Cleaning apparatus and method of assembly therefor for cleaning an inkjet print head

BACKGROUND OF THE INVENTION

This invention generally relates to print head cleaning apparatus and methods and more particularly relates to a cleaning apparatus and method of assembly therefor for cleaning an inkjet print head.

An ink jet printer produces images on a recording medium by ejecting ink droplets onto the recording medium in an image-wise fashion. The advantages of non-impact, low-noise, low energy use, and low cost operation in addition to the ability of the printer to print on plain paper are largely responsible for the wide acceptance of ink jet printers in the marketplace.

More specifically, an ink jet printer comprises a print head cartridge that includes a plurality of ink ejection chambers and a plurality of ink ejection orifices in communication with respective ones of the ink ejection chambers. At every orifice an ink ejector is used to produce an ink droplet. In this regard, either one of two types of ink ejectors may be used. These two types of ink ejectors are heat actuated ink ejectors and piezoelectric actuated ink ejectors. With respect to piezoelectric actuated ink ejectors, a piezoelectric material is used. The piezoelectric material possesses piezoelectric properties such that an electric field is produced when a mechanical stress is applied. The converse also holds true; that is, an applied electric field will produce a mechanical stress in the material. When a piezoelectric actuated ink ejector is used for inkjet printing, an electric pulse is applied to the piezoelectric material causing the piezoelectric material to bend, thereby squeezing an ink droplet from an ink body in contact with the piezoelectric material. The ink droplet thereafter travels through the ink ejection orifice and lands on the recording medium. One such piezoelectric inkjet printer is disclosed by U.S. Pat. No. 3,946,398 titled “Method And Apparatus For Recording With Writing Fluids And Drop Projection Means Therefor” issued Mar. 23, 1976 in the name of Edmond L. Kyser, et al.

With respect to heat actuated ink ejectors, such as found in thermal ink jet printers, a heater locally heats the ink body and a quantity of the ink phase changes into a gaseous steam bubble. The steam bubble raises the internal ink pressure sufficiently for an ink droplet to be expelled through the ink ejection orifice and toward the recording medium. Thermal inkjet printers are well-known and are discussed, for example, in U.S. Pat. No. 4,500,895 to Buck, et al.; U.S. Pat. No. 4,794,409 to Cowger, et al.; U.S. Pat. No. 4,771,295 to Baker, et al.; U.S. Pat. No. 5,278,584 to Keefe, et al.; and the Hewlett-Packard Journal, Vol.

39

, No. 4 (Aug. 1988), the disclosures of which are all hereby incorporated by reference.

The print head cartridge itself may be a carriage mounted print head cartridge that reciprocates transversely with respect to the recording medium (i.e., across the width of the recording medium) as a controller connected to the print head cartridge selectively fires individual ones of the ink ejection chambers. Each time the print head traverses the recording medium, a swath of information is printed on the recording medium. After printing the swath of information, the printer advances the recording medium the width of the swath and the print head cartridge prints another swath of information in the manner mentioned immediately hereinabove. This process is repeated until the desired image is printed on the recording medium. Alternatively, the print head cartridge may be a page-width print head cartridge that is stationary and that has a length sufficient to print across the width of the recording medium. In this case, the recording medium is moved continually and normal to the stationary print head cartridge during the printing process.

Inks useable with piezoelectric and thermal ink jet printers, whether those printers have carriage-mounted or page-width print head cartridges, are specially formulated to provide suitable images on the recording medium. Such inks typically include a colorant, such as a pigment or dye, and an aqueous liquid, such as water, and/or a low vapor pressure solvent. More specifically, the ink is a liquid composition comprising a solvent or carrier liquid, dyes or pigments, humectants, organic solvents, detergents, thickeners, preservatives and other components. Moreover, the solvent or carrier liquid may be water alone or water mixed with water miscible solvents such as polyhydric alcohols, or organic materials such as polyhydric alcohols. Various liquid ink compositions are disclosed, for example, by U.S. Pat. No. 4,381,946 titled “Ink Composition For Ink-Jet Recording” issued May 3, 1983 in the name of Masafumi Uehara, et al.

Such inks for inkjet printers, whether of the piezoelectric or thermal type, have a number of special characteristics. For example, the ink should incorporate a nondrying characteristic, so that drying of the ink in the ink ejection chambers is hindered or slowed to such a state that by occasional spitting of ink droplets, the ejection chambers and corresponding orifices are kept open and free of dried ink. However, it has been observed that ink can builds-up on the print head and electrical interconnect of the print head. This ink build-up can result from the following three main sources: (1) ink puddling and splatter as ink is ejected; (2) ink aerosol condensation on the print head; and (3) ink redeposited by a service station cap and wiper. Such ink build-up may lead to the following undesirable results: (1) wet ink shorting the electrical interconnect of the print head thereby causing electrical malfunction of the print head; (2) paper fiber tracks causing unwanted lines of ink on the recording medium due to dragging of wet paper fibers stuck to the ink on the print head; (3) poor ink ejection orifice performance causing drop ejection errors, and drop velocity or drop volume degradation; and (4) ink drops falling-off the print head causing unwanted ink spots on the recording medium.

In addition, the inkjet print head cartridge is exposed to the environment where the inkjet printing occurs. That is, the previously mentioned ink ejection orifices are exposed to many kinds of air born particulates, such as dust, dirt and the previously mentioned paper fibers. Particulate debris may accumulate on surfaces formed around the orifices and may accumulate in the orifices and chambers themselves. That is, the ink may combine with such particulate debris to form an interference burr that blocks the orifice or that alters surface wetting to inhibit proper formation of the ink droplet. Blocking the orifice interferes with proper ejection of ink droplets, thereby altering the flight path of the ink droplets and causing the ink droplets to strike the recording medium in unintended locations. The particulate debris and ink build-up should be cleaned from the print head surface and orifice to restore proper droplet formation and proper ink droplet trajectory.

For all the foregoing reasons, it is important to clean the print head of unwanted ink and debris. In some prior art devices, this cleaning is accomplished by wiping the print head or by absorbing ink and debris from the print head.

