BACKGROUND OF THE INVENTION The present invention relates to ink containers for providing ink to inkjet printers. More specifically, the present invention relates to ink containers that make use of a network of heat bonded fibers for retaining and providing the controlled release of ink from the ink container.

Inkjet printers frequently make use of an inkjet printhead mounted within a carriage that is moved back and forth across print media, such as paper. As the printhead is moved across the print media, a control system activates the printhead to deposit or eject ink droplets onto the print media to form images and text. Ink is provided to the printhead by a supply of ink that is either carried by the carriage or mounted to the printing system not to move with the carriage.

For the case where the ink supply is not carried with the carriage, the ink supply can be in continuous fluid communication with the printhead by the use of a conduit to replenish the printhead continuously. Alternatively, the printhead can be intermittently connected with the ink supply by positioning the printhead proximate to a filling station that facilitates connection of the printhead to the ink supply.

For the case where the ink supply is carried with the carriage, ink supply may be integral with the printhead, whereupon the entire printhead and ink supply are replaced when ink is exhausted. Alternatively, the ink supply can be carried with the carriage and be separately replaceable from the printhead. For the case where the ink supply is separately replaceable, the ink supply is replaced when exhausted, and the printhead is replaced at the end of printhead life. Regardless of where the ink supply is located within the printing system, it is critical that the ink supply provide a reliable supply of ink to the inkjet printhead.

In addition to providing ink to the inkjet printhead, the ink supply frequently provides additional functions within the printing system, such as maintaining a negative pressure, frequently referred to as a backpressure, within the ink supply and inkjet printhead. This negative pressure must be sufficient so that a head pressure associated with the ink supply is kept at a value that is lower than the atmospheric pressure to prevent leakage of ink from either the ink supply or the inkjet printhead, frequently referred to as drooling. The ink supply is required to provide a negative pressure or back pressure over a wide range of temperatures and atmospheric pressures which the inkjet printer experiences in storage and operation.

One negative pressure generating mechanism that has previously been used is a porous member, such as an ink absorbing member, which generates a capillary force. Once such ink absorbing member is a reticulated polyurethane foam which is discussed in U. S. Patent 4,771,295, entitled"Thermal Inkjet Pen Body Construction Having Improved Ink Storage and Feed Capability"to Baker, et al., issued September 13,1988, and assigned to the assignee of the present invention.

There is an ever present need for ink supplies which make use of low cost materials and are relatively easy to manufacture, thereby reducing ink supply cost that tends to reduce the per page printing costs. In addition, these ink containers should be volumetrically efficient to produce a relatively compact ink supply for reducing the overall size of the printing system. In addition, these ink supplies should be capable of being made in different form factors so that the size of the printing system can be optimized. Finally, these ink supplies should be compatible with inks used in inkjet

printing systems to prevent contamination of these inks. Contamination of the ink tends to reduce the life of the inkjet printhead as well as reduce the print quality.

SUMMARY OF THE INVENTION One aspect of the present invention relates to a method of manufacturing a capillary member for use in an ink reservoir for providing ink to an inkjet printhead.

The method includes extruding a three dimensional capillary member. The method further includes cutting the extrusion at a discrete length that corresponds to at least one dimension of an ink reservoir.

In one preferred embodiment, the three dimensional capillary member is a network of fibers for use within the ink reservoir to retain ink. The network of fibers are heat fused to each other at points of contact to define a capillary storage member for storing ink. At least one fiber in the network of fibers is a bi-component fiber having a core material and a sheath material at least partially surrounding the core material. The core material is polypropylene and the sheath material is polyethylene terephthalate.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. I is an exemplary embodiment of an inkjet printer that incorporates the ink container of the present invention.

Fig. 2 is a schematic representation of the ink container of the present invention and an inkjet printhead that receives ink from the ink container to accomplish printing.

Fig. 3 is an exploded view of the ink container of the present invention showing an ink reservoir, a network of fused fibers for insertion into the reservoir, and a reservoir cover for enclosing the reservoir.

Fig. 4A represents the network of fused fibers shown in Fig. 3.

Fig. 4B is a greatly enlarged perspective view taken across lines 4B-4B of the network of fused fibers shown in Fig. 4A that are inserted into the ink reservoir shown in Fig. 3.

