser
corresponding to the data chart, in accordance with an example
embodiment.
[0034] FIG. 15A shows a side view of the dispenser after formable
material has accumulated on the surface of a faceplate, in
accordance with an example embodiment.
[0035] FIG. 15B shows a bottom view of the dispenser of FIG. 15A
after formable material has accumulated on the surface of the
faceplate, in accordance with an example embodiment.
[0036] FIG. 15C shows a perspective view of the dispenser of FIG.
15A after formable material has accumulated on the surface of the
faceplate, in accordance with an example embodiment.
[0037] FIG. 16 shows a flowchart of a cleaning method in accordance
with an example embodiment.
[0038] FIG. 17 shows a data chart representing light intensity from
data collected when formable material has accumulated on a surface
of a faceplate, in accordance with an example embodiment.
[0039] FIG. 18 shows a data chart representing light intensity from
data collected while a vacuum apparatus suctions formable material
from a surface of a faceplate, in accordance with an example
embodiment.
[0040] FIG. 19 shows a data chart representing light intensity from
data collected after formable material has been removed from a
surface of a faceplate, in accordance with an example
embodiment.
[0041] Throughout the figures, the same reference numerals and
characters, unless otherwise stated, are used to denote like
features, elements, components or portions of the illustrated
embodiments. Moreover, while the subject disclosure will now be
described in detail with reference to the figures, it is done so in
connection with the illustrative exemplary embodiments. It is
intended that changes and modifications can be made to the
described exemplary embodiments without departing from the true
scope and spirit of the subject disclosure as defined by the
appended claims.
DETAILED DESCRIPTION
[0042] Throughout this disclosure, reference is made primarily to
nanoimprint lithography, which uses the above-mentioned patterned
template to impart a pattern onto formable liquid. However, as
mentioned below, in an alternative embodiment, the template is
featureless in which case a planar surface may be formed on the
substrate. In such embodiments where a planar surface is formed,
the formation process is referred to as planarization. Thus,
throughout this disclosure, whenever nanoimprint lithography is
mentioned, it should be understood that the same method is
applicable to planarization. The term superstrate is used in place
of the term template in instances where the template is
featureless.
[0043] As noted above, the nano-fabrication technique involves
dispensing the formable material from a dispenser onto the
substrate. Over many dispensing cycles, the formable material may
accumulate on a faceplate of the dispenser. Eventually, the amount
of accumulation can interfere with the production and needs to be
cleaned. It desirable for a cleaning system and method that does
not require physical contact with the faceplate.
Nanoimprint System (Shaping System)
[0044] FIG. 1 is an illustration of a nanoimprint lithography
system 100 in which an embodiment may be implemented. The
nanoimprint lithography system 100 is used to shape a film on a
substrate 102. The substrate 102 may be coupled to a substrate
chuck 104. The substrate chuck 104 may be but is not limited to a
vacuum chuck, pin-type chuck, groove-type chuck, electrostatic
chuck, electromagnetic chuck, and/or the like.
[0045] The substrate 102 and the substrate chuck 104 may be further
supported by a substrate positioning stage 106. The substrate
positioning stage 106 may provide translational and/or rotational
motion along one or more of the x, y, z, .theta., and .phi.-axes.
The substrate positioning stage 106, the substrate 102, and the
substrate chuck 104 may also be positioned on a base (not shown).
The substrate positioning stage may be a part of a positioning
system.
[0046] Spaced-apart from the substrate 102 is a template 108. The
template 108 may include a body having a mesa (also referred to as
a mold) 110 extending towards the substrate 102 on a front side of
the template 108. The mesa 110 may have a patterning surface 112
thereon also on the front side of the template 108. Alternatively,
the template 108 may be formed without the mesa 110, in which case
the surface of the template facing the substrate 102 is equivalent
to the mold 110 and the patterning surface 112 is that surface of
the template 108 facing the substrate 102.
[0047] The template 108 may be formed from such materials
including, but not limited to, fused-silica, quartz, silicon,
organic polymers, siloxane polymers, borosilicate glass,
fluorocarbon polymers, metal, hardened sapphire, and/or the like.
The patterning surface 112 may have features defined by a plurality
of spaced-apart template recesses 114 and/or template protrusions
116. The patterning surface 112 defines a pattern that forms the
basis of a pattern to be formed on the substrate 102. In an
alternative embodiment, the patterning surface 112 is featureless
in which case a planar surface is formed on the substrate. In an
alternative embodiment, the patterning surface 112 is featureless
and the same size as the substrate and a planar surface is formed
across the entire substrate. In such embodiments where a planar
surface is formed, the formation process may be alternatively
referred to as planarization and the featureless template may be
alternatively referred to as a superstrate.
[0048] Template 108 may be coupled to a template chuck 118. The
template chuck 118 may be, but is not limited to, vacuum chuck,
pin-type chuck, groove-type chuck, electrostatic chuck,
electromagnetic chuck, and/or other similar chuck types. The
template chuck 118 may be configured to apply stress, pressure,
and/or strain to template 108 that varies across the template 108.
The template chuck 118 may include piezoelectric actuators which
can squeeze and/or stretch different portions of the template 108.
The template chuck 118 may include a system such as a zone based
vacuum chuck, an actuator array, a pressure bladder, etc. which can
apply a pressure differential to a back surface of the template
causing the template to bend and deform.
[0049] The template chuck 118 may be coupled to an imprint head 120
which is a part of the positioning system. The imprint head may be
moveably coupled to a bridge. The imprint head may include one or
more actuators such as voice coil motors, piezoelectric motors,
linear motor, nut and screw motor, etc., which are configured to
move the template chuck 118 relative to the substrate in at least
the z-axis direction, and potentially other directions (e.g. x, y,
.theta., y, and .phi.-axes).
[0050] The nanoimprint lithography system 100 may further comprise
a fluid dispenser 122. The fluid dispenser 122 may also be moveably
coupled to the bridge. In an embodiment, the fluid dispenser 122
and the imprint head 120 share one or more or all positioning
components. In an alternative embodiment, the fluid dispenser 122
and the imprint head 120 move independently from each other. The
fluid dispenser 122 may be used to deposit liquid formable material
124 (e.g., polymerizable material) onto the substrate 102 in a
pattern. Additional formable material 124 may also be added to the
substrate 102 using techniques, such as, drop dispense,
spin-coating, dip coating, chemical vapor deposition (CVD),
physical vapor deposition (PVD), thin film deposition, thick film
deposition, and/or the like prior to the formable material 124
being deposited onto the substrate 102. The formable material 124
may be dispensed upon the substrate 102 before and/or after a
desired volume is defined between the mold 112 and the substrate
102 depending on design considerations. The formable material 124
may comprise a mixture including a monomer as described in U.S.
Pat. Nos. 7,157,036 and 8,076,386, both of which are herein
incorporated by reference.
[0051] Different fluid dispensers 122 may use different
technologies to dispense formable material 124. When the formable
material 124 is jettable, ink jet type dispensers may be used to
dispense the formable material. For example, thermal ink jetting,
microelectromechanical systems (MEMS) based ink jetting, valve jet,
and piezoelectric ink jetting are common techniques for dispensing
jettable liquids.
[0052] The nanoimprint lithography system 100 may further comprise
a radiation source 126 that directs actinic energy along an
exposure path 128. The imprint head and the substrate positioning
stage 106 may be configured to position the template 108 and the
substrate 102 in superimposition with the exposure path 128. The
radiation source 126 sends the actinic energy along the exposure
path 128 after the template 108 has made contact with the formable
material 128. FIG. 1 illustrates the exposure path 128 when the
template 108 is not in contact with the formable material 124, this
is done for illustrative purposes so that the relative position of
the individual components can be easily identified. An individual
skilled in the art would understand that exposure path 128 would
not substantially change when the template 108 is brought into
contact with the formable material 124.
[0053] The nanoimprint lithography system 100 may further comprise
a field camera 136 that is positioned to view the spread of
formable material 124 after the template 108 has made contact with
the formable material 124. FIG. 1 illustrates an optical axis of
the field camera's imaging field as a dashed line. As illustrated
in FIG. 1 the nanoimprint lithography system 100 may include one or
more optical components (dichroic mirrors, beam combiners, prisms,
lenses, mirrors, etc.) which combine the actinic radiation with
light to be detected by the field camera. The field camera 136 may
be configured to detect the spread of formable material under the
template 108. The optical axis of the field camera 136 as
illustrated in FIG. 1 is straight but may be bent by one or more
optical components. The field camera 136 may include one or more of
a CCD, a sensor array, a line camera, and a photodetector which are
configured to gather light that has a wavelength that shows a
contrast between regions underneath the template 108 that are in
contact with the formable material, and regions underneath the
template 108 which are not in contact with the formable material
124. The field camera 136 may be configured to gather monochromatic
images of visible light. The field camera 136 may be configured to
provide images of the spread of formable material 124 underneath
the template 108, the separation of the template 108 from cured
formable material, and can be used to keep track the progress over
the imprinting process.
[0054] The nanoimprint lithography system 100 may further comprise
a droplet inspection system 138 that is separate from the field
camera 136. The droplet inspection system 138 may include one or
more of a CCD, a camera, a line camera, and a photodetector. The
droplet inspection system 138 may include one or more optical
components such as a lenses, mirrors, apertures, filters, prisms,
polarizers, windows, adaptive optics, and/or light sources. The
droplet inspection system 138 may be positioned to inspect droplets
prior to the patterning surface 112 contacting the formable
material 124 on the substrate 102
[0055] The nanoimprint lithography system 100 may further include a
thermal radiation source 134 which may be configured to provide a
spatial distribution of thermal radiation to one or both of the
template 108 and the substrate 102. The thermal radiation source
134 may include one or more sources of thermal electromagnetic
radiation that will heat up one or both of the substrate 102 and
the template 108 and does not cause the formable material 124 to
solidify. The thermal radiation source 134 may include a spatial
light modulator such as a digital micromirror device (DMD), Liquid
Crystal on Silicon (LCoS), Liquid Crystal Device (LCD), etc., to
modulate the spatial temporal distribution of thermal radiation.