A representative inkjet print head cartridge cleaner using a wiper blade to wipe the print head is disclosed by U.S. Pat. No. 5,907,335 titled “Wet Wiping Printhead Cleaning System Using A Non-Contact Technique For Applying A Printhead Treatment Fluid” issued May 25, 1999 in the name of Eric Joseph Johnson, et al. and assigned to the assignee of the present invention. The Johnson, et al. patent discloses cleaning in printers employing a “wiper” blade, which slidingly engages and wipes a nozzle orifice plate surface of a print head cartridge to remove excess ink and accumulated debris. Removal of excess ink and accumulated debris is intended to improve print head performance and print quality. According to the Johnson, et al. disclosure, the cleaning system comprises a print head service station including a source of treatment fluid located near a cap belonging to the service station. The cap is brought into sealing contact with the print head. A wiper, which is included in one embodiment of the service station, comes into contact with the print head for removing dried ink and debris. The treatment fluid lubricates the wiper to reduce wear of the wiper. Also, the treatment fluid dissolves some of the dried ink residue accumulated on the print head. In addition, the treatment fluid leaves a thin film, which does not readily dry, so that ink residue and other debris subsequently deposited on the print head over the layer of the fluid are more easily wiped-off. Scrappers are provided within the service station to clean the wipers.

Another technique for cleaning an inkjet print head is disclosed in Japanese Patent JP 3-189163 titled “Ink Jet Recorder” issued Aug. 19, 1989 to Canon, Incorporated. The Canon patent discloses a method of removal of paper powder, dust, ink or the like from the front discharge portion of a print head. More specifically, when the print head is positioned at a cleaning location in the printer by means of a carriage motor, the print head is pushed into contact with a ribbon of porous material. Ink, bubbles, e.t.c. are absorbed from the discharge portion of the print head by capillary action between the discharge portion and the porous material. The amounts of ink, bubbles, e.t.c., that may contain paper powder or dust, are absorbed in proportion to contact time with the porous material. After cleaning, the print head is then returned to a printing position by operation of the carriage motor. After confirming that the print head is no longer at the cleaning location, the porous material is advanced to ready another portion of the porous material for the next cleaning event.

Although prior art print head cartridge cleaning techniques, such as disclosed by the Johnson, et al. patent, may function satisfactorily, it has been observed that ink will build-up on the wiper over time. This results in diminished effectiveness of the wiper over the life of the wiper. Although scrapers, such as disclosed by the Johnson et al. patent, are sometimes provided to clean the wiper, use of scrappers do not eliminate the root cause of the problem and can themselves experience ink build-up that diminishes scraper effectiveness over time. Moreover, although the Canon patent discloses a porous material for removal of ink, bubbles, e.t.c. that may contain paper powder or dust, there is apparently no disclosure in the Canon patent that the porous material remains wrinkle-free in order to enhance cleaning effectiveness when the porous material is brought into contact with the print head. Also, according to the Canon patent, the porous material must remain in contact with the print head for a specified time to satisfactorily absorb ink, bubbles, paper powder or dust by the relatively slow process of capillary action. Use of the Canon cleaning technique therefore increases cleaning time.

Therefore, what is needed is a cleaning apparatus and method of assembly therefor for cleaning an inkjet print head, which apparatus and method (1) eliminate need for wipers and scrapers, yet removes ink build-up and particulate debris from the exterior surface of the print head to avoid wet ink shorting the electrical interconnect of the print head; (2) remove paper fiber tracks causing unwanted lines of ink on the recording medium; (3) improve poor ink ejection orifice performance that otherwise cause drop ejection errors, drop velocity or drop volume degradation; (4) reduce risk of ink drops falling-off the print head causing unwanted ink spots on the recording medium; and (5) avoid reliance on the relatively slow process of capillary action to clean the print head.

SUMMARY OF THE INVENTION

In a broad form, the invention is a cleaning apparatus and method of assembly therefore for cleaning an inkjet print head. The cleaning apparatus comprises a web supply for supplying a web therefrom. A web receiver is associated with the web supply for receiving the web, the web being capable of extending from the web supply to the web receiver and slidably engaging the print head for cleaning the print head. A web drive is associated with the web supply and the web receiver for driving the web from the web supply to the web receiver. The web drive is adapted to pull the web from the web supply with a first tension force and to pull the web onto the web receiver with a second tension force greater than the first tension force, so that the web is wrinkle-free while the web slidably engages the print head.

According to an aspect of the present invention, the cleaning apparatus comprises a web supply wound about a freely rotatable first spindle. Disposed proximate the first spindle is a web receiver comprising a rotatable second spindle for receiving the web thereon. In this manner, the web extends from the first spindle to the second spindle while the web slidably engages the exterior surface of the print head for cleaning the surface of the print head.

The cleaning apparatus further comprises a web drive coupled to the second spindle for driving the web from the freely rotatable first spindle to the second spindle. In this regard, the web drive comprises a drive roller concentrically mounted on a third spindle disposed proximate the first spindle. A portion of the web extending from the first spindle wraps partially around the drive roller, so that the web is pulled from the first spindle as the drive roller rotates. The web drive is also coupled to the second spindle. That is, the web drive simultaneously pulls the web onto the second spindle as the drive roller, which belongs to the web drive, pulls the web from the first spindle. In other words, the web drive both pulls the web from the web supply and pulls the web onto the web receiver. Moreover, it is the portion of the web that is wrapped partially around the drive roller that engages the print head surface for cleaning the print head surface.

The web drive further comprises a gear train for controllably rotating the second spindle (web receiver) and the third spindle (drive roller). Coupled to the second spindle is an adjustable overdrive slip clutch. The overdrive slip clutch is adjustable for applying a predetermined amount of sliding friction to the second spindle to control speed of rotation of the second spindle. Controlling speed of rotation of the second spindle will control the forward tension acting on the web. In this regard, the overdrive slip clutch can be adjusted to apply a desired forward tension force acting on the web. Moreover, the portion of the web that partially wraps around the drive roller effectively functions as a “passive slip clutch” arrangement. The passive slip clutch arrangement applies a predetermined amount of friction between the drive roller and the web, depending on a predetermined “wrap angle” (i.e., angle formed by the web as it wraps partially around the drive roller), so that the drive roller moves the web without slippage. In this regard, the passive slip clutch arrangement applies a desired back tension force acting on the web. Adjustment of the overdrive slip clutch and presence of the passive slip clutch allows the overdrive slip clutch and the passive slip clutch to cooperatively act to hold the web in tension, so that the web remains wrinkle-free. It is important that the web remains wrinkle-free. This is important to ensure that the surface of the web will contact the surface of the print head without gaps in contact coverage. This enhances cleaning effectiveness compared to a web having wrinkles.