Fig. SA is a cross section of a single fiber taken across lines 5-5 of Fig. 4.

Fig. 5B is an alternative embodiment of a fiber shown in Fig. 4 having a cross- shaped or x-shaped core portion.

Fig. 6 is a cross section of a pair of fibers that are fused at a contact point taken across lines 6-6 shown in Fig. 4.

Fig. 7 is a simplified representation of the method of the present invention for filling the ink supply shown in Fig. 3.

Fig. 8 is a schematic representation of the ink container shown in Fig. 3 fluidically coupled to an inkjet printhead.

Fig. 9 is a schematic representation of the method of the present invention for manufacturing the ink container of the present invention shown in Fig. 3.

Fig. 10 is a perspective view of an extrusion of the present invention shown in perspective prior to being cut to form a capillary storage member.

Fig. 11 is a flow diagram illustrating the method of the present invention for manufacturing the ink container of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Fig. 1 is a perspective view of one exemplary embodiment of a printing system 10, shown with its cover open, that includes at least one ink container 12 of the present invention. Before discussing the method of the present invention for manufacturing the ink container 12 it will be helpful to discuss the ink container in more detail. The printing system 10 includes at least one inkjet printhead (not shown) installed in the printer portion 14. The inkjet printhead is responsive to activation signals from the printer portion 14 to eject ink. The inkjet printhead is replenished with ink by the ink container 12.

The inkjet printhead is preferably installed in a scanning carriage 18 and moved relative to a print media as shown in Fig. 1. Alternatively, the inkjet printhead is fixed and the print media is moved past the printhead to accomplish printing. The inkjet printer portion 14 includes a media tray 20 for receiving print media 22. As print media 22 is stepped through the print zone, the scanning carriage moves the printhead relative to the print media 22. The printer portion 14 selectively activates the printhead to deposit ink on print media to thereby accomplish printing.

The printing system 10 shown in Fig. I is shown with 2 replaceable ink containers 12 representing an ink container 12 for black ink and a three-color partitioned ink container 12 containing cyan, magenta, and yellow inks, allowing for printing with four colorants. The method and apparatus of the present invention is applicable to printing systems 10 that make use of other arrangements such as printing systems that use greater or less than 4-ink colors, such as in high fidelity printing which typically uses 6 or more colors.

Fig. 2 is a schematic representation of the printing system 10 which includes the ink supply or ink container 12, an inkjet printhead 24, and a fluid interconnect 26 for fluidically interconnecting the ink container 12 and the printhead 24.

The printhead 24 includes a housing 28 and an ink ejection portion 30. The ink ejection portion 30 is responsive to activation signals by the printer portion 14 for ejecting ink to accomplish printing. The housing 28 defines a small ink reservoir for containing ink 32 that is used by the ejection portion 30 for ejecting ink. As the inkjet printhead 24 ejects ink or depletes the ink 32 stored in the housing 28, the ink container 12 replenishes the printhead 24. A volume of ink contained in the ink supply 12 is typically significantly larger than a volume of ink contained within the housing 28. Therefore, the ink container 12 is a primary supply of ink for the printhead 24.

The ink container 12 includes a reservoir 34 having a fluid outlet 36 and an air inlet 38. Disposed within the reservoir 34 is a network of fibers that are heat fused at points of contact to define a capillary storage member 40. The capillary storage member 40 performs several important functions within the inkjet printing system 10.

The capillary storage member 40 must have sufficient capillarity to retain ink to

prevent ink leakage from the reservoir 34 during insertion and removal of the ink container 12 from the printing system 10. This capillary force must be sufficiently great to prevent ink leakage from the ink reservoir 34 over a wide variety of environmental conditions such as temperature and pressure changes. The capillary should be sufficient to retain ink within the ink container 12 for all orientations of the reservoir 34 as well as undergoing shock and vibration that the ink container 12 may undergo during handling.