The nanoimprint lithography system may further comprise one or more
optical components which are used to combine the actinic radiation,
the thermal radiation, and the radiation gathered by the field
camera 136 onto a single optical path that intersects with the
imprint field when the template 108 comes into contact with the
formable material 124 on the substrate 102. The thermal radiation
source 134 may send the thermal radiation along a thermal radiation
path (which in FIG. 1 is illustrated as 2 thick dark lines) after
the template 108 has made contact with the formable material 128.
FIG. 1 illustrates the thermal radiation path when the template 108
is not in contact with the formable material 124, this is done for
illustrative purposes so that the relative position of the
individual components can be easily identified. An individual
skilled in the art would understand that the thermal radiation path
would not substantially change when the template 108 is brought
into contact with the formable material 124. In FIG. 1 the thermal
radiation path is shown terminating at the template 108, but it may
also terminate at the substrate 102. In an alternative embodiment,
the thermal radiation source 134 is underneath the substrate 102,
and thermal radiation path is not combined with the actinic
radiation and visible light.
[0056] Prior to the formable material 124 being dispensed onto the
substrate, a substrate coating 132 may be applied to the substrate
102. In an embodiment, the substrate coating 132 may be an adhesion
layer. In an embodiment, the substrate coating 132 may be applied
to the substrate 102 prior to the substrate being loaded onto the
substrate chuck 104. In an alternative embodiment, the substrate
coating 132 may be applied to substrate 102 while the substrate 102
is on the substrate chuck 104. In an embodiment, the substrate
coating 132 may be applied by spin coating, dip coating, etc. In an
embodiment, the substrate 102 may be a semiconductor wafer. In
another embodiment, the substrate 102 may be a blank template
(replica blank) that may be used to create a daughter template
after being imprinted.
[0057] The nanoimprint lithography system 100 may be regulated,
controlled, and/or directed by one or more processors 140
(controller) in communication with one or more components and/or
subsystems such as the substrate chuck 104, the substrate
positioning stage 106, the template chuck 118, the imprint head
120, the fluid dispenser 122, the radiation source 126, the thermal
radiation source 134, the field camera 136 and/or the droplet
inspection system 138. The processor 140 may operate based on
instructions in a computer readable program stored in a
non-transitory computer readable memory 142. The processor 140 may
be or include one or more of a CPU, MPU, GPU, ASIC, FPGA, DSP, and
a general purpose computer. The processor 140 may be a purpose
built controller or may be a general purpose computing device that
is adapted to be a controller. Examples of a non-transitory
computer readable memory include but are not limited to RAM, ROM,
CD, DVD, Blu-Ray, hard drive, networked attached storage (NAS), an
intranet connected non-transitory computer readable storage device,
and an internet connected non-transitory computer readable storage
device.
[0058] Either the imprint head 120, the substrate positioning stage
106, or both varies a distance between the mold 110 and the
substrate 102 to define a desired space (a bounded physical extent
in three dimensions) that is filled with the formable material 124.
For example, the imprint head 120 may apply a force to the template
108 such that mold 110 is in contact with the formable material
124. After the desired volume is filled with the formable material
124, the radiation source 126 produces actinic radiation (e.g. UV,
248 nm, 280 nm, 350 nm, 365 nm, 395 nm, 400 nm, 405 nm, 435 nm,
etc.) causing formable material 124 to cure, solidify, and/or
cross-link; conforming to a shape of the substrate surface 130 and
the patterning surface 112, defining a patterned layer on the
substrate 102. The formable material 124 is cured while the
template 108 is in contact with formable material 124 forming the
patterned layer on the substrate 102. Thus, the nanoimprint
lithography system 100 uses an imprinting process to form the
patterned layer which has recesses and protrusions which are an
inverse of the pattern in the patterning surface 112. In an
alternative embodiment, the nanoimprint lithography system 100 uses
an imprinting process to form the planar layer with a featureless
patterning surface 112.
[0059] The imprinting process may be done repeatedly in a plurality
of imprint fields that are spread across the substrate surface 130.
Each of the imprint fields may be the same size as the mesa 110 or
just the pattern area of the mesa 110. The pattern area of the mesa
110 is a region of the patterning surface 112 which is used to
imprint patterns on a substrate 102 which are features of the
device or are then used in subsequent processes to form features of
the device. The pattern area of the mesa 110 may or may not include
mass velocity variation features which are used to prevent
extrusions. In an alternative embodiment, the substrate 102 has
only one imprint field which is the same size as the substrate 102
or the area of the substrate 102 which is to be patterned with the
mesa 110. In an alternative embodiment, the imprint fields overlap.
Some of the imprint fields may be partial imprint fields which
intersect with a boundary of the substrate 102.
[0060] The patterned layer may be formed such that it has a
residual layer having a residual layer thickness (RLT) that is a
minimum thickness of formable material 124 between the substrate
surface 130 and the patterning surface 112 in each imprint field.
The patterned layer may also include one or more features such as
protrusions which extend above the residual layer having a
thickness. These protrusions match the recesses 114 in the mesa
110.
Template/Superstrate
[0061] FIG. 2 is an illustration of a template 108 that may be used
in an embodiment. The patterning surface 112 may be on a mesa 110
(identified by the dashed box in FIG. 2). The mesa 110 is
surrounded by a recessed surface 244 on the front side of the
template. Mesa sidewalls 246 connect the recessed surface 244 to
patterning surface 112 of the mesa 110. The mesa sidewalls 246
surround the mesa 110. In an embodiment in which the mesa is round
or has rounded corners, the mesa sidewalls 246 refers to a single
mesa sidewall that is a continuous wall without corners.
[0062] An alternative template may be used in another embodiment,
referred herein as a superstrate. In the case of the superstrate,
the patterning surface 112 is featureless. That is, in an
embodiment there is no pattern on the surface 112. A superstrate
with no pattern is used in a planarization process. Thus, when a
planarization process is performed, the superstrate is used in
place of the template shown in FIG. 1.
Imprinting/Planarizing Process
[0063] FIG. 3 is a flowchart of an imprinting process 300 by the
nanoimprint lithography system 100 that can be used to form
patterns in formable material 124 on one or more imprint fields
(also referred to as: pattern areas or shot areas). The imprinting
process 300 may be performed repeatedly on a plurality of
substrates 102 by the nanoimprint lithography system 100. The
processor 140 may be used to control imprinting process 300.
[0064] In an alternative embodiment, a similar process may be
performed to planarize the substrate 102. In the case of
planarizing, substantially the same steps discussed herein with
respect to FIG. 3 are performed, except that a patternless
superstrate is used in place of the template. Thus, it should be
understood that the following description is also applicable to a
planarizing method. When using as superstrate, the superstrate may
be the same size or larger than the substrate 102.
[0065] The beginning of the imprinting process 300 may include a
template mounting step causing a template conveyance mechanism to
mount a template 108 onto the template chuck 118. The imprinting
process may also include a substrate mounting step, the processor
140 may cause a substrate conveyance mechanism to mount the
substrate 102 onto the substrate chuck 104. The substrate may have
one or more coatings and/or structures. The order in which the
template 108 and the substrate 102 are mounted onto the nanoimprint
lithography system 100 is not particularly limited, and the
template 108 and the substrate 102 may be mounted sequentially or
simultaneously.
[0066] In a positioning step, the processor 140 may cause one or
both of the substrate positioning stage 106 and/or a dispenser
positioning stage to move an imprint field i (index i may be
initially set to 1) of the substrate 102 to a fluid dispense
position below the fluid dispenser 122. The substrate 102, may be
divided into N imprint fields, wherein each imprint field is
identified by an index i. In which N is a real integer such as 1,
10, 75, etc. {N.di-elect cons..sup.+}. In a dispensing step S302,
the processor 140 may cause the fluid dispenser 122 to dispense
formable material onto an imprint field i. In an embodiment, the
fluid dispenser 122 dispenses the formable material 124 as a
plurality of droplets. The fluid dispenser 122 may include one
nozzle or multiple nozzles. The fluid dispenser 122 may eject
formable material 124 from the one or more nozzles simultaneously.
The imprint field i may be moved relative to the fluid dispenser
122 while the fluid dispenser is ejecting formable material 124.
Thus, the time at which some of the droplets land on the substrate
may vary across the imprint field i. In an embodiment, during the
dispensing step S302, the formable material 124 may be dispensed
onto a substrate in accordance with a drop pattern. The drop
pattern may include information such as one or more of position to
deposit drops of formable material, the volume of the drops of
formable material, type of formable material, shape parameters of
the drops of formable material, etc.
[0067] After, the droplets are dispensed, then a contacting step
S304 may be initiated, the processor 140 may cause one or both of
the substrate positioning stage 106 and a template positioning
stage to bring the patterning surface 112 of the template 108 into
contact with the formable material 124 in imprint field i.
[0068] During a spreading step S306, the formable material 124 then
spreads out towards the edge of the imprint field i and the mesa
sidewalls 246. The edge of the imprint field may be defined by the
mesa sidewalls 246. How the formable material 124 spreads and fills
the mesa can be observed via the field camera 136 and may be used
to track a progress of a fluid front of formable material.
[0069] In a curing step S308, the processor 140 may send
instructions to the radiation source 126 to send a curing
illumination pattern of actinic radiation through the template 108,
the mesa 110 and the patterning surface 112. The curing
illumination pattern provides enough energy to cure (polymerize)
the formable material 124 under the patterning surface 112.
[0070] In a separation step S310, the processor 140 uses one or
more of the substrate chuck 104, the substrate positioning stage
106, template chuck 118, and the imprint head 120 to separate the
patterning surface 112 of the template 108 from the cured formable
material on the substrate 102.
[0071] If there are additional imprint fields to be imprinted then
the process moves back to step S302. In an embodiment, additional
processing is performed on the substrate 102 in a processing step
S312 so as to create an article of manufacture (e.g. semiconductor
device). In an embodiment, each imprint field includes a plurality
of devices.