An actuator is also provided for actuating the gear train. Actuating the gear train in turn rotates the second spindle and the drive roller a predetermined amount. In this regard, after the print head is sufficiently cleaned by the web, the actuator indexes the web by rotating the second spindle and the drive roller the predetermined amount in order to present an unused portion of the web for the next cleaning event.

The cleaning apparatus further includes a plurality of conventional spittoons for receiving ink ejected or “spit” from the cartridge orifices to clear the orifices of dried ink and debris. The cleaning apparatus also includes a plurality of conventional capping stations for capping the orifices when the print head is not in use, so that risk of ink dry-out is reduced. Thus, the cleaning apparatus may inventively include traditional spittoons and/or capping stations in combination with the web and web drive for enhanced cleaning effectiveness.

A feature of the present invention is the provision of a web capable of slidably engaging the print head for cleaning the print head.

Another feature of the present invention is the provision of a web drive to precisely drive the web, so that the web is wrinkle-free while the web slidably engages the print head.

An advantage of the present invention is that use thereof eliminates need for wipers and scrapers, yet removes ink build-up and particulate debris from the exterior surface of the print head.

Another advantage of the present invention is that use thereof (1) avoids wet ink shorting the electrical interconnect in the print head; (2) removes paper fiber tracks causing unwanted lines of ink on the recording medium; (3) improves poor ink ejection orifice performance that otherwise cause drop ejection errors, drop velocity or drop volume degradation; and (4) reduces risk of ink drops falling-off the print head causing unwanted ink spots on the recording medium.

Yet another advantage of the present invention is that use thereof reduces cleaning time.

These and other features and advantages of the present invention will become apparent to those skilled in the art upon a reading of the following detailed description when taken in conjunction with the drawings wherein there are shown and described illustrative embodiments of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

While the specification concludes with claims particularly pointing-out and distinctly claiming the subject matter of the present invention, it is believed the invention will be better understood from the following description when taken in conjunction with the accompanying drawings wherein:

FIG. 1

is a perspective view of an inkjet printer having a print head and also a cleaning apparatus disposed therein for cleaning the print head;

FIG. 2

is a view in partial elevation of the print head ejecting an ink drop and having particulate debris residing on an exterior surface of the print head;

FIG. 3

is a fragmentary view in partial elevation of one of a plurality of ink cartridges belonging to the print head;

FIG. 4

is a view taken along section line

4

—

4

of

FIG. 2

;

FIG. 5

is a view in perspective of a web belonging to the cleaning apparatus combined with conventional ink spittoons and print head capping stations;

FIG. 6

is a view in perspective of the cleaning apparatus;

FIG. 7

is a perspective view in elevation of the cleaning apparatus, this view showing a web supply, a web receiver and a web drive roller;

FIG. 8

is a perspective view in elevation of the cleaning apparatus, this view showing a first gear belonging to a gear train and also showing an actuator and ratchet engaging the first gear;

FIG. 9

is a view in perspective of the gear train, with parts removed for clarity;

FIG. 10

is a view in perspective of a second embodiment cleaning apparatus; and

FIG. 11

is a view in perspective of a second embodiment gear train, with parts removed for clarity, that belongs to the second embodiment cleaning apparatus.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention will be directed in particular to elements forming part of, or cooperating more directly with, apparatus in accordance with the present invention. It is to be understood that elements not specifically shown or described may take various forms well known to those skilled in the art.

Therefore, referring to

FIG. 1

, there is shown an inkjet printer, generally referred to as

10

, for printing an image

20

on a recording medium

30

. The recording medium

30

may be a reflective recording medium, such as paper, textile, or the like or recording medium

30

may be a transmissive recording medium such as transparency.

Referring to

FIGS. 1

,

2

and

3

, printer

10

comprises a thermal ink jet print head

40

having an exterior surface

45

thereon. Print head

40

includes a plurality of adjacent ink cartridges

50

a

,

50

b

,

50

c

and

50

d

containing ink having colors cyan, magenta, yellow and black, respectively. Although four ink cartridges

50

a

,

50

b

,

50

c

and

50

d

are disclosed herein, it should be appreciated that more or fewer ink cartridges may be present depending on the specific printing application required. Each ink cartridge

50

a/b/c/d

has formed therein at least one ink ejection chamber

60

, the chamber

60

containing an ink body

65

. Ink ejection chamber

60

terminates in a plurality of collinearly-aligned ink ejection orifices

70

(only some of which are shown) for ejecting a plurality of ink drops

80

onto recording medium

30

in order to form image

20

on recording medium

30

. Horizontally-disposed in chamber

60

is a generally rectangular die

90

. Die

90

has an underside surface

100

for reasons disclosed presently. In this regard, attached to underside surface

100

of die

90

is a plurality of thermal resistive heater elements or thin-film resistors

110

aligned with respective ones of orifices

70

, for locally boiling ink body

65

in the vicinity of orifices

70

. Resistors

110

are each electrically connected to a controller (not shown), so that the controller selectively controls flow of electrical energy to resistors

110

in response to output signals received from an image source, such as a scanner, computer or digital camera (all not shown). In this regard, when electrical energy momentarily flows to any of resistors

110

, the resistor

110

locally heats ink body

65

causing a vapor bubble (not shown) to form adjacent to resistor

110

. The vapor bubble pressurizes chamber

60

by displacing ink body

65

to squeeze ink drop

80

from ink body

65

. Ink drop

80

travels through orifice

70

to be intercepted by recording medium

30

. After a predetermined time, the controller ceases supplying electrical energy to resistor

110

. The vapor bubble will thereafter collapse due to absence of energy input to ink body

65

and ink will subsequently refill chamber

60

generally along flow lines illustrated by dual arrows

115

. A bulk ink supply, generally referred to as

120

, may be provided for supplying ink to refill chambers

60

. Of course, such a bulk ink supply

120

has a plurality of ink reservoirs

130

a

,

130

b

,

130

c

and

130

d

containing ink of colors cyan, magenta, yellow and black, respectively. Each of reservoirs

130

a/b/c/d

is connected, such as by means of flexible hoses (not shown), to respective ones of cartridges

50

a/b/c/d

for refilling chambers

60

in cartridges

50

a/b/c/d

. Reservoirs

130

a/b/c/d

may reside in a housing

135

having a lid

137

capable of being rotated, such as in direction of double headed arrow

138

, for opening and closing housing

135

. Thermal print head

40

may preferably be of a type such as disclosed by U.S. Pat. No. 6,231,168 titled “Ink Jet Print Head With Flow Control Manifold Shape” issued May 15, 2001 in the name of Robert C. Maze and assigned to the assignee of the present invention, the disclosure of which is hereby incorporated by reference. Although print head

40

is disclosed hereinabove as a thermal print head, print head

40

alternatively may be a piezoelectric print head, if desired.