Once the ink container 12 is installed into the printing system 10 and fluidically coupled to the printhead by way of fluid interconnect 26, the capillary storage member 40 should allow ink to flow from the ink container 12 to the inkjet printhead 24. As the inkjet printhead 24 ejects ink from the ejection portion 30, a negative gauge pressure, sometimes referred to as a back pressure, is created in the printhead 24. This negative gauge pressure within the printhead 24 should be sufficient to overcome the capillary force retaining ink within the capillary member 40, thereby allowing ink to flow from the ink container 12 into the printhead 24 until equilibrium is reached. Once equilibrium is reached and the gauge pressure within the printhead 24 is equal to the capillary force retaining ink within the ink container 12, ink no longer flows from the ink container 12 to the printhead 24. The gauge pressure in the printhead 24 will generally depend on the rate of ink ejection from the ink ejection portion 30. As the printing rate or ink ejection rate increases, the gauge pressure within the printhead will become more negative, causing ink to flow at a higher rate to the printhead 24 from the ink container 12. In one preferred inkjet printing system 10, the printhead 24 produces a maximum backpressure that is equal to 10 inches of water or a negative gauge pressure that is equal to 10 inches of water.

The printhead 24 can have a regulation device included therein to compensate for environmental changes such as temperature and pressure variations. If these variations are not compensated for, then uncontrolled leaking of ink from the printhead ejection portion 30 can occur. In some configurations of the printing system 10, the printhead 24 does not include a regulation device. Instead the capillary member 40 is used to maintain a negative back pressure in the printhead 24 over normal pressure and temperature excursions. The capillary force of the capillary

member 40 tends to pull ink back to the capillary member, thereby creating a slight negative back pressure within the printhead 24. This slightly negative back pressure tends to prevent ink from leaking or drooling from the ejection portion 30 during changes in atmospheric conditions such as pressure changes and temperature changes.

The capillary member 40 should provide sufficient back pressure or negative gauge pressure in the printhead 24 to prevent drooling during normal storage and operating conditions.

The embodiment in Fig. 2 depicts an ink container 12 and a printhead 24 that are each separately replaceable. The ink container 12 is replaced when exhausted and the printhead 24 is replaced at end of life. The method and apparatus of the present invention is applicable to inkjet printing systems 10 having other configurations than those shown in Fig. 2. For example, the ink container 12 and the printhead 24 can be integrated into a single print cartridge. The print cartridge which includes the ink container 12 and the printhead 24 is then replaced when ink within the cartridge is exhausted.

The ink container 12 and printhead 24 shown in Fig. 2 contain a single color ink. Alternatively, the ink container 12 can be partitioned into three separate chambers with each chamber containing a different color ink. In this case, three printheads 24 are required with each printhead in fluid communication with a different chamber within the ink container 12. Other configurations are also possible, such as more or less chambers associated with the ink container 12 as well as partitioning the printhead and providing separate ink colors to different partitions of the printhead or ejection portion 30.

Fig. 3 is an exploded view of the ink container 12 shown in Fig. 2. The ink container 12 includes an ink reservoir portion 34, the capillary member 40 and a lid 42 having an air inlet 38 for allowing entry of air into the ink reservoir 34. The capillary member 40 is inserted into the ink reservoir 34. The reservoir 34 is filled with ink as will be discussed in more detail with respect to Fig. 7, and the lid 42 is placed on the ink reservoir 34 to seal the reservoir. In the preferred embodiment, each of the height, width, and length dimensions indicated by H, W, and L, respectively, are all greater than one inch to provide a high capacity ink container 12.

In the preferred embodiment, the capillary member 40 of the present invention is formed from a network of fibers that are heat fused at points of contact. These fibers are preferably formed of a bi-component fiber having a sheath formed of polyester, such as polyethylene terephthalate (PET) or a co-polymer thereof, and a core material that is formed of a low cost, low shrinkage, high strength thermoplastic polymer, preferably polypropylene or polybutylene terephthalate.

The network of fibers is preferably formed using a melt blown fiber process.

For such a melt blow fiber process, it may be desirable to select a core material of a melt index similar to the melt index of the sheath polymer. Using such a melt blown fiber process, the main requirement of the core material is that it is crystallized when extruded, or it is crystallizable during the melt blowing process. Therefore, other highly crystalline thermoplastic polymers such as high density polyethylene terephthalate and polyamides such as nylon and nylon 66 can also be used.

Polypropylene is a preferred core material due to its low price and ease of processibility. In addition, the use of a polypropylene core material provides core strength, allowing the production of fine fibers using various melt blowing techniques.