[0072] The further processing in processing step S312 may include
etching processes to transfer a relief image into the substrate
that corresponds to the pattern in the patterned layer or an
inverse of that pattern. The further processing in processing step
S312 may also include known steps and processes for article
fabrication, including, for example, curing, oxidation, layer
formation, deposition, doping, planarization, etching, formable
material removal, dicing, bonding, and packaging, and the like. The
substrate 102 may be processed to produce a plurality of articles
(devices).
Drop Dispensing Method
[0073] A drop dispensing method by the nanoimprint lithography
system 100 or planarization system can be used to dispense a
pattern of drops of formable material 124 onto the substrate 102,
which is then imprinted/planarized. Imprinting/planarizing may be
done in a field by field basis or on a whole wafer basis. The drops
of formable material 124 may also be deposited in a field by field
basis or on a whole substrate basis. Even when the drops are
deposited on a whole substrate basis generating the drop pattern is
preferably done on a field by field basis.
[0074] Generating a drop pattern for a full field may include a
processor 140 receiving a substrate pattern of a representative
substrate 102, and a template pattern of a representative template
108.
[0075] The substrate pattern may include information about
substrate topography of the representative substrate, a field of
the representative substrate and/or a full field of the
representative substrate. The substrate topography may be measured,
generated based on previous fabrication steps and/or generated
based on design data. In an alternative embodiment, the substrate
pattern is featureless either because there were no previous
fabrication steps or the substrate had previously been planarized
to reduce topography. The substrate topography may include
information about the shape of an edge such as a beveled edge or a
rounded edge of the representative substrate. The substrate
topography may include information about the shape and position of
one or more flats or notches which identify the orientation of the
substrate. The substrate topography may include information about a
shape and position of a reference edge which surrounds the area of
the substrate on which patterns are to be formed.
[0076] The template pattern may include information about the
topography of the patterning surface 112 of the representative
template. The topography of the patterning surface 112 may be
measured and/or generated based on design data. In an alternative
embodiment, the template pattern of the representative embodiment
is featureless and may be used to planarize the substrate 102. The
patterning surface 112 may be the same size as: an individual full
field; multiple fields; the entire substrate, or larger than the
substrate.
[0077] Once the substrate pattern and the template pattern are
received, a processor 140 may calculate a distribution of formable
material 124 that will produce a film that fills the volume between
the substrate and the patterning surface when the substrate and the
patterning surface are separated by a gap during imprinting. The
distribution of formable material on the substrate may take the
form of: an areal density of formable material; positions of
droplets of formable material; and/or volume of droplets of
formable material. Calculating the distribution of formable
material may take into account one or more of: material properties
of the formable material; material properties of the patterning
surface; material properties of the substrate surface; spatial
variation in volume between the patterning surface and the
substrate surface; fluid flow; evaporation; etc.
Cleaning System
[0078] FIGS. 4A and 4B show perspective views of a cleaning system
400 for cleaning formable material from the dispenser 122, all of
which are parts of the overall system 100. FIG. 5A shows a side
view of the dispenser 122. FIG. 5B shows an underside view of the
dispenser 122. FIG. 5C shows an end view of the dispenser 122. The
dispenser 122 includes a faceplate 133 having a surface 135 in
which a plurality of dispensing nozzles 137 are formed. The number
of nozzles 137 formed in the surface 135 of the faceplate 133 may
be on the order of hundreds, for example 500 or more. The faceplate
133 includes a first end 123 and a second end 125. The faceplate
133 has a length 127 extending in an X dimension from the first end
123 to the second 125. The dispenser 122 has a first flange 129
extending from the first end 123 and a second flange 131 extending
from the second end 125. The faceplate 133 includes a width 139
extending in a Y dimension, the Y dimension being perpendicular to
the X dimension.
[0079] FIG. 4A shows a perspective view the cleaning system 400
oriented in a first operative position and FIG. 4B shows the
cleaning system 400 oriented in a second operative position. The
cleaning system 400 may include a bracket 402 that serves as a
fixed stationary structure to which the other elements described
herein are mounted. The bracket 402 itself may be mounted within a
housing of the overall system 100. The cleaning system 400 may
include a vacuum apparatus 404 coupled with a vacuum source 405
(FIG. 8), a light emitter/sensor 406 that emits and measures
intensity of light 408, a guide rail 410, and a translating
mechanism 412 that translates the vacuum apparatus 404 and light
emitter/sensor 406 along the guide rail 410. The light
emitter/sensor 406 may include a light emitter that emits light and
a corresponding light sensor that measures an intensity of the
light. Such light emitter/sensors are known in the art, for example
a Keyence LV-S62 retro-reflective type beam sensor or a Panasonic
HG-T1010 thru-beam type digital displacement sensor or any other
type of light emitter/sensor may be used. The wavelength(s) of the
emitted light should be selected such that it does not
significantly alter the formable material being dispensed by the
dispenser. That is, as noted above, the formable material may be a
photocurable composition where certain light wavelengths will cure
the formable material or otherwise causes a change to the formable
material. Because the light emitted by the light emitter/sensor 406
is for analytical purposes only, the light wavelength should be
selected to have no impact on the formable material, the light
wavelength is used for measurement and observation.
[0080] As further shown in FIGS. 4A and 4B, the vacuum apparatus
404 and the light emitter/sensor 406 may be coupled with the
translating mechanism 412 via a tray 414 and a sensor bracket 416.
In the example embodiment shown in FIGS. 4A and 4B, the vacuum
apparatus 404 is mounted on the tray 414, while the tray 414 is
mounted to the translating mechanism 412. Furthermore, in the
example embodiment shown in FIGS. 4A and 4B, the light
emitter/sensor 406 is mounted to the tray 414 via the sensor
bracket 416.
[0081] FIG. 6A shows a perspective view of a portion of the
cleaning system of FIGS. 4A and 4B. FIG. 6B shows an exploded view
of the portion of FIG. 6A. FIG. 7 shows an underside view of the
dispenser 122 with only the light emitter/sensor 406 and the light
408 shown. As seen in FIGS. 6A and 6B, the cleaning system 400 may
further include a retroreflector 418 attached to the sensor bracket
416. The retroreflector may be made from a material that reflects
light back to the light source with minimum scattering. Any
suitable retroreflector known in the art may be used. In the
embodiment shown in FIGS. 6A and 6B the retroreflector is a thin
reflective material. The sensor bracket 416 may have U shape with a
first arm 420, a second arm 422 opposing the first arm 420, and a
third arm 424 extending from the first arm 420 to the second arm
422. The third arm 424 extends in the Y dimension. The first arm
420 and the second arm 422 extend in the Z dimension perpendicular
to the Y dimension. The light emitter/sensor 406 may be mounted to
an inner surface of the first arm 420 and the retroreflector 418
may be mounted to an inner surface of the second arm 422, such that
the retroreflector 418 is directly opposite the light emitter of
the light emitter/sensor 406. The third arm 424 of the sensor
bracket 416 may be mounted to an underside surface of the tray 414.
Thus, because of this structural arrangement, as best seen in FIG.
7, the light emitter of the light emitter/sensor 406 emits light
408 across the width 139 of the faceplate 133 in the Y dimension
where the light is reflected by the retroreflector 418. In another
example embodiment, rather than reflecting the light via the
retroreflector 418, a light sensor may be mounted to the inner
surface of the second arm 422 where the retroreflector 418 is shown
in FIG. 6A.
[0082] As best seen in FIGS. 6A and 6B, the vacuum apparatus 404
may also be mounted to an end 426 of the tray 414. In particular,
the vacuum apparatus 404 may include a mounting portion 428 which
may abut an end 426 of the tray 414. The vacuum apparatus 404 may
be mounted to the end 426 of the tray 414 by securing the mounting
portion 428 to the end 426 of the tray 414 using a securing
mechanism 430. The securing mechanism 430 may be a set of screws,
for example. The angle of the vacuum apparatus 404 relative to the
surface 135 of the faceplate 133 can be set by tightening the
securing mechanism 430, which is described in more detail below.
For this reason, the securing mechanism 430 is also referred herein
as the vacuum apparatus angle adjusting mechanism.
[0083] FIG. 8 shows a perspective exploded view of the vacuum
apparatus 404. As best seen in FIG. 8, the vacuum apparatus 404
includes a vacuum orifice 432. The vacuum orifice 432 may be an
elongated slit shape where the length of the vacuum orifice 432 is
much longer than the width of the vacuum orifice 432. For example,
the ratio of the length of the vacuum orifice 432 to the width of
the vacuum office 432 may be from 5:1 to 100:1, may be 10:1 to
90:1, may be 20:1 to 80:1, may be 30:1 to 70:1, or may be 40:1 to
65:1. In one example, the ratio may be 60:1. In an example
embodiment, the length of the vacuum orifice 432 is substantially
the same (e.g., within .+-.20%) as the width 139 of the faceplate
133 in the Y dimension. In an example embodiment, the width of the
vacuum orifice 432 is wide enough so that it does not become
clogged with formable material while being narrow enough to supply
sufficient vacuum (for example, 0.5 mm, 1 mm, etc.). The vacuum
orifice 432 may also have lips on each side which are similar
(e.g., within .+-.30%) in width to the width of the vacuum orifice
432 which helps constrain the suction force to a local region of
the faceplate. The vacuum apparatus 404 may further include a
vacuum connector 434 and a connector port 436. The vacuum connector
434 may include a first end 438 that connects with the connector
port 436 and a second end 440 that connects with the vacuum source
405. Thus, by activating the vacuum source 405, a suction force is
applied to the vacuum orifice 432.
[0084] As seen in FIG. 6A, once the vacuum apparatus 404 is mounted
to the tray 414, the vacuum orifice 432 extends along the width 139
in the Y dimension in the same manner as the light 408.
Furthermore, as seen in FIGS. 4A, 4B, and 6A, the sensor bracket
416, and more particularly the third arm 424, is mounted on the
underside 442 of the tray 414 via securing mechanism 444. The
mounting position of the sensor bracket 416 may be particularly
selected such that the light 408 emitted by the light
emitter/sensor 406 travels precisely across the surface 135 of the
faceplate 133 above the nozzle orifice 432. That is, due to the
mounting positions of both the vacuum apparatus 404 and light
emitter/sensor 406, the emitted light 408 and the nozzle orifice
432 are coplanar in a Y-Z plane.
