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Description  |
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FIELD OF THE INVENTION
The present invention relates to noncontact fluid printing devices
conventionally known as "ink jet" or "fluid jet" printers and, more
particularly, to a method for ultrasonically cleaning solid particles,
dried ink or other contaminants from the fluid supply system, print head
and orifice plate through which the ink jet droplets emerge.
BACKGROUND AND SUMMARY OF THE INVENTION
Noncontact printers which utilize droplets emitted from an orifice plate
are generally known in the art as shown by U.S. Pat. Nos. 3,373,437 to
Sweet et al; 3,560,988 to Crick; 3,579,721 to Kaltenbach; and 3,596,275 to
Sweet. Typically, fluid filaments of ink, dye or the like (hereinafter
"fluid") pass through the orifices of an orifice plate, and a first array
of individually controllable electrostatic charging electrodes are
disposed downstream of the orifice plate along a "droplet formation zone"
to selectively charge droplets of the fluid. The droplets subsequently
pass through an electrostatic field which deflects the charged ones of the
droplets from the normal path towards a droplet catcher. Uncharged
droplets proceed along a normal path and are deposited upon a receiving
substrate.
Typically, noncontact ink jet or "fluid jet" printers use a solvent-based
ink or dye medium which contains water as the principal component. Many of
the dye compositions used in fluid jet printing operations are formed by
dissolving a solid dye material in the aqueous solvent medium. In other
compositions, the fluid is comprised of a dispersion of fine particles in
a liquid, such as disperse dyes commonly used in dyeing textiles.
Typically, the ink supply system for the printer includes a fluid
reservoir or supply chamber disposed above the orifice plate which
connects to a fluid manifold assembly. The manifold distributes an even
flow of printing fluid across the linear array of orifices and is
generally secured to the orifice plate by using mounting clamps, brackets
or the like. Once assembled, the manifold and orifice plate define a "dye
cavity" for the dye medium used during the print operation. In this
regard, the present method and apparatus for ultrasonically cleaning the
fluid jet components is particularly useful for cleaning the orifice
plate/dye cavity structures described and claimed in commonly-owned U.S.
application Ser. No. 750,589, the disclosure of which is hereby
incorporated by reference.
During the assembly of the orifice plate and manifold structure, tiny metal
particles, dust or other solid particulates may become trapped in the
assembly at or near the bearing and seating surfaces for metal components,
particularly when the clamps are tightened against the orifice plate. The
particles are thereafter introduced into the dye cavity and/or the
openings of the orifice plate itself. In addition, during normal operation
of the fluid jet printer, particles of dried ink or disperse dye may
become lodged in or adjacent to the orifices or even collect on the inside
surfaces of the fluid reservoir, dye cavity and related parts of the print
head assembly.
The problem of solid particulates in the fluid becomes particularly
significant in fluid jet devices in which certain of the droplets not
deposited on the print substrate are caught by a catcher structure (or
"gutter" assembly). The so-caught fluid droplets (containing undesired
solid particulates) are usually recirculated to the fluid supply system
for reuse in a subsequent printing operation. Invariably, contaminants
such as dust, lint and the like are introduced into the fluid supply
system and are not removed by conventional fluid filtration means. Such
solid particulates may "settle out" and attach to portions of the fluid
supply system forming undesired deposits.
Particles within the deposits may also break loose and migrate to other
portions of the fluid supply system causing clogging or contamination. In
particular, the solid particles in the fluid may block or partially hinder
the flow of fluid through one or more of the orifices, Obviously, if an
orifice is partially or totally blocked, the normal throughput of fluid
for deposition on the substrate may change. In addition, a blocked orifice
may result in imperfect droplet trajectories and/or variations in the
charging/deflection mode of the printer, thereby reducing the accuracy of
placement of the droplet on the substrate. In printing or dyeing
operations this could result in quality degradation.
Recently, it has been proposed to utilize a fluid jet apparatus as a means
to print patterns or the like on textile materials, such as the fluid jet
printing device disclosed in commonly-owned U.S. Pat. No. 4,523,202, the
disclosure of which is also expressly incorporated herein by reference.