As best seen in

FIGS. 1 and 4

, print head

40

is slidably mounted on a rail

140

extending at least the width of recording medium

30

, so that print head

40

reciprocatingly traverses rail

140

in direction of double-headed arrow

145

. Print head

40

traverses rail

140

by means of a first motor

150

connected to print head

40

and engaging rail

140

. Although print head

40

is shown as being driven by first motor

150

connected to print head

40

and engaging rail

140

, it may be appreciated that print head

40

may instead be driven by a belt and pulley assembly (not shown), if desired. A support member, such as a platen

160

, is spaced-apart from and disposed opposite to print head

40

for supporting recording medium

30

. Platen

110

may be configured as an elongate cylindrical roller operable by a second motor

170

for rotating platen

160

, so that recording medium

30

moves in direction of an arrow

175

.

It may be understood from the description hereinabove, that print head

40

is caused to traverse rail

140

in a first printing direction to print a first one of a plurality of printing swaths that will form image

20

. As the first printing swath is printed, platen

160

is not rotated so that platen

160

remains stationary. Then, after the first swath is printed, platen

160

is rotated through a predetermined angle to advance recording medium

30

a predetermined distance in direction of arrow

175

. At that point, print head

40

is caused to traverse rail

140

in a second printing direction opposite the first printing direction to print a second one of the printing swaths. In other words, print head

40

reciprocatingly traverses rail

140

in direction of arrow

145

. Platen

160

is rotated only after print head

40

reaches an end portion of rail

140

during each reciprocating motion of print head

40

. This process of reciprocating print head

40

and rotating platen

160

is repeated until all printing swaths are printed and recording medium

30

receives the entire desired image

20

.

However, at best seen in

FIGS. 2 and 3

, ink can builds-up and form unwanted ink incrustations or deposits

180

on print head surface

45

and the electrical interconnect (not shown) of print head

40

. These ink deposits

180

can result from the following three main sources: (1) ink puddling and splatter; (2) ink aerosol condensation on surface

45

; and (3) ink redeposited on surface

45

by a service station cap and wiper. Such ink deposits

180

may lead to the following undesirable results: (1) wet ink shorting the print head electrical interconnect thereby causing electrical malfunction of print head

40

; (2) paper fiber tracks causing unwanted lines of ink on recording medium

30

due to dragging of wet paper fibers stuck to ink on surface

45

; (3) poor ink ejection orifice performance causing drop ejection errors, drop velocity or drop volume degradation; and (4) ink drops falling-off surface

45

causing unwanted ink spots on recording medium

30

.

In addition, ink cartridges

50

a/b/c/d

are exposed to many kinds of air born particulate debris, such as dust, dirt and the previously mentioned paper fibers. Such particulate debris may accumulate to form particulate deposits

180

on surface

45

surrounding orifices

70

and may ultimately accumulate in orifices

70

and chambers

60

themselves. That is, such particulate deposits

180

may accumulate to form an interference burr that blocks orifice

70

or that alters surface wetting to inhibit proper formation of ink droplet

80

. Blocking orifice

70

interferes with proper ejection of ink droplets

80

, thereby altering the flight path of the ink droplets

80

and causing the ink droplets

80

to strike recording medium

30

in unintended locations. The particulate and ink build-up deposits

180

should be cleaned from surface

45

and orifice

70

to restore proper droplet formation and proper ink droplet trajectory.

Returning to

FIG. 1

, printer

10

further comprises an integrally attached open cradle

190

for removably receiving a print head cleaning apparatus, generally referred to as

200

. Cradle

190

has a rear wall

192

. Cradle

190

also has an opening

195

to allow print head

40

to travel along rail

140

and into cradle

190

so that print head

40

can be cleaned by cleaning apparatus

200

. Opening

195

also allows print head

40

to travel along rail

140

and out of cradle

190

after cleaning by cleaning apparatus

200

. As described in more detail hereinbelow, cleaning apparatus

200

is capable of cleaning particulate deposits

180

from surface

45

of print head

40

. Cradle

200

may include a positioning recess

210

formed in cradle

190

for precisely slidably positioning cleaning apparatus

200

in cradle

190

. Cradle

190

may also include a cover

220

capable of being rotated, such as in direction of a double-headed arrow

225

, for opening and closing cradle

190

in order to protect the interior of cradle

190

from dirt, dust and the like.

Referring to

FIGS. 5

,

6

and

7

, cleaning apparatus

200

comprises a web supply, generally referred to as

230

, for supplying a cleaning web

240

therefrom. Material comprising web

240

should preferably have a low tendency to produce errant fibers in order to reduce risk that web

240

will itself deposit fibers on surface

45

of print head

40

. In this regard, material comprising web

240

may be Freudenberg Evolon 100™ having a thickness of approximately 0.32 mm, or Contac EXNW0039™ having a thickness of approximately 0.23 mm, or similar web material, available from Freudenberg Vliesstoffe KG located in Weinheim, Germany. The supply of web

240

is wound about a freely rotatable first spindle

250

, which may have a diameter of approximately 0.348 inch (8.84 mm). Disposed proximate first spindle

250

is a web receiver comprising a rotatable second spindle

260

, which may have a diameter of approximately 0.350 inch (8.89 mm), for receiving web

240

thereon. Web

240

is capable of extending from first spindle

250

to second spindle

260

and is also capable of slidably engaging exterior surface

45

of print head

40

for cleaning surface

45

in a manner disclosed more fully hereinbelow.