[0085] Because the tray 414 is coupled with the translating
mechanism 412, when the translating mechanism 412 actuates, the
tray 414 travels along the guide rail 410 in the X dimension.
Likewise, because the vacuum apparatus 404 and the light
emitter/sensor 406 are mounted to the tray 414, the translation of
the tray 414, in turn, translates the vacuum apparatus 404 and the
light emitter/sensor 406 along the guide rail 410 in the X
dimension. Thus, it can be said that the translating mechanism 412
translates the vacuum apparatus 404 and the light emitter/sensor
406 in the X dimension. The translating mechanism 412 may be any
mechanism known in the art that suitable for imparting linear
translation on an object. For example, the translating mechanism
may be a linear actuator that may include: a stepper motor; a
linear motor; a moving coil; a hydraulic actuator; pneumatic
actuator; and the like. The linear actuator may include a position
encoder. The position encoder may be a rotary or linear encoder.
Such encoders are known in the art and provide position information
at a particular moment in time. That is, the position of the light
emitter/sensor 406 and the vacuum apparatus 404 in the X dimension
can be known based on the information provided by the position
encoder, when properly calibrated.
[0086] The translation of the vacuum apparatus 404 and the light
emitter/sensor 406 is best seen by comparing FIG. 4A and FIG. 4B.
In FIG. 4A the vacuum apparatus 404 and the light emitter/sensor
406 have been translated fully across the faceplate 135 in the X
dimension such that the light 408 extends across the width 139 in Y
dimension at the second end 125 of the faceplate 133. In FIG. 4B
the vacuum apparatus 404 and the light emitter/sensor 406 have been
fully retracted along the faceplate 133 in the X dimension such
that the light 408 extends across the width 139 in Y dimension at
the first end 125 of the faceplate 133. In this manner, the light
408 can be emitted and measured at a plurality of points along the
X dimension of faceplate 133 by measuring the light as the
light/emitter sensor 406 travels along the X dimension. Similarly,
a vacuum force can be selectively imparted on the faceplate 133 by
actuating the vacuum source 405 when the vacuum orifice 432 of the
vacuum apparatus 404 travels along the X dimension. The particular
position of the light emitter/sensor 406 in the X dimension can be
determined using the rotary or linear encoder noted above.
[0087] FIGS. 9A and 9B show perspective end views of a portion of
the cleaning system 400, with other structure omitted. In
particular, FIGS. 9A and 9B show the bracket 402 and guide rail 410
and related structure, while omitting the structure relating to the
translation mechanism 412 and all of the elements coupled with the
translation mechanism 412. These elements are omitted from FIGS. 9A
and 9B so that a change in an angle 411a, 411b of the guide rail
410 is visible. FIG. 9A shows a first orientation of the guide rail
410. FIG. 9B shows a second orientation of the guide rail 410.
[0088] As seen in FIGS. 4A, 4B, 9A and 9B, the cleaning system 400
may include a guide rail angle adjustment mechanism 446. The guide
rail angle adjustment mechanism 446 is configured to adjust the
angle of the guide rail 410 when actuated. For example, the guide
rail angle adjustment mechanism 446 may comprise a screw, pin, or
the like that when moved forward impinges upon a carrier 448 on
which the guide rail 410 is mounted. As seen in FIGS. 9A and 9B,
the guide rail angle adjustment mechanism 446 impinges upon the
carrier 448 near an end. The carrier further has a pivot point 450
near the center. Thus, when a force is placed upon the end of the
carrier 448, the carrier will rotate about the pivot point 450. The
pivot point 450 is aligned with a center point of the face
plate.
[0089] FIG. 9A shows an orientation in which the guide rail angle
adjustment mechanism 446 is at a fully engaged position. In this
position, the guide rail angle adjustment mechanism 446 has been
pushed to the point that an upper long edge 452 of the carrier 448
is nearly parallel to a lower long edge 454 of the bracket 402.
That is, in the orientation shown in FIG. 9A, the upper long edge
452 of the carrier 448 has a zero or substantially zero angle 411a
relative to the lower long edge 454 of the bracket. Because the
guide rail 410 is mounted on the carrier 448, the same can be said
of the upper long edge 456 and the lower long edge 458 of the guide
rail 410. That is, the upper long edge 456 and the lower long edge
458 of the guide rail 410 are each nearly parallel to the lower
long edge 454 of the bracket 402 such that there is a zero or
substantially zero angle 411a relative to the lower long edge 454
of the bracket 402.
[0090] FIG. 9B shows an orientation in which the guide rail angle
adjustment mechanism 446 is at a fully retreated position. In this
position, the guide rail angle adjustment mechanism 446 has been
pulled to the point that the upper long edge 452 of the carrier 448
has an angle 411b relative to the lower long edge 454 of the
bracket 402. That is, in the orientation shown in FIG. 9B, the
upper long edge 452 of the carrier 448 has a greater than zero
angle 411b relative to the lower long edge 454 of the bracket. For
example, the range of the angle 411b may be .+-.2 degrees depending
on the position of the guide rail angle adjustment mechanism.
Because the guide rail 410 is mounted on the carrier 448, the same
can be said of the upper long edge 456 and the lower long edge 458
of the guide rail 410. That is, the upper long edge 456 and the
lower long edge 458 of the guide rail 410 are each at a greater
than zero angle relative to the lower long edge 454 of the bracket
402. In this manner, the angle 411a, 411b of the guide rail 410 can
be adjusted by actuating the guide rail angle adjustment mechanism
446.
[0091] FIGS. 10A and 10B show a schematic representations of the
impact of the guide rail angle 411a, 411b on the position of the
vacuum apparatus 404 relative to the surface 135 of the faceplate
133. Because the vacuum apparatus 404 travels along the guide rail
410 via the tray 414, the vacuum apparatus 404 and the tray 414
will have a direction of travel 460a, 460b at an angle 413a, 413b
relative to the horizontal plane defined by the surface 135 of the
faceplate 133, depending on the guide rail angle 411a, 411b. FIG.
10A shows an orientation that corresponds to the guide rail angle
411a while FIG. 10B shows an orientation that corresponds to the
guide rail angle 411b. As seen in FIG. 10A, when the guide rail
angle 411a is zero or substantially zero, as the vacuum apparatus
404 travels in the direction of travel 460a underneath the
faceplate 133, the angle 413a is also zero or substantially zero.
That is, in this case, a distance in the Z dimension between the
faceplate 133 and the orifice 432 of the vacuum apparatus 404 is
nearly constant, and there is zero or near zero displacement long
the Z dimension. Rather, the displacement is nearly entirely in the
X dimension. If the angle 413a, 413b were precisely zero, there
would be no displacement in Z dimension and only displacement in X
dimension as the vacuum apparatus 404 travels across the faceplate
133. As seen in FIG. 1013, when the guide rail angle 411b is
greater than zero (and greater than angle 411a), as the vacuum
apparatus 404 travels in travel direction 460b underneath the
faceplate 133, the angle 413b is also greater than zero (and
greater than 413a). That is, in this case, a distance in the Z
dimension between the faceplate 133 and the orifice 432 of the
vacuum apparatus 404 is much larger at the first end 123 than at
the second end 125, and there is greater displacement along the Z
dimension than in FIG. 10A. While the displacement is still
primarily in the X dimension when the vacuum apparatus travels in
the direction of travel 460b, there is greater displacement in the
Z direction than in FIG. 10A. Therefore, controlling the guide rail
angle 411a, 411b in turn controls the angle 413a, 413b relative to
the horizontal plane defined by the surface 135 of the faceplate
133.
[0092] FIGS. 11A and 11B show end views of the cleaning system 400
with the bracket 402, guide rail 410, translating mechanism 412,
and corresponding structure omitted for clarity. As noted above,
the angle of the vacuum apparatus 404 relative to the faceplate 133
may be adjusted by tightening the securing mechanism 430. FIG. 11A
shows an orientation where the angle 417a of the vacuum apparatus
404 relative to the faceplate 133 is zero or substantially zero.
That is, in the orientation shown in FIG. 11A, the faceplate 133 is
substantially parallel to the orifice 431 of the vacuum apparatus
along the width 139. FIG. 11B shows an orientation where the angle
417b of the vacuum apparatus 404 relative to the faceplate 133 is
greater than zero. The particular angle of the vacuum apparatus 404
may be set by first loosening the securing mechanism 430. Once the
securing mechanism 430 is loosened, the vacuum apparatus 404 may be
rotated about the securing mechanism 430. Once the new angle has
been selected, the securing mechanism 430 may be tightened until
the mounting portion 428 is tightly held against the tray 412.
These steps can be repeated to readjust the angle of the vacuum
apparatus 404. The angle of the vacuum apparatus 404 can be
adjusted in this manner by .+-.15 degrees or less, by .+-.10
degrees or less, by .+-.5 degrees or less, or by .+-.1 degrees or
less. While FIG. 11B shows a clockwise rotation of the vacuum
apparatus 404 from the illustrated viewpoint relative to the
orientation in FIG. 11A, the vacuum apparatus 404 may also be
rotated in a counter-clockwise manner relative to the orientation
shown in FIG. 11A.
[0093] FIG. 12 shows an end view of the cleaning system 400 with
the bracket 402, guide rail 410, translating mechanism 412, and
corresponding structure omitted for clarity. In FIG. 12, a distance
462 between the surface 135 of the faceplate 133 and the orifice
432 of the vacuum apparatus 404 is increased as compared a distance
between the surface 135 of the faceplate 133 and the orifice 432 of
the vacuum apparatus 404 shown in FIG. 11A. The distance 462
between the surface 135 of the faceplate 133 and the orifice 432 of
the vacuum apparatus 404 may be adjusted in the same manner that
the angle of the vacuum apparatus is adjusted. That is, the
securing mechanism 430 may be first loosened to allow for movement
of the vacuum apparatus 404. Once the securing mechanism 430 is
loosened, the vacuum apparatus 404 may moved to increase or
decrease the distance 462. Once the new distance 462 has been
selected, the securing mechanism 430 may be tightened until the
mounting portion 428 is tightly held against the tray 412. These
steps can be repeated to readjust the distance 462. The distance
may be adjusted to be 0.5 mm.+-.0.2 mm. Notably, because the
orifice 432 is at a distance 462 from the faceplate 133, the vacuum
apparatus 404 will not come into contact with the faceplate
133.