Fine printing of patterns on a textile substrate is achieved by the use an
orifice plate having at least one linear array of very small orifices
sized in the range of, for example, 0.00035 to 0.020 inches in diameter
equally spaced from one another on the order of fifty to two hundred per
inch. It is highly desirable in the use of such small diameter, high
density orifices spaced for purposes of forming print patterns on textile
substrates that any particles or residue which might otherwise clog an
orifice or change its configuration be eliminated or reduced to an
absolute minimum.
A number of methods have been used in the past for cleaning an ink jet
printing head without removing the print head from the printing structure,
such as those shown by U.S. Pat. Nos. 4,007,465 and 4,276,554. In
addition, various approaches have been used for providing an ultrasonic
vibration to assist in dislodging trapped solid particles at or near the
orifice openings. Certain arrangements, for example, increase the ink
pressure upstream of the orifice while vibrating a nozzle or orifice
structure. Other proposals use vibration means coupled with heat at or
near the nozzle or orifice.
However, none of the prior arrangements are entirely effective for removing
particles or residues which might otherwise block the orifice openings,
particularly under circumstances where the orifice plate uses small,
closely-spaced orifice openings. In particular, the prior devices are
incapable of preventing ink clogs caused by contaminants introduced, for
example, when the orifice plate is initially fastened to the manifold
assembly before being placed in operation, or during a routine maintenance
function such as when a filter for the fluid supply is replaced without
shutting down and cleaning the entire fluid supply system. For
closely-spaced, high density orifice plate structures, the prior methods
of ultrasonic cleaning are also ineffective in removing solidified ink
which forms ink deposits during long periods of non-use, or the fine dust
particles and atmospheric impurities in the ink supply which may
ultimately cause the entire ink jet head to malfunction or perform to a
degree that is less than satisfactory. Prior methods and apparatus are
particularly unsuited for cleaning orifice plate assemblies for textile
applications in which the orifice array is on the order of 1.8 meters
long.
It has now been found that the above problems relating to the clogging of
orifices in fluid jet devices may be substantially eliminated by the
method and apparatus according to the present invention. In particular,
applicant has discovered a method for cleaning the ink jet printing
orifices of the orifice plate of a printing head which serves as the final
step in the initial assembly of the print head, i.e., at the critical time
when small, solid particulates are generated by the assembly process
itself. In essence, the improved method of ultrasonic cleaning according
to the invention includes the steps of placing the orifice plate/dye
cavity assembly into a tank containing a quantity of cleaning fluid. The
tank is then agitated at a ultrasonic frequency to cause cavitation of the
cleaning fluid, thereby dislodging foreign particles from the entire
orifice plate/dye cavity assembly. Simultaneously, a filtered fluid stream
is directed through the orifices of the orifice plate in a direction
opposite the normal flow of fluid through the orifices by pumping cleaning
fluid out through ink supply inlets on the opposite side of the orifice
plate/dye cavity assembly. The combination of ultrasonic fluid cavitation
and reverse flow causes particles to be dislodged from the orifices and
the ink/dye cavity. The solid particulates are then carried by the
reverse-directed fluid stream away from the orifices and out of the inlet
tubes of the dye manifold so that they cannot fall back toward the
orifices themselves. The dislodged solid particulates on the exterior of
the orifice plate/dye cavity assembly may be removed through a separate
cleaning fluid outlet in the ultrasonic agitation tank itself or through
the orifices into the cavity to be carried off by the reverse-directed
fluid stream. Alternatively, the exterior may be cleaned before the
interior.
INFORMATION DISCLOSURE STATEMENT
Various methods and apparatus for providing ultrasonic cleaning of devices,
including fluid jet manifolds and nozzle structures, are evidenced by U.S.