Referring to

FIGS. 6

,

7

,

8

and

9

, cleaning apparatus

200

further comprises a web drive, generally referred to as

270

. The web drive

270

is coupled to second spindle

260

(web receiver) for driving web

240

from first spindle

250

(web supply) to second spindle

260

. Web drive

270

comprises a rotatable cylindrical drive roller

280

concentrically mounted on a third spindle

290

disposed proximate first spindle

250

. Drive roller

280

may have a wall thickness of approximately 0.157 inch (4 mm). The material of drive roller

280

may be a foam that is soft enough to conform to surface

45

for providing good wiping performance, yet stiff enough to effectively drive web

240

without slippage. Drive roller

280

is adapted to engage web

240

that is supplied from first spindle

250

such that drive roller

280

pulls web

240

from first spindle

250

in the manner disdosed hereinbelow. Web

240

is caused to wrap partially around drive roller

280

, as shown. That is, web

240

partially wraps around drive roller

280

so as to define a predetermined “wrap angle” Ø. The amount or value of wrap angle Ø is predetermined such that wrap angle Ø ensures that friction between web

240

and drive roller is sufficient to move web

240

as drive roller

280

rotates. In this manner, a “passive slip clutch” arrangement generally referred to as

285

is provided as web

240

partially wraps around drive roller

280

to define wrap angle Ø. That is, passive slip clutch arrangement

285

is provided by roller

280

and web

240

as web

240

partially wraps around drive roller

280

to define wrap angle Ø. Moreover, to maintain wrap angle Ø, interposed between web supply

230

and drive roller

280

and engaging web

240

is a generally cylindrical first tensioning bar

300

. First tensioning bar

300

assists in applying a back tension force to a portion of web

240

residing between drive roller

280

and web supply

230

. The back tension force acts in a direction

305

away from drive roller and toward web supply

230

. In addition, disposed opposite first tensioning bar

300

and interposed between drive roller

280

and second spindle

260

and engaging web

240

is a generally cylindrical second tensioning bar

310

. Second tensioning bar

310

assists in applying a forward tension force to a portion of web

240

residing between drive roller

280

and second spindle

260

. Furthermore, disposed approximately intemediate first spindle

250

and second spindle

260

is a generally cylindrical third tensioning bar

320

to also assist in applying a forward tension force to the portion of web

240

residing between drive roller

280

and second spindle

260

. The forward tension force acts in a direction

315

away from drive roller

280

and toward second spindle

260

. Thus, it may be understood from the description hereinabove and with reference to the several figures that web

240

defines a web path extending from web supply

230

to under first tensioning bar

300

, to over drive roller

280

, to under second tensioning bar

310

, to over third tensioning bar

320

and then onto second spindle

260

. In addition, first spindle

250

, second spindle

260

, third spindle

290

, first tensioning bar

300

, second tensioning bar

310

and third tensioning bar

320

are each coupled to a lightweight frame

330

made of plastic, aluminum, or the like, for supporting these components. Moreover, as described more fully hereinbelow, the portion of web

240

wrapped partially around drive roller

280

will engage print head surface

45

for cleaning print head surface

45

.

Referring again to

FIGS. 6

,

7

,

8

and

9

, the transverse cross section of drive roller

280

is illustrated as being circular. However, drive roller

280

may have a noncircular transverse cross section, such as oval, triangular or square, if desired. Moreover, corners of such a noncircular cross section for drive roller

280

could be presented to surface

45

in a manner to provide a “sharper” edge of drive roller

280

in order to enhance cleaning of surface

45

.

Referring yet again to

FIGS. 6

,

7

,

8

and

9

, web drive

270

further comprises a gear train, generally referred to as

340

. The gear train

340

is coupled to second spindle

260

(web receiver) and third spindle

290

(drive roller

280

) for controllably rotating second spindle

260

and third spindle

290

. Gear train

340

will now be described in detail. In this regard, gear train

340

comprises a firs gear

350

supported by first spindle

250

of web supply

240

. Although first gear

350

is supported by first spindle

250

, first gear

350

does not rotate first spindle

250

. Rather, first spindle

250

is freely rotatable. In other words, first gear

350

is freely rotatable. First gear

350

may have a diameter of approximately 1.000 inch (25.4 mm). Coupled to first gear

350

is a second gear

360

, which may have a diameter of approximately 0.833 inch (21.2 mm). Also coupled to first gear is a third gear

370

, which may have a diameter of approximately 0.833 inch (21.2 mm). Connected to second spindle

260

and engaging second gear

360

is a fourth gear

380

, which may have a diameter of approximately 0.563 inch (14.3 mm), so that fourth gear

380

rotates while second gear

360

rotates. Of course, second spindle

260

rotates while fourth gear

380

rotates in order to take-up web

240

onto second spindle

260

. Slidably coupled to second spindle

260

and affixed to fourth gear

380

is an adjustable overdrive slip clutch

390

. Overdrive slip clutch

390

has a threaded hole

395

therethrough in communication with a slot

397

formed in overdrive slip clutch

390

. The purpose of hole

395

is to receive a screw (not shown) for adjustably tightening and loosening overdrive slip clutch

390

on second spindle

260

. That is, tightening the screw will tend to close slot

397

thereby forcing clutch

390

to radially constrict and tighten around second spindle

260

. Conversely, loosening the screw will tend to open slot

397

allowing clutch

390

to radially expand and loosen around second spindle

260

. Thus, overdrive slip clutch

390

is adjustable for applying a predetermined amount of sliding friction to second spindle

260

. In this manner, overdrive slip clutch

390

can be adjusted so as to apply a desired forward tension force acting on web

240

in a direction generally illustrated by arrow

315

.