Cleaning Method
[0094] With the above structure described, a method of cleaning the
surface 135 of the faceplate 133 with the structure will now be
described. The method may begin with a calibration method 500 to
calibrate the cleaning system 400 for the particular dispenser 122
being used in the overall system 100. The calibration method 500
may be considered part of the overall cleaning method in one
embodiment and may be considered a separate method from the
cleaning method in another embodiment. For example, the calibration
method 500 does not need to be performed with every cleaning of the
dispenser 122. Rather, the calibration method 500 is performed at
least one time prior to the first cleaning, and then can be
performed occasionally depending on certain conditions being met,
which is discussed below in more detail. Thus, the overall cleaning
method may or may not include the calibration method.
[0095] FIG. 13 shows a flowchart of the calibration method 500. The
calibration method 500 begins with step S502, where an initial
position of the vacuum apparatus 404 is set relative to the surface
135 of the faceplate 133, prior to any accumulation of formable
material on the faceplate 133. That is, the faceplate 133 does not
have any formable material on the surface 135 at the time of
performing the calibration method 500. The initial position of the
vacuum apparatus 404 includes the three factors set forth above. In
summary, these three factors are 1) the angle of the direction of
travel 460a, 460b of the vacuum apparatus 404 relative to the
horizontal plane defined by the surface 135 of the faceplate 133
(as controlled by the guide rail angle adjustment mechanism 446);
2) the angle 417a, 417b of the vacuum apparatus 404 relative to the
surface 135 of the faceplate 133, and 3) the distance 462 between
the surface 135 of the faceplate 133 and the vacuum orifice 432.
Each of these factors can be set in the manner described above. The
initial position may be arbitrarily selected or if previous data is
available from other calibrations, then the initial position may be
based on such data. Setting the initial position based on previous
data may reduce the number of iterations required to arrive at the
optimal final position as compared to arbitrarily selecting the
initial position.
[0096] The method may then proceed to step S504 where light data is
collected by the light emitter/sensor 406 at plurality of points
along the X dimension of the faceplate 133. In step S504, the light
emitter/sensor 406 travels along the length 127 of the faceplate
133 in the X dimension while emitting light across the surface 135
of the faceplate 133, and while simultaneously measuring the
intensity of the light that is reflected by the retroreflector 418.
The light emitter/sensor 406 may collect data starting at the first
flange 129 and continue to collect data while traveling in the X
dimension until reaching the second flange 131 via actuation by the
translating mechanism 412. During this time, the light
emitter/sensor 406 emits light and senses light at a predetermined
frequency. For example, the light emitter/sensor 406 may be preset
to take a light reading from 10 times per second to 30 times per
second, from 15 times per second to 25 times per second, or from 18
times per second to 22 times per second. In one example embodiment,
the measurement may be taken 20 times per second. The speed at
which the light emitter/sensor 406 travels may be for example 0.1,
1, or 10 mm/second. In one example embodiment, the speed may be 1
mm/sec. Both the frequency of measurements and the speed of travel
may be optimized to achieve sufficiently accurate data.
[0097] FIG. 14 shows an example chart 600 of data measurements
taken by the light emitter/sensor 406 during a complete passing
across the faceplate 133, with the chart 600 projected onto the
dispenser 122. As shown in FIG. 14, the x-axis of the chart
represents the particular location that the light emitter/sensor
406 is located in the X dimension. The far left on the x-axis
corresponds to the location at the first flange 129, while the far
right on the x-axis corresponds to the location at the second
flange 131. The data points in between correspond to the locations
along the faceplate 133 from the first end 123 to the second end
125. The particular location of the light emitter/sensor in the X
dimension may be determined from the position encoder. As shown in
FIG. 14, the y-axis of the chart represents the voltage measured by
the light emitter/sensor 406 at the particular x-axis location. The
data recorded by a light sensor is voltage but may also be a
current (mA), a calibrated scaled distance (mm) (as discussed below
in more detail), a percent, etc. When greater light intensity is
measured, the voltage reported is greater. When less light
intensity is measured, the voltage reported is lower. In the
example shown in FIG. 14, a first portion of data 602 corresponds
to the voltages recorded as the light emitter/sensor 406 passes
across the first flange 129. The voltage is relatively much higher
at this point because the beam of light mostly passes underneath
the first flange 129. That is, there is less or nothing to block
the light being emitted by the light emitter/sensor 406 at this
location. A second portion of data 604 corresponds to the voltages
recorded after the light emitter/sensor 406 has finished passing
across the first flange 129 and travels all the way across the
faceplate 133 until reaching the second flange 131. The leftmost
end 606 of the second portion of data 604 corresponds to the
location of the light emitter/sensor 406 being at the first end
123. The rightmost end 608 of the second portion of data 604
corresponds to the location of the light emitter/sensor 406 being
at the second end 125. The voltage is much lower in the second
portion 604 than the first portion 602 because the light is being
partially blocked by the dispenser and faceplate. A third portion
of data 610 corresponds to the voltages recorded as the light
emitter/sensor 406 passes across the second flange 131. As with the
first flange 129, the voltage is relatively much higher at this
point because the beam of light mostly passes underneath the second
flange 131. The variation in voltages recorded within the second
portion of data 604 directly correlates to the height of the
faceplate 133 in the Z dimension at each location along the X
dimension because the greater the height in the Z dimension, the
more light is blocked from being sensed.
[0098] The method may then proceed to step S506 where the position
of the vacuum apparatus 404 is changed relative to the surface 135
of the faceplate 133 by changing one of a) the angle 417a, 417b of
the vacuum apparatus 404 relative to the surface 135 of the
faceplate 133, b) the distance 462 between the vacuum apparatus 404
and the faceplate 133, or c) the angle of direction of travel 460a,
460b of the vacuum apparatus 404 relative to the surface 135 of the
faceplate 133. That is, in step S506 one, and only one, of the
above-described factors that define the position of the vacuum
apparatus 404 are changed, while the other two factors are held
constant. In one example embodiment, either factor a) or factor b)
is selected as the first factor to change. The magnitude of the
change for the two angle factors may be in the range of
.+-.2.degree.. The magnitude of change for the distance 462 may be
in the range of 1 mm to 2 mm.
[0099] After changing the position of one of the position factors,
the method may proceed to step S508, where additional light data at
a plurality of points along the X-dimension of the faceplate 133
are collected. In particular, the same data collection step noted
above with respect to step S504 is repeated. That is, once again
the light emitter/sensor 406 will pass across the dispenser 122 and
faceplate 133 in the X dimension while measuring light intensity at
the same rate as the first data collection. Thus, a new chart
similar to the example shown in FIG. 14 will be generated. However,
the chart will be different because of the change in the position
factor. In the case of changing either a) the angle 417a, 417b of
the vacuum apparatus 404 relative to the surface 135 of the
faceplate 133 or b) the distance 462 between the vacuum apparatus
404 and the faceplate 133, the new chart will, as a whole move
either up or down along the y-axis as compared to the original
chart. In particular, the second portion 604 will be higher or
lower on the y-axis. This is because when the angle or the distance
is not optimized less reflected light is sensed and therefore the
voltage reading is lower. However, when the angle or the distance
is optimal, a maximum reflectance is achieved. Thus, one can
determine if the change in the position factor was better or worse
than the previous setting by seeing if the data points move upward
or downward on the y-axis. If the data points move upward on the
y-axis, then the new position is closer to optimal. If the data
points move downward, then the new position is less optimal.
[0100] With the above principle in mind, the method may then
proceed to step S510, where it is determined whether optimized
light measurements are being captured. As noted above, in the case
of changing either a) the angle of the vacuum apparatus relative to
the surface of the faceplate or b) the distance between the vacuum
apparatus and the faceplate, then this determination is made based
on whether second portion 604 data has moved upward or downward on
the y-axis as compared to the previous measurement. If the data has
moved downward, then the answer in step S510 is certainly "no."
However, even if the data has moved upward, the answer in step S510
is still "uncertain." This is because a further adjustment may move
the data points upwards even further than the first adjustment. The
answer in step S510 is not "yes" until the adjustment stops causing
the data to move up on the y-axis and instead the data moves back
down on the y-axis. In other words, the answer to step S510 can
only be "yes" if a series of iterative adjustment and data
collections shows the data moving downward on the y-axis
immediately after an adjustment shows the data going up on the
y-axis. At that point, the user knows that the setting just prior
to the downward movement of data was the optimal setting. Thus, as
long as the answer is "no" or "uncertain" in step S510, the steps
of S506 through S510 are repeated, except that in step S506 it
should be understood that the same position factor is adjusted
during each iteration until reaching the optimal position or that
factor. That is, the other two factors should remain unadjusted at
constant positions until the factor correctly being iteratively
adjusted has been optimized.
[0101] While the above steps of comparing the upward and downward
movement of data with adjustment applies to a) the angle of the
vacuum apparatus 404 relative to the surface 135 of the faceplate
133 and b) the distance 462 between the vacuum apparatus 404 and
the faceplate 133, the same approach does not apply to when the
factor being adjusted is c) the angle of direction of travel of the
vacuum apparatus. In the case of adjusting c) the angle 413a, 413b
of direction of travel 460a, 460b of the vacuum apparatus 404, the
iterative process of comparing data is different. In this case,
rather than looking at the data moving upward or downward on the
y-axis, the comparison between data collections is used to
determine what adjustment provides the flattest data spread in the
second portion 604. For example, if the data shown in FIG. 14 is
the first data collected when the angle 413a, 413b of direction of
travel 460a, 460b of the vacuum apparatus 404 is at the initial
position, a linear best fit line can be generated using the data
points in the second portion 604. The slope of the generated line
would be the initial value to be compared to subsequent iterations.