Pat. Nos. 3,572,352 to Koopman; 4,178,188 to Dussault et al; 4,296,418 to
Yamazaki et al; 4,007,465 to Chaudhary; 4,369,456 to Cruz-Uribe et al;
4,371,881 to Bork et al; 4,123,761 to Kimura et al; 4,050,078 to Isayama
et al; 4,375,991 to Sachs et al; 3,208,731 to Gams et al; 3,901,726 to
Snearly; 4,563,688 to Braun; 4,193,818 to Young et al; 4,372,787 to Fields
et al; 3,113,761 to Platzman; 4,600,928 to Braun et al.
Koopman '352 discloses a permanent cleaning vessel containing a cleaning
fluid and means for directing the flow of cleaning fluid through a fixed
passageway defined in the vessel through which a strip material to be
cleaned also passes in the same direction. An ultrasonic generator
transmits sonic energy into the fluid in the passageway to clean the strip
of material moving therethrough.
Dussault et al '188 teaches spraying a solvent stream onto the surface of a
rotating workpiece while applying an ultrasonic frequency to the workpiece
to induce cavitation of the sprayed solvent film on the workpiece.
Yamazaki et al '418 discloses a solvent tank containing a quantity of
pressurized solvent which communicates with a cap through a filter. The
cap is engaged with the orifice and pressurized solvent flows from the cap
through the nozzle and into a tank on the ink supply side of the nozzle
and into a tank on the ink supply side of the nozzle to dissolve clogged
ink in the nozzle. Pressurized air is then applied to the nozzle to purge
solvent from the nozzle.
Chaudhary '465 discloses a cross-flow of ink pressure within the dye
manifold to dislodge any soft clogs from the nozzle orifices. The
reference teaches discontinuing operation of the perturbation voltage
source during unclogging.
Cruz-Uribe et al '456 disclose an ink jet recorder having a cleaning belt
which is positioned so as to contact the orifice plate to wipe it clean.
Cleaning of nozzles is accomplished by the flow of ink out of the nozzles
due to capillary wicking.
Bork et al '881 and Kimura et al '761 both disclose cleaning orifices by
increasing ink pressure through the orifices to dislodge foreign particles
and dried ink.
Isayama et al '078 disclose ejecting a solvent through an ink jet printing
nozzle from the ink supply side to the ink ejection side of the nozzle to
remove ink deposits clogging the nozzle.
Sachs et al '991 teach a method for cleaning deposits from a heat exchanger
comprising banks of pipes situated in a water environment. A sonic
cleaning transducer is coupled to the banks of pipes to remove deposits
from the outer surfaces of the pipes.
Snearly '726, Young et al '818, Fields et al '787 and Platzman '761 are
indicative of the generally state of the art of ultrasonic cleaning.
Braun '688 utilizes a transducer to provide vibrational energy to the
orifice plate coupled with fluid "flushing" in a direction generally
parallel to the orifice plate.
Gams et al '731 disclose agitating dry workpieces in a tank and
subsequently rinsing the particles removed from the workpieces with a
fluid.
Braun et al '928 disclose cross-flowing ink in an orifice cavity, with a
thin layer of ink on the outside of the orifice plate, while applying
ultrasonics to effect cleaning.
The present invention deviates from the above methods and structures in
that it effectively eliminates clogging problems associated with
closely-spaced, high density orifice plate configurations. Unlike prior
arrangements, applicant's method and apparatus utilizes reverse flushing
of the orifice by fluid flow, coupled with the simultaneous application of
ultrasonic waves to cause cavitation of the cleaning fluid at or near the
orifice plate. Applicant's claimed method and apparatus also have
particular advantages as the final step in the assembly of an ink jet
printing head.
Thus, it is an object of the present invention to provide for an improved
method and apparatus for ultrasonically cleaning an orifice structure
prior to assembly into the fluid jet printing apparatus.
It is a further object of the present invention to provide for a method and
apparatus having means for causing ultrasonically-induced cavitation,
together with countercurrent fluid propelling means to effect cleaning of
small diameter, high density orifices used in fluid jet apparatus.