Still referring to

FIGS. 6

,

7

,

8

and

9

, gear train

340

also comprises a fifth gear

400

, which may have a diameter of approximately 0.563 inch (14.3 mm). Fifth gear

400

engages third gear

370

, so that fifth gear

400

rotates while third gear

370

rotates. Coupled to fifth gear

400

is a sixth gear

410

, which may have a diameter of approximately 0.188 inch (4.76 mm). Engaging sixth gear

410

and connected to third spindle

290

(drive roller

280

) is a seventh gear

420

, which may have a diameter of approximately 0.188 inch (4.76 mm), so that seventh gear

420

rotates while sixth gear

410

rotates. Of course, third spindle

290

rotates while seventh gear

420

rotates in order to rotate drive roller

280

. Adjustment of overdrive slip clutch

390

and presence of the previously mentioned passive slip clutch (i.e., provided by drive roller

280

and web

240

as web

240

partially wraps around drive roller

280

to define wrap angle Ø) allow overdrive slip clutch

390

and the passive slip clutch to cooperatively act to produce the previously mentioned back tension force and forward tension force. Proper management of the back tension force and the forward tension force will hold web

240

in tension. In this manner, web

240

remains in tension and wrinkle-free. It is important that web

240

remains wrinkle-free. This is important because wrinkle-free web

240

ensures that web

240

will contact surface

45

of print head

40

without gaps in contact coverage. This enhances cleaning effectiveness compared to a web having wrinkles.

Returning to

FIGS. 1 and 5

, cleaning apparatus

200

further includes a chassis

440

integrally connected to frame

330

for reasons disclosed presently. In this regard, chassis

440

includes a plurality of conventional spittoons

442

alignable with ink ejection orifices

70

of cartridges

50

a/b/c/d

for receiving ink ejected or “spit” from cartridges

50

a/b/c/d

. This occasional “spitting” of ink from orifices

70

of cartridges

50

a/b/c/d

is intended to keep orifices

70

clear of unwanted dried ink and particulate debris. Chassis

440

further includes a plurality of conventional capping stations

444

alignable with orifices

70

for capping orifices

70

when print head

40

is not in use. Capping of orifices

70

reduces risk that ink will dry-out. Moreover, chassis

440

also includes a plurality of barrier walls

446

capable of abutment with respective ones of cartridges

50

a/b/c/d

to establish a barrier against damage to cartridges

50

a/b/c/d

while cartridges

50

a/b/c/d

are capped. Chassis

440

and integrally attached frame

330

are movable generally in the direction of a double-headed arrow

447

for aligning spittoons

442

or capping stations

444

with orifices

70

of cartridges

50

a/b/c/d

. Chassis

440

and integrally attached frame

330

are movable by means of a motor mechanism (not shown) engaging chassis

440

. Thus, web

240

of cleaning apparatus

200

is inventively combined with traditional spittoons

442

and capping stations

444

for enhanced cleaning effectiveness.

Still referring to

FIGS. 1 and 5

, the cleaning technique using cleaning apparatus

200

will now be described. In this regard, first motor

150

, which engages rail

140

and print head

40

, moves print head

40

along rail

140

, through opening

195

and into cradle

190

to begin the cleaning event. First motor

150

positions print head

40

at a predetermined location within cradle

190

, such that surface

45

can be cleaned by web

240

. The previously mentioned motor mechanism (not shown) that engages chassis

440

then reciprocates chassis

440

backward and forward along positioning recess

210

in direction of arrow

447

. Reciprocation of chassis

440

backward and forward a single time is defined herein as a cleaning cycle. When chassis

440

translates in the forward direction (i.e., toward the front of printer

10

), the portion of web

240

that is partially wrapped around drive roller

280

will engage surface

45

of print head

40

to clean surface

45

. When chassis

440

translates in the backward direction (i.e., toward the rear of printer

10

), the portion of web

240

that is partially wrapped around drive roller

280

will again engage surface

45

of print head

40

to clean surface

45

. This movement of chassis

440

will cause web

240

to rub surface

45

and remove particulate debris

180

from surface

45

in order to clean surface

45

. The particulate debris

180

, thus removed, will adhere to web

240

due to the composition of web

240

, which may be the previously mentioned Freudenberg Evolon 100™ or Contac EXNW0039™. Approximately seven cleaning cycles are preferably used to clean surface

45

. However, at the end of each cleaning cycle, first motor

150

that engages print head

40

and rail

140

moves print head

40

through opening

195

and out cradle

190

in order to continue printing image

20

. This process is repeated until all cleaning cycles (e.g., seven cleaning cycles) comprising the cleaning event are completed. After a predetermined time during operation of printer

10

, print head

40

is again cleaned in the manner described immediately hereinabove. However, between each cleaning event, web

240

is advanced in the manner disclosed hereinbelow. Advancement of web

240

presents a clean and unused portion of web

240

for cleaning print head

40

prior to each cleaning event.

The manner in which web

240

is advanced will now be described. As best seen in

FIGS. 1 and 8

, cleaning apparatus

200

further comprises an elastic lever or actuator

448

connected to frame

330

and adapted to engage rear wall

192

for indexing first gear

350

a predetermined amount. When first gear

330

is indexed, second spindle

260

and drive roller

280

each index a predetermined amount proportional to their respective diameters. Second spindle

260

and drive roller

280

will index when first gear

330

is indexed because first gear

330

is coupled to second spindle

260

and drive roller

280

in the manner previously described. In this regard, actuator

440

, which may be a relatively thin member of stainless steel, has an outwardly projecting elbow-shaped portion

450

for engagement with rear wall

192

in a manner described more fully hereinbelow. In this respect, when the previously mentioned motor mechanism (not shown) reciprocates chassis

440

after the last cleaning cycle (e.g., the seventh cleaning cycle), the motor mechanism will move chassis

440

toward rear wall

192

until elbow-shaped portion

450

engages rear wall

192

. When elbow-shaped portion

450

engages rear wall

192

, actuator

440

will elastically move generally in a direction illustrated by arrow

455

. When actuator

440

moves in the direction illustrated by arrow

455

, an end portion

460

of actuator

440

will engage first gear

350

to index first gear

350

the predetermined amount. Indexing of first gear

350

will also index gears

360

,

370

,

380

,

400

,

410

and

420

because first gear

350

and gears

360

,

370

,

380

,

400

,

410

and

420

are all interacting members of gear train

340

. Of course, indexing of first gear

350

and gears

360

,

370

,

380

,

400

,

410

and

420

will index drive roller

280

, second spindle

260

and third spindle

290

for advancing web

240

a predetermined amount. As previously mentioned, advancement of web

240

presents a clean and unused portion of web

240

for cleaning print head

40

prior to a cleaning event. After first gear

350

is indexed, the controller (not shown) controlling the motor mechanism will translate chassis

440

away from rear wall

192

, so that elbow-shaped portion

450

of actuator

440

disengages rear wall

192

. Due to the elastic nature of actuator

440

, the actuator

440

will then reset or return to its original position, to await the next cleaning event.