After adjusting the angle 413a, 413b of direction of travel 460a,
460b of the vacuum apparatus 404, the data collection would be
repeated using the light emitter/sensor 406. The new linear best
fit line is generated for the second portion 604 of the new data,
having a new slope. Then, the slopes can be compared. If the new
slope is farther from zero (i.e., flat) than the initial slope,
then the answer to step S510 is "no." If the new slope is closer to
zero than the initial slope, then as above, the answer to S510 is
"uncertain." As with the other two factors, this is because a
further adjustment may provide a slope that is even closer to zero.
The answer in step S510 is not "yes" until the adjustment stops
causing the slope to get closer to zero and instead slope moves
back farther from zero. In other words, as above, the answer to
step S510 becomes "yes" when a series of iterative adjustment and
data collections shows the slope of the linear best fit line in the
second portion 604 going farther from zero immediately after an
adjustment shows the slope of the linear best fit line in the
second portion 604 going closer from zero. At that point, the user
knows that the setting just prior to the slope moving farther from
zero was the optimal setting. Thus, the same iterative process of
repeating steps S504 to S510 is applicable to all three position
factors.
[0102] After it is determined in step S510 that the first position
factor has been optimized, the method may then proceed to step
S512, where the same steps of S506 to S510 are repeated for the
other two position factors. In particular, after the first factor
has been optimized, it should remain fixed at the optimized
position. For example, if a) the angle 417a, 417b of the vacuum
apparatus 404 relative to the surface 135 of the faceplate 133 was
the first position factor to be optimized, then this angle would no
longer be adjusted throughout the remaining calibration process.
The iterative optimization process would be performed for the one
of the two remaining factors. After the second position factor is
optimized, then the iterative optimization process is performed for
the final remaining position factor, while keeping the first two
position factors fixed at their optimized positions. Notably, the
vacuum apparatus 404 is not actuated during any of the calibration
steps.
[0103] In one example embodiment, the angle 417a, 417b of the
vacuum apparatus 404 relative to the surface 135 of the faceplate
133 is optimized first. The adjustment may be performed by
loosening the adjustment mechanism 430, repositioning the nozzle
apparatus 404, then tightening the adjustment mechanism 430. The
light data may then be collected as described above. After
collecting the light data, the adjustment mechanism 430 may be
loosened, and the angle 417a, 417b of the nozzle apparatus 404
relative to the surface 135 of the faceplate 133 may be adjusted.
The light data may be collected for the new position. The
repositioning and measurements may be repeated as described above
until the optimum angle 417a, 417b has been achieved. Next, the
distance 462 between the vacuum apparatus 404 and faceplate 133 may
adjusted by loosening the adjustment mechanism 430 and
repositioning the vacuum apparatus 404 to a different distance
while maintaining the angle 417a, 417b. The light data may be
collected in this new position. The repositioning of the distance
and measurements may be repeated as described above until the
optimal distance has been achieved. Finally, the angle 413a, 413b
of the direction of travel 460a, 460b of the vacuum apparatus 404
may be adjusted by actuating the guide rail angle adjustment
mechanism 446. The light data may be collected in this new
position. The repositioning of the angle 413a, 413b of the
direction of travel 460a, 460b and measurements may be repeated as
described above until the optimal angle 413a, 413b of the direction
of travel 460a, 460b has been achieved. As noted above, any order
of optimization is suitable, but preferably the angle of direction
of travel optimization is performed last to avoid accidental
collision of the vacuum apparatus 404 with the faceplate 135.
[0104] After all three position factors have been optimized, the
method may proceed to step S514, where baseline data is generated.
The baseline data is essentially the same as FIG. 14, only that the
light data is the data that is acquired after all three of the
position factors have been optimized. In other words, the baseline
data is a representation of the expected light measurements for a
particular dispenser, with no accumulated formable material on the
faceplate, after the all three of the position factors have been
set to their optimal positions. The baseline data is thus
information about the relative height of the surface of the
faceplate at particular locations along the X dimension in terms of
voltage. The baseline data also provides information about the
location in the X dimension of the first end 123 and second end 125
of the faceplate 133 based on the spike in voltage readings that
occur at the first portion of data 602 that corresponds to the
first flange 129 and the spike in voltage that occurs at the second
portion of data 610 that corresponds to the second flange 131. That
is, the location along the x-axis of the baseline chart where the
left data spike transitions into the second portion of data 604
indicates the first end 123 of the faceplate. Similarly, the
location along the x-axis of the baseline chart where the second
portion of data 604 transitions into the right data spike indicates
the second end 125 of the faceplate 133. The data shown in FIG. 14
can be considered as an example of baseline data if it is assumed
that FIG. 14 has been acquired after the optimization steps
discussed above have been completed. After generating the baseline
data in step S514, the calibration method is complete.
[0105] FIGS. 15A to 15C show several views of the dispenser 122
after formable material 124 has accumulated on the surface 135 of
the faceplate 133. As shown schematically in FIG. 15A to 15C the
accumulated formable material 124 may be located at various
patterns and thickness across the surface 135 of the faceplate 133.
FIGS. 15A and 15B show the dispenser 122 with all other components
of the cleaning system 400 omitted for clarity. FIG. 15C shows an
underside perspective view of the dispenser 122 with accumulated
formable material 124, with the vacuum apparatus 404 and the light
emitter/sensor 406. The structure of the cleaning system 400 and
the dispenser 122 are the same as discussed above, the only
difference being that formable material 124 has accumulated on the
surface 135 of the faceplate 133 after the dispenser 122 has
dispensed formable material 124 many times. Thus, as discussed
above, the light emitted from the light emitter/sensor 404 travels
across the width 139 of the faceplate 133 and the orifice 432 of
the vacuum apparatus 404 also extends across the width 139 of the
faceplate 133.
[0106] FIG. 16 shows a flowchart of a cleaning method 700 that may
be performed after the calibration method 500 has been completed.
The method begins at step S702 where light readings are collected
at a plurality of points along the X dimension of the dispenser.
However, as noted above, the calibration method 500 can also be
considered to be part of the overall cleaning method and would
occur prior to step S702 of the cleaning method 700 in such an
embodiment. Step S702 is performed in the same manner as discussed
above in the calibration method and the light data are generally
collected at the same points along the X dimension. That is, step
S702 is essentially the same as step S504 in calibration method
500. Accordingly, in step S702, the light emitter/sensor 406
travels across the length 127 of the faceplate 133 in the X
dimension while emitting light across with the width 139 of the
faceplate 133 in the Y dimension and sensing reflected light. The
result of the data collection in step S702 generates a chart
similar to the chart shown in FIG. 14, except that the voltages
representing the intensities of the light received will vary more
greatly depending on the amount of formable material 124
accumulated on the surface 135 of the faceplate 133.
[0107] FIG. 17 shows an example of a data chart 800 of voltages
representing light intensity from voltage data collected by the
light emitter/sensor 406 when formable material 124 has accumulated
on the surface 135 of the faceplate 133. As seen in FIG. 17, the
chart includes an overall similar shape to the chart 600 in FIG.
14. The chart 800 similarly includes a first portion of data 802 on
the left side before a first data spike 804, which transitions to a
second portion of data 806. The second portion of data 806 leads
into a second data spike 808 which transitions into a third portion
of data 810. Similar to chart 600, in the chart 800 the transition
from the first data spike 802 to the second portion 806 represent
the light emitter/sensor 406 moving from the first flange 129 to
the faceplate 133. Likewise, the transition from the second portion
806 to the second data spike 808 represents the light
emitter/sensor 406 moving from the faceplate 133 to the second
flange 131. As seen in FIG. 17, there are several peaks 812 and
valleys 814 along the second portion of the data 806 that
corresponds to locations at the surface of the faceplate. The peaks
correspond to locations on the surface of the faceplate where the
formable material has accumulated because the accumulated formable
material blocks more of the emitted light than locations with less
or no formable material. That is, chart 800 is similar to chart 600
with respect to having the same general sections of data, but is
different in that there are more peaks in the second portion 806 of
chart 800 than the second portion 604 of chart 600 because there no
accumulated formable material in chart 600.
[0108] The method may then proceed to step S704, where it is
determined whether cleaning is necessary by comparing the data
collected in step S702 with the baseline data acquired in step
S514. As discussed above, the baseline data acquired in step S514,
shown in FIG. 14, corresponds to the height of the surface 135 of
the faceplate 133 across the entire length of the faceplate
relative to a base plane. On the other hand, the data collected in
step S702, shown in FIG. 17, corresponds to the height when
formable material has accumulated on the surface 135 of the
faceplate 133. Accordingly, by comparing the data collected in step
S702 with the baseline data, it can be determined whether there is
too much accumulated formable material at any particular point
along the X dimension. For example, for a particular point on the
x-axis of FIG. 17, if the difference between the light data
collected at the same point on the x-axis of FIG. 14 is greater
than a predetermined threshold value, it can be concluded that too
much formable material has accumulated on the faceplate. In other
words, because the same x-axis location on the two charts 600, 700
correspond to the same X dimension location along the faceplate
133, if the light intensity measured at that same point is much
lower than in the baseline, it is apparent that formable material
has accumulated at this location. In one example embodiment if the
difference in voltage between the value measured in step S702 and
the value measured in the baseline data is between 50 mV and 75 mV,
which is equivalent to 100 .mu.m to 150 .mu.m height relative to
the base plane, then the determination in Step 704 is "yes." In
another embodiment, a certain number of points on the x-axis may
have to exceed the above value before the answer is "yes" in step
S704. For example two, three, four, or more points exceeding the
threshold may can be considered to be satisfactory for needing
cleaning. If the above thresholds are not met, then the answer to
step S704 is "no."