The core material should be capable of forming a bond to the sheath material as well.

Fig. 4B is a greatly simplified representation of the network of fibers that form the capillary member 40, shown greatly enlarged in break away taken across lines 4B- 4B of the capillary member 40 shown in Fig 4A. The capillary member 40 is made up of a network of fibers with each individual fiber 46 being heat bonded or heat fused to other fibers at points of contact. The network of fibers 46 which make up the capillary member 40 can be formed of a single fiber 46 that is wrapped back upon itself, or formed of a plurality of fibers 46. The network of fibers form a self- sustaining structure having a general fiber orientation represented by arrow 44. The self-sustaining structure defined by the network of fibers 46 defines spacings or gaps between the fibers 46 which form a tortuous interstitial path. This interstitial path is formed to have excellent capillary properties for retaining ink within the capillary member 40.

In one preferred embodiment, the capillary member 40 is formed using a melt blowing process whereby the individual fibers 46 are heat bonded or melted together

to fuse at various points of contact throughout the network of fibers. This network of fibers, when fed through a die and cooled, hardens to form a self-sustaining three dimensional structure.

Fig. SA represents a cross section taken across lines 5A-5A in Fig. 4 to illustrate a cross section of an individual fiber 46. Each individual fiber 46 is a bi- component fiber, having a core 50 and a sheath 52. The size of the fiber 46 and relative portion of the sheath 52 and core 50 have been greatly exaggerated for illustrative clarity. The core material preferably comprises at least 30 percent and up to 90 percent by weight of the overall fiber content. In the preferred embodiment, each individual fiber 46 has, on average, a diameter of 12 microns or less.

Fig. 5B represents an alternative fiber 46 that is similar to the fiber 46 shown in Fig. 5A, except fiber 46 in Fig. 5B has a cross or x-shaped cross section instead of a circular cross section. The fiber 46 shown in Fig. 5B has a non-round or cross-shaped core 50 and a sheath 52 that completely cover the core material 50. Various other alternative cross sections can also be used, such as a tri-lobal or y-shaped fiber, or an h-shaped cross-section fiber, just to name a few. The use of non-round fibers results in an increased surface area at the fibrous surface. The capillary pressure and absorbency of the network of fibers 40 is increased in direct proportion to the wettable fiber surface. Therefore, the use of nonround fibers tends to improve the capillary pressure and absorbency of the capillary member 40.

Another method for improving the capillary pressure and absorbency is to reduce a diameter of the fiber 46. With a constant fiber bulk density or weight, the use of smaller fibers 46 improves the surface area of the fiber. Smaller fibers 46 tend to provide more uniform retention. Therefore, by changing the diameter of the fiber 46 as well as by changing the shape of the fiber 46, the desired capillary pressure for the printing system 10 can be achieved.

Fig. 6 illustrates the heat melding or heat fusing of individual fibers 46. Fig. 6 is a cross section taken across lines 66 at a point of contact between two individual fibers. Each individual fiber 46 has a core 50 and a sheath 52. At a point of contact between the two fibers 46, the sheath material 52 is melted together or fused with the sheath material of the adjacent fiber 46. The fusing of individual fibers is

accomplished without the use of adhesives or binding agents. Furthermore, individual fibers 46 are held together without requiring any retaining means, thereby forming a self-sustaining structure.

Fig. 7 is a schematic illustration of the process of filling ink into the ink container 12 of the present invention. The ink container 12 is shown with the capillary member 40 inserted into the reservoir 34. The lid 42 is shown removed. Ink is provided to the reservoir 34 by an ink container 54 having a supply of ink 56 contained therein. A fluid conduit 58 allows ink to flow from the ink supply 54 into the reservoir 34. As ink flows into the reservoir, ink is drawn into the interstitial spaces 48 between fibers 46 of the network of fibers 40 by the capillarity of this network of fibers. Once the capillary member 40 is no longer capable of absorbing ink, the flow of ink from the ink container 54 is ceased. The lid 42 is then placed on the ink reservoir 34.