Still referring to

FIG. 8

, it is desirable to prevent first gear

350

from reversing direction, such as due to vibration, after being indexed. This is desirable in order to prevent reverse travel of web

240

and redeposit of the particulate debris

180

onto surface

45

by web

240

. Therefore, an elongate ratchet lock

470

is also provided to prevent first gear

350

from reversing direction after being indexed. Ratchet lock

470

is connected to frame

330

and has an end portion

475

adapted to engage first gear

350

. Ratchet lock

470

allows first gear

350

to index in its intended direction but not to reverse direction after being indexed.

It may be understood from the description hereinabove that first spindle

250

will obtain a predetermined amount of lineal travel ? S

I

which is equal to the radius of first gear

350

times the angle of rotation of first gear

350

when first gear

350

is indexed by actuator

440

. A predetermined amount of web

240

will be fed from web supply

230

each time first gear

350

is indexed by actuator

440

. For example, indexing of first gear

350

one time, which corresponds to approximately 0.0524 inch (1.33 mm) of travel of actuator

440

, may equal 30° of rotation of first gear

350

. This, in turn, may correspond to approximately 0.0269 inch (0.685 mm) of travel for web

240

. Also, according to the invention, the rate at which web

240

is taken-up by second spindle

260

is faster than the rate of web

240

that is fed from web supply

230

. This is so in order to maintain tension in web

240

without slack, so that web

240

is wrinkle-free. In other words, ?S

E

>?S

I

, or (?S

E

)/(?S

I

)>1, where ?S

E

equals the radius of fourth gear

380

times the angle of rotation of fourth gear

380

when fourth gear

380

is indexed. It may be appreciated by a person of ordinary skill in the art that second spindle

260

is coupled to fourth gear

380

and therefore ?S

E

increases as web

240

is wound onto second spindle

260

.

Turning now to

FIGS. 10 and 11

, there is shown a second embodiment of the present invention, which is a second embodiment cleaning apparatus generally referred to as

480

. Second embodiment cleaning apparatus

480

is substantially similar to first embodiment cleaning apparatus

200

, except that a pressure foot

490

of predetermined transverse cross section is connected to frame

330

and interposed between web supply

230

and drive roller

280

. Material of pressure foot

490

may be a foam that is soft enough to conform to surface

45

for providing good wiping performance. Use of second embodiment cleaning apparatus

480

obtains an advantage not provided by first embodiment cleaning apparatus

200

. In this regard, cross section of pressure foot

490

may possess virtually any desired cross sectional profile. This in turn provides greater flexibility in designing the interactions between web

240

and surface

45

of print head

40

compared to the circular cross section of drive roller

280

when only drive roller

280

is used to clean surface

45

of print head

40

.

Referring again to

FIGS. 10 and 11

, cleaning apparatus

480

may also comprise a second embodiment gear train, generally referred to as

500

. The gear train

500

is coupled to first spindle

250

(web supply

230

), second spindle

260

(web receiver) and third spindle

290

(drive roller

280

) for controllably rotating first spindle

250

, second spindle

260

and third spindle

290

in the manner disclosed hereinbelow. In this regard, second embodiment gear train

500

will now be described in detail. More specifically, gear train

500

comprises an eighth gear

510

supported by freely rotatable first spindle

250

. Eighth gear

510

may have a diameter of approximately 1.000 inch (25.4 mm). Coupled to eighth gear

510

is a ninth gear

520

, which may have a diameter of approximately 0.833 inch (21.2 mm). Also coupled to eighth gear

510

is a tenth gear

530

, which may have a diameter of approximately 0.667 inch (16.9 mm). Connected to second spindle

260

and engaging tenth gear

530

is an eleventh gear

540

, which may have a diameter of approximately 0.563 inch (14.3 mm), so that eleventh gear

540

rotates while ninth gear rotates. Slidably coupled to second spindle

260

and affixed to eleventh gear

540

is the previously mentioned overdrive slip clutch

390

for applying a predetermined amount of sliding friction to second spindle

260

.

Still referring to

FIGS. 10 and 11

, second embodiment gear train

500

also comprises a twelfth gear

550

, which may have a diameter of approximately 0.438 inch (11.1 mm). Twelfth gear

550

engages tenth gear

530

,

0

that twelfth gear

550

rotates while tenth gear

530

rotates. Coupled to twelfth gear

550

is a thirteenth gear

560

, which may have a diameter of approximately 0.209 inch (5.31 mm). Engaging thirteenth gear

560

and connected to third spindle

290

is a fourteenth gear

570

, which may have a diameter of approximately 0.229 inch (5.82 mm), so that fourteenth gear

570

rotates while thirteenth gear

560

rotates. Moreover, web

240

wraps partially around drive roller

280

to define the previously mentioned passive slip clutch arrangement.

It may be understood from the description hereinabove that, according to this second embodiment cleaning apparatus

480

, first spindle

250

will obtain a predetermined amount of lineal travel ΔS

1

which equals the radius of eighth gear

510

times the angle of rotation of eighth gear

510

when eighth gear

510

is indexed. A predetermined amount of web

240

will be fed from web supply

230

each time eighth gear

510

is indexed by actuator

440

. For example, indexing of eighth gear

510

one time, which corresponds to approximately 0.0524 inch (1.33 mm) of travel of actuator

440

, may equal 3° of rotation of eighth gear

510

. This in turn, may correspond to approximately 0.0182 inch (0.0.462 mm) of travel for web

240

. Adjustment of overdrive slip clutch

390

and presence of the previously mentioned passive slip clutch arrangement

285

(i.e., provided by drive roller

280

and web

240

as web

240

partially wraps around drive roller

280

to define wrap angle Ø) allow overdrive slip clutch

390

and the passive slip clutch arrangement to cooperatively act to hold web

240

in tension, so that web

240

remains wrinkle-free. Moreover, this second embodiment cleaning apparatus

500

includes the previously mentioned chassis

440

integrally connected to frame

330

for reasons disclosed hereinabove.

It may be appreciated from the description hereinabove, that an advantage of the present invention is that use thereof eliminates need for wipers and scrapers, yet removes ink build-up and particulate debris from the exterior surface

45

of the print head

40

. This is so because the invention uses web

240

to rub surface

45

in order to clean print head

40

.