[0109] If the answer is "no" in step S704, then the method returns
back to step S702 after a predetermined number of further dispenses
by the dispenser is performed or after a predetermined amount of
time has passed. The predetermined amount of dispenses or
predetermined amount of time may be based on previously collected
prediction data or based on how similar the data collected in step
S702 is to the baseline data. For example, in one embodiment,
regardless of how the data collected in step S702 compares to the
baseline data, the step S702 may be repeated after every 1 to 3
million drops are dispensed, after approximately 1 .mu.L of drops
are dispensed, or after 12 to 48 hours of dispensing drops based on
historical estimates of how fast formable material accumulates. In
another embodiment, if it is determined that the data collected in
step S702 is very close to the baseline data, then more dispenses
or more time may be used before repeating step S702. On the other
hand, if it is determined that the data collected in step S702 is
far from the baseline data and close to exceeding the thresholds
for cleaning, then less dispenses or less time may be used before
repeating step S702. How close or far the data collected in step
S702 is to the baseline data can be determined as an average
deviation across all x-axis points, for example.
[0110] If the answer is "yes" in steps S704, i.e., it is determined
that cleaning is necessary, then the method proceeds to step S706
where the vacuum apparatus 404 is used to clean the surface 135 of
the faceplate 133, while simultaneously collected light data. As
discussed above, the light emitter/dispenser 406 and the vacuum
apparatus 404 are mounted to the tray 414 such that when the
translation mechanism 412 actuates, the tray 412, the light
emitter/dispenser 406, and the vacuum apparatus 404 all translate
together across the surface 135 of the faceplate 133 in the X
dimension. As also discussed above, light emitter/sensor 406 is
positioned so that the emitted light travels across the orifice 432
of the vacuum apparatus 404, with both the orifice 432 and the
emitted light 408 extending across the width 139 at the same
position on the X dimension. For this reason, it is possible to
both actuate the vacuum to suction formable material 124 off the
surface 135 of the faceplate 133 and simultaneously measure light
intensity at the same X dimension position. Accordingly, in step
S706, the nozzle apparatus 404 travels along the X dimension at a
distance 462 from the surface 135 of the faceplate 133 while
sucking formable material 124 into the orifice 432, and at the same
time the light emitter/sensor 406 is recording data at the same X
dimension points as the previous data collections.
[0111] In one example embodiment, the pressure applied to the
vacuum apparatus 404 may be constant from the first end 123 of the
faceplate up until reaching a point along the X dimension located
near the second end 125 of the faceplate. At this point, the vacuum
may be greatly increased. The point along the X dimension from the
first end 123 where the vacuum is increased may be from 80% the
length of the faceplate to about 99% the length of the faceplate or
from about 88% the length of the faceplate to about 98% the length
of the faceplate. In an example embodiment, the point along the X
dimension from the first end 123 where the vacuum is increased
includes the region 141 (FIG. 7) of the faceplate that does not
include nozzles 137. That is, as shown in FIG. 7, there is a region
141 where no nozzles are present and it is at this point where the
vacuum is increased. In another example embodiment, the point along
the X dimension from the first end 123 where the vacuum is
increased includes a region of the faceplate in which there are
some nozzles 137 present, but in such a case those nozzles are not
used to dispense drops of formable material when performing step
S302. In other words, in some dispensing processes, some of the
nozzles near the first and/or second ends 123, 125 are not used to
dispense formable material. For example, the first 1 to 10 nozzles
on the first end 123 and the final 1 to 10 nozzles on the second
end 125 may not be used to dispense formable material during
operation. Accordingly, the increase in vacuum may occur at the
position along the X dimension where the first non-used nozzle are
located adjacent the second end 125. It should also be understood
that in another example embodiment, the vacuum may begin suction on
the second end 125 and the increase in pressure may occur near the
first end 123. The increase in the vacuum pressure may be from 25%
higher to 100% higher, from 33% higher to 80% higher, or from 50%
to 66% higher. The increase in vacuum pressure may be then held at
the increased amount until reaching the second end 125 of the
faceplate 133. The benefit of increases in the vacuum pressure
toward the second end 125 of the faceplate 133 is that the sudden
increase assists in suctioning away formable material 124 that has
been displaced during the vacuuming that has occurred up until this
point in the X dimension. That is, during the period where the
initial vacuum pressure is set, as the vacuum apparatus 404 travels
across the faceplate 133 in the X dimension, some of the formable
material 124 will be sucked up, while some will be displaced in a
direction toward to the second end 125 of the faceplate 133. While
some of the displaced formable material 124 may be suctioned as the
vacuum apparatus 404 continues to travel in the X dimension, other
amounts will continue to displace in the direction of the second
end 125 of the faceplate 133. The sudden increase in vacuum
pressure near the second end 125 of the faceplate 133 assists in
suctioning off the final amount of displaced formable material
124.
[0112] FIG. 18 shows an example of a chart 900 with data
representing light intensity collected by the light emitter/sensor
406 when the vacuum apparatus 404 is actuated to suction formable
material 124 from the surface 135 of the faceplate 133. As seen in
FIG. 18, the chart 900 includes an overall similar shape to the
chart in FIGS. 14 and 17. The chart 900 similarly includes a first
portion of data 902 on the left side before a data spike 904, which
transitions to a second portion of data 906. The second portion of
data 906 leads into another data spike 908 which transitions into a
third portion of data 910. Similar to chart 600, in the chart 900
the transition from the first data spike 902 to the second portion
906 represent the light emitter/sensor 406 moving from the first
flange 129 to the faceplate 133. Likewise, the transition from the
second portion 906 to the second data spike 908 represents the
light emitter/sensor 406 moving from the faceplate 133 to the
second flange 131. As seen in FIG. 18, there are several peaks 912
and valleys 914 along the second portion of the data 806 that
corresponds to locations at the surface of the faceplate. However,
the peaks 912 and valleys 914 in the chart 900 have higher
magnitudes than the peaks 812 and valleys 814 than in the chart
800. This is because, during the physical act of sucking formable
material 124 into the orifice 432, the formable material being
pulled down blocks light from being sensed by the light
emitter/sensor 406. Thus, the presence of larger peaks 912 and
valleys 914 in the chart 900 as compared to the chart 800,
indicates that formable material 124 is being suctioned off from
the surface 135 of the faceplate 133. Furthermore, the location on
the x-axis of the peaks 912 and valleys 914 of chart 900 are
expected to somewhat coincide with the location on the x-axis of
the peaks 812 and valleys 814 of chart 800. This is because if the
chart 800 indicates via a valley 814 that there is formable
material present, then the corresponding valley 914 should be
caused by sucking up that same formable material.
[0113] With the data obtained in step S706, the method may then
proceed to step S708 where it is determined whether the vacuum
apparatus 404 is in the proper position relative to the faceplate
133. It is possible that over time, the position of the vacuum
apparatus 404 set during the calibration method 500 is no longer in
the same position relative to the faceplate 133. That is, one, two,
or all of the position factors discussed above may no longer be in
the original setting due to mechanical shifting of the various
components within the overall system that may cause movement of the
vacuum apparatus 404 or movement of the dispenser 122 to no longer
be positioned at the initially set relative position. Indeed, it is
inevitable that after many operation cycles, the position of the
vacuum apparatus 404 relative to the dispenser 122 will be
shifted.
[0114] The data obtained during step S706 can be compared to the
baseline data acquired in the calibration method 500 to determine
whether such a shifting has occurred. More particularly, bridging
events may be identified in which a maximum amount of light is
blocked while the vacuum is on. A bridging event is when formable
material 124 from the faceplate 133 bridges the gap 462 between the
vacuum apparatus 404 while the vacuum is on. At least one bridging
event should occur when the vacuum apparatus 404 is optimally
positioned relative to the faceplate 133. If no bridging event
occurs, then drifting may have occurred such that the vacuum
apparatus 404 is no longer optimally positioned relative to the
faceplate 133. If the bridging event lasts too long, for example
for the entire period that the vacuum is over the nozzles 137 of
the faceplate 133, then drifting may have occurred such that the
vacuum apparatus 404 is no longer optimally positioned relative to
the faceplate 133.
[0115] The determination in step S708 can also be based on
comparing the data collected after the cleaning operation has been
completed with the baseline data. This same comparison is discussed
below with respect to FIG. 19. Thus, step S708 may also include an
additional step of acquiring light data after the vacuum has been
completed to generate the data shown in FIG. 19 and comparing that
data to the baseline data in the manner described below. This
comparison can be used in addition to the comparison of the data
acquired during the vacuuming with the baseline data. If one or
both of these instances are occurring, it is an indication that
drifting may have occurred. In other words, data showing that the
faceplate has not been adequately cleaned is also useful
information in determining whether the position of the vacuum
apparatus relative to the faceplate is no longer optimal.
[0116] If it is determined in step S708 that the vacuum apparatus
404 is no longer in the proper position relative to the faceplate
133, i.e., the answer is "no", then the method proceeds to step
S710. In step S710, the calibration method 500 is performed again
to optimize the position of the vacuum apparatus 404 relative to
the faceplate 133. Prior to performing the calibration method 500,
the surface 135 of the faceplate 133 should be completely cleaned
for the calibration method to be accurate. Thus, prior to
performing the calibration method 500, a separate cleaning step may
be performed such as manually wiping the surface 135 of the
faceplate 133.