Although the method of filling the ink reservoir 34 can be accomplished without the lid 42 as shown in Fig. 7, the reservoir 34 can be filled in other ways as well. For example the reservoir can alternatively be filled with the lid 42 in place, and ink is provided from the ink supply 54 through the air vent from the lid 42 and into the reservoir. Alternatively, the reservoir 34 can be inverted, and ink can be filled from the ink supply 54 through the fluid outlet 36 and into the ink reservoir 34. Once in the reservoir 34, ink is absorbed by the capillary member 40. The method of the present invention can be used during the initial filling of the ink reservoir 34 at the time of manufacture as a method to refill the ink container 12 once ink is exhausted.

The use of the capillary material 40 of the present invention, which is preferably a bi-component fiber having polypropylene core and a polyethylene terephthalate sheath, greatly simplifies the process of filling the ink container. The capillary material 40 of the present invention is more hydrophilic than the polyurethane foam that has been used previously as an absorbent material in thermal inkjet pens such as those disclosed in U. S. Patent No. 4,771,295, to Baker, et al., entitled"Thermal Inkjet Pen Body Construction Having Improved Ink Storage and Feed Capability"issued September 13,1988, and assigned to the assignee of the present invention. Polyurethane foam, in its untreated state, has a large ink contact

angle, therefore making it difficult to fill ink containers having polyurethane foam contained therein without using expensive and time consuming steps such as vacuum filling in order to wet the foam. Polyurethane foam can be treated to improve or reduce the ink contact angle ; however, this treatment, in addition to increasing manufacturing cost and complexity, tends to add impurities into the ink which tend to reduce printhead life or reduce printhead quality. The use of the capillary member 40 of the present invention has a relatively low ink contact angle, allowing ink to be readily absorbed into the capillary member 40 without requiring treatment of the capillary member 40.

Fig. 8 shows inkjet printing system 10 in operation. With the ink container 12 properly installed into the inkjet printing system 10, fluidic coupling is established between the ink container 12 and the inkjet printhead 24 by way of a fluid conduit 26.

The selective activation of the drop ejection portion 30 to eject ink produces a negative gauge pressure within the inkjet printhead 24. This negative gauge pressure draws ink retained in the interstitial spaces between fibers 46 within the capillary storage member 40. Ink that is provided by the ink container 12 to the inkjet printhead 24 replenishes the inkjet printhead 24. As ink leaves the reservoir through fluid outlet 36, air enters through a vent hole 38 to replace a volume of ink and exits the reservoir 34, thereby preventing the build up of a negative pressure or negative gauge pressure within the reservoir 34.

Fig. 9 is a schematic representation of an apparatus of the present invention for manufacturing the ink supply 12 of the present invention. The process begins with the formation of one or more fibers by the fiber forming apparatus 60. The fiber is then used to form the capillary member 40 which is inserted into the ink reservoir 34. The fiber forming apparatus 60, in a preferred embodiment, forms a bi-component fiber having a core material and a sheath material. In this preferred embodiment, the core material is a polypropylene core and the sheath is a polyester sheath, preferably polyethylene terephthalate. As schematically represented in the fiber forming apparatus 60, the core forming material 62 is enveloped with the sheath forming material 64 to form this bi-component fiber such as shown in Figs. SA and 5B. In a preferred embodiment, the fiber forming apparatus 60 is a device for melt blowing bi-

component fibers which are extruded into a high velocity air stream which attenuates the fibers, enabling the formation of fine bi-component fibers. The fibers 46 are deposited on a transport device 66 such as a conveyor belt. The individual fibers 46 are somewhat entangled but have a general fiber orientation along the transport direction as represented by arrow 44.

The web of fibers 46, which has a somewhat random orientation in two dimensions, is gathered and inserted into a forming die 68 that forms an extrusion 70 as shown in Fig. 10. The forming die 68 in a preferred embodiment is a hot air or steam die which heats the individual fibers 46 and forms them into a desired extrusion shape. The extrusion shown in Fig. 10 is a rectangular shape, having a height and width represented by"h"and"w"associated therewith. The extrusion 70 should have a proper shape to be inserted into the ink reservoir 34. Therefore, the ink reservoir 34 can be formed in any shape that is extrudable. The forming die 68 heats the individual fibers 46 so that individual fibers are heat bonded or melt bonded to each other at points of contact.

The extrusion 70 is then cooled by a cooling apparatus 72 to limit bonding of fibers 46 to thereby insure sufficient interstitial spaces 48 exist as shown in Fig. 4B.