It is still a further object of the present invention to provide for an
improved method for cleaning orifices which have been in operation in a
fluid jet device for an extended period of time and/or have become
inoperative or inefficient due to the presence of solid particles or
deposits in or around the orifices.
These and other objects of the present invention will become more clear by
specific reference to the following discussion and appended drawings.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
FIG. 1 is a schematic elevational view, taken in cross-section, of an
exemplary ultrasonic cleaning device in accordance with the present
invention;
FIG. 2 is an end sectional view of the apparatus depicted in FIG. 1;
FIG. 3 is an elevational view, taken in cross-section, showing an exemplary
orifice plate/dye cavity assembly; and FIG. 4 is a view taken along line
4--4 of the orifice plate/dye cavity assembly depicted in FIG. 3.
DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EXEMPLARY EMBODIMENT
As indicated above, the improved apparatus for cleaning foreign particles
from an ink jet orifice plate assembly in accordance with the present
invention is particularly useful for assemblies which include high density
orifice plates having a plurality of closely-spaced orifices and which
utilize an ink stream input passage or ink supply manifold in the orifice
plate assembly.
In the preferred embodiment of the present invention, the ink jet orifice
plate manifold assembly is placed within a reservoir containing filtered
water or other suitable cleaning liquid. Ultrasonic vibration means are
provided for ultrasonically agitating and cavitating the liquid within the
reservoir at a fluid temperature suitable to cause cavitation (room
temperature is usually adequate) and reverse-flow propelling means are
connected to the input passage of the orifice plate/dye cavity assembly
for purposes of propelling a stream of liquid through the plurality of
orifices and out the ink stream in the passage. The simultaneous
cavitation and reverse flow causes foreign particles to be ultrasonically
dislodged from the orifice plate assembly and carried away.
Applicant's method for cleaning foreign particles from a newly-assembled
ink jet orifice plate/dye cavity assembly (which has at least one liquid
inlet passage and a plurality of orifices), includes the steps of
immersing the newly assembled ink jet head in the cleaning liquid,
ultrasonically agitating the liquid and, simultaneously with the agitating
step, propelling a stream of cleaning fluid through the orifices and out
the inlet passage to thereby propel dislodged foreign particles from the
assembled unit.
The ultrasonic vibration means employed in accordance with the present
invention may include conventional agitation devices currently available
for "ultrasonic washing" operations and are known within the textile
industry. Such devices include, for example, the "Ultrasonic Washing
Machine" manufactured by Studio Impianti Indistriali, Milan, Italy, and
typically comprise a fluid reservoir for housing the cleaning fluid, means
for imparting ultrasonic vibrations (ultimately resulting in cavitation of
the liquid) to the cleaning fluid, and means for circulating and/or
discharging the cleaning fluid from the reservoir chamber. A majority of
the ultrasonic devices available in the textile industry operate at
frequencies in the range of 10 to 40 KHz and it has been found that the
preferred operating frequency for the ultrasonic cleaning method according
to the invention is approximately 16 KHz. Typical conventional ultrasonic
"washing" devices utilize one or more piezoelectric transducers as the
principal means for generating fixed frequency ultrasonic vibrations.
During the simultaneous ultrasonic cleaning and reverse flow operation in
accordance with the present invention, the ultrasonic action of the washer
causes the filtered water (possibly with detergent) or cleaning solvent to
cavitate. That is, a localized small volume of liquid will decompress and
vaporize, thereby generating a high number of tiny bubbles within the
solvent. Immediately thereafter, the bubbles are recompressed within the
fluid chamber by the action of the ultrasonics, dislodging particulate
materials in the process. Then, the reverse flow of the cleaning liquid
through the orifice plate carries the particulate materials out of the
orifice plate assembly. For closely-spaced, high density orifice plates,
the use of ultrasonic cleaning techniques in conventional washing
equipment alone, without the reverse flow step, will not effectively
remove the solid particulates which become entrained in the dye medium or
which form in the orifice openings during normal operation or shutdown.