[0117] If it is determined in step S708 that the position of the
vacuum apparatus 404 relative to the dispenser 122 is still proper,
then the method proceeds to step S712, where it is determined
whether the end points 123, 125 of the faceplate are being detected
at the proper location. Step S712 can be performed by comparing the
data obtained in step S706 to the baseline data acquired in the
calibration method 500 to determine whether the endpoints 123, 125
of the faceplate are being detected at the proper location. More
particularly, as discussed above, the data acquired during the
calibration method 500 shows the position of the endpoints 123, 125
of the faceplate in the X dimension because there is a sudden spike
in the sensed light when the light emitter/sensor 406 reaches the
first flange 129 and the second flange 131 on either end of the
faceplate 133. The point along the X dimension that these spikes
occur in the baseline data indicates where the location of the
endpoints 123, 125 of the faceplate are expected to be located. As
discussed above, the data acquired in step S708, shown in FIG. 18,
also includes data spikes 904, 908 representing the location of the
endpoints 123, 125 of the faceplate 133. If the location of the
data spikes 904, 908 of FIG. 18 do not match the same x-axis
position of the data spikes 804, 808 of FIG. 17, then the end
points 123, 125 of the faceplate 133 are not being detected at the
correct location. The endpoints 123, 125 may be considered not
matching if there is a deviation of greater than a threshold such
as: 0.1 mm; 1 mm; 5 mm; or 10 mm or a deviation on the order of
1-6% of the length 127 of the faceplate 133. If the endpoints 123,
125 are of the faceplate 133 according the data collected in step
S706 are not where they are expected to be, then this means that
vacuum pressure is not being applied at the proper location along
the X dimension. This is particularly important for the sudden
increase in vacuum pressure, which, as discussed above, is
controlled to occur at a particular location along the X dimension
of the faceplate 133. In other words, if the endpoints 123, 125 of
the faceplate are not being detected in the expected location along
the X dimension, then the vacuum pressure increase is going to be
applied too early or too late. Similarly, the vacuum pressure may
turn on or stop too early or too late. Thus, when the answer to
step S712 is "no," then the method also proceeds to step S170 where
the calibration method 500 is performed again. As above, prior to
performing the calibration method 500, the faceplate 133 will need
to be completely removed of formable material 124, such as by
manual cleaning.
[0118] If it is determined in step S712 that the answer is "yes,"
i.e., that the endpoints 123, 125 of the faceplate 133 are being
detected in the proper position, then the method proceeds to step
S714 where it is determined whether the vacuuming of the formable
material 124 has been successful. Step S714 can be performed by
observing the data for periodic data peaks that are higher than the
peaks shown in the data collected in step S702. When the vacuuming
of the formable material 124 is successfully occurring, there is an
expectation that there would be sharp peaks of higher magnitude
than the peaks in the data collected in step S702. That is, the
bridging event described above also informs whether the vacuuming
of the formable material has been successful. When formable
material is successfully being pulled off the faceplate, more light
is blocked. The data acquired in step S706 (FIG. 18) can be
compared to the data collected in step S702 (FIG. 17) in this step.
If the data in FIG. 18 does not show any bridging events or the
data in FIG. 18 indicates there are no breaks in the fluid being
pulled off the surface of the faceplate, but it is also known that
the faceplate does have formable material on the surface from the
data in FIG. 17, then it means the vacuum is not working and/or the
cleaning is malfunctioning and damaging the faceplate.
[0119] While FIG. 16 shows the order of steps to be first step
S708, followed by step S712, and lastly step S714, it should be
understood that these steps can be performed in any order. In any
case, if the answer is "no" to any one of these steps, the method
proceeds to step S710. When the answer is "yes" to all three steps
the method proceeds to back to step S702. In the case that the
calibration step S710 is indeed performed, after completing the
calibration, the method 700 would then be performed from the
beginning after the same amount of time and/or number of dispenses
as described above has passed.
[0120] Returning to step S702, a plurality of light data are
collected at the same plurality of points as in the previous steps
along the X dimension of the faceplate 133. FIG. 19 shows an
example of a chart 1000 representing light intensity data collected
at step S702 by the light emitter/sensor 406 after the completion
of step S714. As seen in FIG. 19, the chart 1000 includes an
overall similar shape to the chart in FIGS. 14, 17, and 18. The
chart 1000 similarly includes a first portion of data 1002 on the
left side before a data spike 1004, which transitions to a second
portion of data 1006. The second portion of data 1006 leads into
another data spike 1008 which transitions into a third portion of
data 1010. Similar to chart 600, in the chart 1000 the transition
from the first data spike 1002 to the second portion 1006 represent
the light emitter/sensor 406 moving from the first flange 129 to
the faceplate 133. Likewise, the transition from the second portion
1006 to the second data spike 1008 represents the light
emitter/sensor 406 moving from the faceplate 133 to the second
flange 131. As seen in FIG. 14, there are several peaks 1012 and
valleys 1014 along the second portion of the data 1006 that
corresponds to locations at the surface 135 of the faceplate 133.
Because the data in chart 1000 is acquired after the vacuum suction
step S706 has occurred, the chart 1000 can be compared to the chart
600 to see how well the surface 135 of the faceplate 133 has been
cleaned using the vacuum apparatus 404. That is, if all of the
formable material 124 has been suctioned off of the surface 135 of
the faceplate 133, the chart 1000 should be nearly identical to the
chart 600. This is because, as discussed above, the data of chart
600 is collected using a faceplate 133 with no formable material
124 present on the surface 135. Thus, the chart 600 and the chart
1000 can be compared in step S704. That is, the method 700 may then
repeat all of steps S704 through S714.
[0121] If the data collected in FIG. 19 does not closely match the
baseline data, then it can be determined that the cleaning was not
successful. Specifically, if the chart in FIG. 19 has been shifted
upwardly or downwardly too greatly in the y-axis relative to the
baseline data (FIG. 14), or if the slope of the best fit linear
line fitted to the FIG. 19 data is much larger than the slope of
the best fit linear line fitted to the FIG. 14 data, then the
cleaning was not successful. Anything less than 25 mV shift in the
y-axis, which corresponds to less than 50 .mu.m, may be considered
an acceptable deviation. With respect to the slope of the best fit
linear line, a difference in slope of less than 10 my/9 mm
(corresponding to 200 .mu.m/9 mm slope) may be considered an
acceptable deviation. Another option is to subtract the baseline
data from the data collected after cleaning and fitting a best fit
linear line to the subtracted data. If the slope of the subtracted
data is less than 10 my/9 mm (corresponding to 200 .mu.m/9 mm
slope), than it may be considered an acceptable deviation. Outside
of any of these ranges, the cleaning process may be considered to
have been unsuccessful. As noted above, this comparison can also be
used to determine whether the vacuum apparatus is no longer
positioned properly relative to the faceplate.
[0122] As discussed above, the data acquired by the light
emitter/sensor 406 is in units of voltage. However, it is also
possible to correlate the voltage reported by the light
emitter/sensor 404 with heights relative a surface plane. This can
be done by first obtaining a dummy head having the same dimension
of the dispenser, the dummy head having a flat surface
corresponding to the surface of the faceplate in the actual
dispenser head. A plurality of shims, each having a known thickness
can be placed spaced part on the flat surface of the dummy head.
For example, five shims can be placed on the flat surface of the
dummy head in a row along the X dimension, where the first shim has
a thickness of 500 microns, the second shim has a thickness of 300
microns, the third shim has a thickness of 200 microns, the fourth
shim has a thickness of 100 microns, and the fifth shim has a
thickness of 50 microns. Each shim may be generally rectangular in
shape with the short side extending in the X dimension and the long
side extending in the Y dimension. The short side may be about 1/6
the length 127 of the faceplate and the long side may be about 3/4
the width 139 of the faceplate. The shims may be centered with
respect to the Y dimension and spaced apart in the X dimension,
with the same interval of space being present between adjacent shim
in the X dimension. The reference plane would be the flat surface
of the dummy head, on which the shims are placed. The same light
data collection process described above can be performed where the
dispenser is replaced with the dummy head having the shims. The
light emitter/sensor 406 will record voltage data points as it
passes along the short side of each shim. The known height on one
axis can be plotted against the corresponding voltages on the other
axis. Then, a linear best-fit line can be fitted to the data
points. This resulting linear equation creates a function where
height is a function of voltage. That is, the voltage reported by
the light emitter/sensor 406 can be entered into the equation and
the outputted value would be the corresponding height. In this
manner, the voltage reported by the light emitter/sensor 406 can be
correlated to height relative to the reference plane.
[0123] To determine the specific height of accumulated formable
material, the heights correlating to the baseline data acquired at
step S514 (i.e., chart 600) can be subtracted from the heights
correlating to the data acquired during step S702 (i.e., chart
800). The result of the subtraction would be the height of the
accumulated formable material on the surface of the faceplate prior
to applying the vacuum cleaning. The height data can also be
approximately correlated to amount of formable material on the
faceplate based upon material properties of the faceplate; and
material properties of the formable material including surface
tension of the formable material on the faceplate. By the same
procedure, the height of the formable material on the faceplate
after the vacuum cleaning step S506 (i.e., chart 1000) can be
determined. This too, can be correlated to amount of formable
material. Therefore, another manner of determining whether the
vacuum cleaning is successful is to subtract the amount of formable
material calculated from the post vacuum clean data (i.e., chart
10000) from the pre-clean data (i.e., chart 800). This subtraction
would represent how much formable material was suctioned off of the
faceplate. If it is determined that not enough formable material
has been removed, then a change in vacuum pressure can be
implemented, for example, in a future vacuum cleaning. The
determination may be made by comparing the subtracted data to data
sets that are known to represent successful cleaning.
[0124] As described above, the nanoimprint lithography system 100
may be regulated, controlled, and/or directed by the one or more
processors 140 (controller). This includes all of the method steps
described above, including controlling the hardware that changes
all three position factors that impact the position of the vacuum
apparatus 404 relative to the faceplate 135, controlling the
translation mechanism 412 to control the movement of the vacuum
apparatus 404 and light emitter/sensor 406, controlling when the
vacuum pressure is applied and at what pressure, controlling the
light emitter/sensor 406 to collect light data, and performing the
determining steps by analyzing the acquired voltage data and making
the necessary calculations. While not shown in the figures, it
should be understood that any of the mechanical adjustments (i.e.,
adjusting the angle of guide rail to impact angle of approach, the
angle of the vacuum apparatus relative to the faceplate, and the
distance between the vacuum apparatus and the faceplate) can be
controlled by the controller via a motor or other known automation
means.
[0125] Further modifications and alternative embodiments of various
aspects will be apparent to those skilled in the art in view of
this description. Accordingly, this description is to be construed
as illustrative only. It is to be understood that the forms shown
and described herein are to be taken as examples of embodiments.
Elements and materials may be substituted for those illustrated and
described herein, parts and processes may be reversed, and certain
features may be utilized independently, all as would be apparent to
one skilled in the art after having the benefit of this
description.
* * * * *