Another advantage of the present invention is that use thereof thoroughly cleans surface

45

of print head

40

in order (1) to avoid wet ink shorting the electrical interconnect between the print head and controller; (2) to remove paper fiber tracks causing unwanted lines of ink on the recording medium; (3) to improve poor ink ejection orifice performance that otherwise cause drop ejection errors, drop velocity or drop volume degradation; and (4) to reduce risk of ink drops falling-off the print head causing unwanted ink spots on the recording medium. This is so because web

240

remains wrinkle-free to contact surface

45

of print head

40

without gaps in coverage in order to remove particulate debris

180

more efficiently compared to a web having wrinkles.

Yet another advantage of the present invention is that use thereof reduces cleaning time. This is so because web

240

rubs surface

45

to remove particulate debris

180

and avoids reliance on the relatively slow process of capillary action in order to clean surface

45

of print head

40

by absorption of ink. Also, use of the invention reduces cleaning time compared to using wipers because rubbing surface

45

to clean surface

45

can be accomplished more quickly than moving a flexible (e.g., rubber) wiper across surface

45

. This is so because such a wiper is moved relatively slowly along surface

45

to allow time for the flexible wiper to conform to the contour (e.g., surface irregularities) of surface

45

. The foam material of drive roller

280

(or foot

490

), on the other hand, readily conforms to irregularities of surface

45

.

While the invention has been described with particular reference to its preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements of the preferred embodiments without departing from the invention. For example, different configurations of gear trains other than gear train

340

and second embodiment gear train

500

may be used, if desired. As another example, although the invention is disclosed herein for cleaning a thermal inkjet print head, the invention may also be used to clean a piezoelectric inkjet print head as well.

Therefore, what is provided is a cleaning apparatus and method of assembly therefor for cleaning an inkjet print head.

Parts List

Ø. . . wrap angle

10

. . . inkjet printer

20

. . . image

30

. . . recording medium

40

. . . print head

45

. . . exterior surface

50

a/b/c/d

. . . ink cartridges

60

. . . ink ejection chambers

65

. . . ink body

70

. . . ink ejection orifices

80

. . . ink drop

90

. . . die

100

. . . underside surface of die

110

. . . thermal resistors

115

. . . arrow (flowlines)

120

. . . bulk ink supply

130

a/b/c/d

. . . ink reservoirs

135

. . . housing

137

. . . lid

138

. . . arrow (direction of rotation of lid

137

)

140

. . . rail

145

. . . arrow (direction of travel of print head

40

)

150

. . . first motor

160

. . . platen

170

. . . second motor

175

. . . arrow (direction of travel of recording medium

30

)

180

. . . deposits

190

. . . cradle

192

. . . rear wall

195

. . . opening

200

. . . print head cleaning apparatus

210

. . . positioning recess

220

. . . cover

225

. . . arrow (direction of rotation of cover

220

)

230

. . . web supply

240

. . . web

250

. . . fist spindle

260

. . . second spindle

270

. . . web drive

280

. . . drive roller

285

. . . passive slip clutch arrangement

290

. . . third spindle

300

. . . first tensioning bar

305

. . . arrow (direction of back tension force)

310

. . . second tensioning bar

315

. . . arrow (direction of forward tension force)

320

. . . third tensioning bar

330

. . . frame

340

. . . geutrain

350

. . . first gear

360

. . . second gear

370

. . . third gear

380

. . . fourth gear

390

. . . overdrive slip clutch

395

. . . threaded hole

397

. . . slot

400

. . . fifth gear

410

. . . sixth gear

420

. . . seventh gear

440

. . . chassis

442

. . . spittoons

444

. . . capping stations

446

. . . barrier walls

447

. . . arrow (direction of movement of chassis)

448

. . . actuator

450

. . . elbow-shaped portion of actuator

455

. . . arrow (direction of movement of actuator)

460

. . . end portion (of actuator)

470

. . . ratchet lock

475

. . . end portion (of ratchet lock)

480

. . . second embodiment cleaning apparatus

490

. . . pressure foot

500

. . . second embodiment gear train

510

. . . eighth gear

520

. . . ninth gear

530

. . . tenth gear

540

. . . eleventh gear

550

. . . twelfth gear

560

. . . thirteenth gear

570

. . . fourteenth gear

Number	Name	Date	Kind
3946398	Kyser et al.	Mar 1976	A
4369456	Cruz-Uribe et al.	Jan 1983	A
4381946	Uehara et al.	May 1983	A
4500895	Buck et al.	Feb 1985	A
4771295	Baker et al.	Sep 1988	A
4794409	Cowger et al.	Dec 1988	A
4928120	Spehrley, Jr. et al.	May 1990	A
5278584	Keefe et al.	Jan 1994	A
5300958	Burke et al.	Apr 1994	A
5487728	Vaillancourt	Jan 1996	A
5489927	Harmon	Feb 1996	A
5500660	Childers et al.	Mar 1996	A
5507226	Burke et al.	Apr 1996	A
5583548	Kearns	Dec 1996	A
5602573	Waschhauser et al.	Feb 1997	A
5745133	Hendricks et al.	Apr 1998	A
5815176	Rotering	Sep 1998	A
5907335	Johnson et al.	May 1999	A
5969731	Michael et al.	Oct 1999	A
5997128	Lou et al.	Dec 1999	A
6155666	Sugimoto et al.	Dec 2000	A
6193537	Harper, Jr. et al.	Feb 2001	B1
6206499	Iijima et al.	Mar 2001	B1
6231168	Maze et al.	May 2001	B1
6290324	Jackson et al.	Sep 2001	B1

Number	Date	Country
0558219	Sep 1993	EP
0856404	Aug 1998	EP
1080909	Mar 2001	EP
3189163	Aug 1991	JP
405064895	Mar 1993	JP

Cleaning apparatus and method of assembly therefor for cleaning an inkjet print head

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (25)

Foreign Referenced Citations (5)

Non-Patent Literature Citations (2)

Entry
Hewlett-Packard Jounal, Aug. 1988 pp. 1-88, various authors.
Patent Abstract of Japan, Inventor-Martin Guraife, entitled Method and Apparatus for Cleaning Printing Head of Ink-jet Printer, publication date Jan. 23, 2001, publication No. 2001018409, 1 page.