In one preferred embodiment, the cooling apparatus 72 sprays a coolant such as water or air.

The cooled extrusion 70 is then provided to a cutting apparatus 76 that cuts the extrusion at discreet lengths. The cutting apparatus is a saw, blade or some conventional cutting device for cutting the extrusion 70. As shown in Fig. 10, the extrusion that is cut to a length"L"is suited to fit within the ink reservoir 34 having a corresponding length dimension. The fit of the extrusion 70 within the ink reservoir 34 will, in general, depend on whether compression of the capillary member 40 is desired to provide a capillary gradient within the capillary member 40. Therefore, the extrusion 70 will be cut slightly larger than the capillary reservoir 34 length if compression is required or cut equal to or slightly less than the capillary reservoir 34 length if no compression is required.

The cut extrusion represents the capillary member 40 which when cut is properly sized for the ink reservoir 34. The capillary member 40 is then inserted into

the ink reservoir 34 using the insertion device 78. The ink reservoir 34 is then filled with ink using a technique similar to that described with respect to Fig. 7.

The extrusion 70 that is formed by the forming die 68 can be formed with uniformly dispersed fibers that form uniform voids and spaces for ink containment.

Alternatively, the fibers can be oriented along the extrusion direction with a slight increasing density gradient from the center to the outside perimeter of the extrusion 70. This increasing density gradient tends to pull ink from the center and concentrate ink at the outside perimeter of the extrusion 70. This increasing density gradient within the extrusion or capillary member 40 can be modeled by the following Laplace equation: Pc = T, (cor 6*)<BR> Equationl : Ao where y represents the specific weight of the ink, Pc represents the capillary pressure, Twp represents the total wetted perimeter of fibers, B represents the contact angle of ink to individual fibers and Ao represents the open cross sectional area. The open cross sectional area is related to the area by Equation 2.

Equation 2: Ao = E x Area E represents the porosity of the capillary member 40. The porosity is related to the mass of the fiber and the total volume of the fiber by Equation 3.

Mass of Fibers<BR> Equation 3: E = Porosity =1- Density of Fibers Volume The mass of the fibers represents the total mass of the capillary member 40, the density of the fibers is the density of the fiber material itself, that is, the effective combined unit density of all polymers used and the total volume is the volume of the entire capillary member 40. In addition, the porosity is related to the density of the fibers and the density of the bulk by Equation 4. Equation 4 is derived by dividing the

numerator and denominator of equation 3 by the total volume of the capillary member 40.

Density of Bulk Equation 4: E = 1- Density of Fibers The density of the bulk in equation 4 represents the density of the entire capillary storage member 40, that is, the mass of the capillary storage member 40 divided by the volume of the capillary storage member 40 or mass per unit volume.

Capillary pressure is an attractive force that acts on the ink within the capillary storage member 40. From Equation 1, it can be seen that as the open cross sectional area declines, the capillary pressure increases, and ink will travel to the higher attractive area. Forming a density gradient in the capillary storage member 40 produces greater fiber density toward the perimeter than in the center of the capillary member 40. This greater fiber density reduces the cross sectional area toward the perimeter. Therefore, ink will tend to be drawn from the inside of the capillary storage member 40 toward the outside or perimeter of the capillary storage member 40. Positioning the fluid outlet 36 at the perimeter of the capillary storage member 40 allows ink to be drawn from interior locations with less capillary pressure to regions of higher capillary pressure near the perimeter where the fluid outlet 36 is positioned.

Thus, the ink reservoir 34 can be efficiently drained without stranding ink in interior locations of the capillary storage member 40.

Fiber density gradients can also be achieved by compressing the capillary storage material 40. Compression tends to decrease the open cross sectional area in the compressed area, thus increasing capillary pressure in the region causing the region to preferentially fill with ink. Locally compressing the capillary storage member 40 near the fluid outlet tends to increase capillarity which tends to draw ink toward the fluid outlet 36. An advantage of the use of a capillary storage member 40 formed from individual fibers 46 is the ability to change capillary pressure, without significantly affecting the porosity, simply by changing diameter of individual fibers 46. Referring to Equation 1 and Equation 4, by reducing fiber diameter and increasing

the number of fibers per unit volume, the total wetted perimeter of fibers is increased, and consequently the capillary pressure is increased, but the density of the bulk and the porosity may be unchanged. In contrast, felting polyurethane to increase its capillary pressure increases the amount of solid material per unit volume, increasing density of bulk and decreasing porosity.