With particular reference to FIG. 1 of the drawings, an exemplary cleaning
device according to the present invention is shown generally at 10. An
assembled orifice plate and manifold structure are depicted at 15 and are
shown in greater detail in FIGS. 3 and 4. FIG. 1 also shows the direction
of fluid flow using an exemplary reverse flow fluid propelling means for
circulating the cleaning fluid through the orifice plate in a
countercurrent manner, i.e., in a direction opposite that for normal
printing operations.
The ultrasonic treatment chamber in accordance with the present invention
(shown generally at 20 in FIGS. 1 and 2) comprises a housing 24 and cover
26 which defines an inner fluid chamber 23 which holds cleaning medium 27.
An ultrasonic generator 21 and plurality of piezoelectric transducers 22
are operatively connected to an electrical control board 25 which set and
control the operating frequency, amplitude and waveform of the ultrasonic
vibrations within the inner fluid chamber. For maximum efficiency, the
transducers are positioned on the sides and bottom of inner fluid chamber
23 (see FIG. 2). In order to maintain the cleaning fluid at the optimum
desired temperature, one or more electrical heating units 28 may be
provided in the lower section of inner fluid chamber 23 and are controlled
by a conventional thermocouple and a fluid temperature control loop (not
shown). As will be apparent, chamber 23 must be large enough to hold the
orifice plate assembly, which in the case of a textile printing device may
be in excess of 1.8 meters long.
FIGS. 1 and 2 also illustrate means for recirculating the cleaning fluid
disposed within the inner fluid chamber and the cleaning fluid which is
forced through the orifices by the reverse flow fluid propelling means.
Fluid exit line 30 from the inner chamber permits the cleaning liquid to
flow from the chamber (along with any entrained solid particulates) by
gravity flow through valve 35, line 36 and valve 50 to waste. If filtered
water is used as the cleaning medium, the fluid supply may be continuously
discharged through line 36 without recirculation to the treatment chamber.
A continuous supply of fresh water may be supplied to the chamber by way
of inlet line 31 and a constant level in the chamber maintained by way of
conventional liquid level control means (not shown).
If, however, the cleaning medium consists of a recoverable cleaning solvent
or water containing a detergent additive, it may be desirable to
recirculate the liquid. Thus, valve 50 is closed, valve 51 is opened and
the exit liquid may be recirculated through one or more cartridge type
filter units 33 to remove solid particulates, dust and/or dried ink
particles. The filtered liquid is then recycled as shown to the inner
fluid chamber by way of, for example, a centrifugal cleaning fluid pump 52
in return line 53.
A simplified drawing of an exemplary orifice plate/dye cavity assembly
which may be cleaned in accordance with the present invention is depicted
in FIGS. 3 and 4 of the drawings. The assembled unit is shown generally as
40, having orifice plate 41 fastened to the dye manifold 42 by means of
clamps 43 and threaded to screws 44. A seal such as a neoprene O-ring 45
is provided between the orifice plate 41 and manifold 42. FIG. 3 also
shows the dye cavity 47 having inlet openings 48 and 49 which allow for
continuous flow of fluid into the cavity to be distributed along the
length of the orifice plate in normal printing operations. However, as
shown in FIGS. 3 and 4, the flow of cleaning fluid is the reverse of that
in normal printing operations, i.e., through the orifices and out the
inlet tubes.
An exemplary reverse flow fluid propelling arrangement in accordance with
the present invention is also depicted in FIG. 1 of the drawings. Openings
48 and 49 of dye cavity 47 are connected through check valve 55 to the
inlet of filter 33. Thus, with valve 51 closed, pump 52 draws fluid
through cavity 47, entraining loosened particles which are trapped in
filter 33 (as will be apparent, the contaminated fluid could merely be
sent to drain, if desired) before being returned to chamber 23 via line
53.
While the present invention has herein been described in what is presently
believed to be the most preferred embodiment thereof, those in the art
will recognize that many modifications may be made while retaining many of
the novel features of the invention, which modifications shall be accorded
the broadest scope of the appended claims so as to encompass all of the
equivalent structures and/or assemblies.
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