In one preferred embodiment, the ink reservoir 34 is formed to have a drafted geometry or taper such that the perimeter of the opening is larger than the perimeter of the bottom portion of the ink reservoir. The fluid outlet 36 is formed in the bottom of the ink reservoir 34. The capillary storage member 40 is then formed to fit into the opening of the ink reservoir 40 and compress against the sides of the bottom of the ink container during insertion. The amount of interference at the bottom of the ink reservoir 34 determines the amount of localized compression. This compression of the capillary storage member 40 adjacent the bottom of the ink reservoir 34 tends to create increased capillarity, drawing ink toward the bottom of the ink reservoir 40 whereupon ink can flow from the fluid outlet 34.

Fig. 11 depicts the overall method of manufacturing the ink container 12 of the present invention. The ink reservoir 40 is formed having length, width and height dimensions as represented by step 80. These length, width and height dimensions are selected to be suitable for the inkjet printing system 10. Fibers are formed for use in the capillary storage member 40 as represented by step 82. These fibers are fused together to form a rectangular extrusion having width and height dimensions as represented by step 84. Fibers within the extrusion 70 are heat melted or heat fused together at points of contact. The extrusion 70 is then cooled to form a self-sustaining structure as represented by step 86. The extrusion 70 is cut to a length dimension as represented by step 88. The cut extrusion 70 is inserted into the ink reservoir 34 as represented by step 90. Finally, the ink reservoir 34 is filled with ink as represented by step 92.

The method and apparatus of the present invention has several important advantages over the use of some previously used techniques such as the use of polyurethane foam as the capillary storage member 40. Use of the heat fused fiber that is extruded is easier to insert into the ink reservoir 34 than polyurethane foam.

Polymer fiber materials have lower coefficients of friction than most foam, thus making the material easier to handle using automated equipment. High coefficient of friction material such as foam is difficult to insert or fill into rectangular shaped containers because the corners and edges tend to roll up wherever the foam touches the container walls, thus failing to fill corners. Failing to fill corners with foam tends to strand ink in these corners, thereby reducing the ink usage efficiency. In contrast, use of a polymer fiber material tends to slide in easily and completely fill the corners of the ink reservoir 34. In addition, use of polymer fiber materials allows the insertion operation to be much simpler and is therefore well-suited to high volume manufacturing.

Polyester fiber materials for use in the capillary storage member 40 are also easier to handle because this material can be delivered in the form of a long extrusion, referred to as bar stock, which is then cut and inserted into the ink reservoir 34. In addition, the use of a polyester fiber as the capillary storage member 40 enables the use of a wider range of ink container sizes and shapes. The ink reservoir shape 34 can be nearly any extrudable shape.

The polyester fiber storage member 40 of the present invention can have dimensions greater than two inches or more. In contrast, use of a foam material as the capillary storage member 40 requires felting to achieve higher capillary pressures.

The felting operation tends to flatten the foam, making the pores smaller. The felting process tends to be limited to foam thicknesses of less than one inch because the heat and pressure required to penetrate thicknesses greater than one inch tend to break down foam, making it no longer suitable as a capillary storage member 40.

The ink container 12 makes use of a relatively low cost bi-component fiber 46 that is preferably comprised of a polypropylene core and a polyethylene terephthalate sheath. Individual fibers are heat bonded at points of contact to form a free standing structure having good capillarity properties. The fiber 46 material is chosen to be naturally hydrophilic to inkjet inks. The particular fiber 46 material is chosen to have a surface energy that is greater than a surface tension of the inkjet inks. The use of a naturally hydrophilic capillary storage member 40 allows faster ink filling of the reservoir 34 without requiring special vacuum filling techniques frequently used in

less hydrophilic materials such as polyurethane foam. Materials that are less hydrophilic often require surfactants to be added to the ink or treatment of the capillary storage member to improve wettability or hydrophilicity. The surfactants tend to alter the ink composition from its optimum composition.

In addition, the fiber 46 material selected for the capillary storage member 40 is less reactive to inkjet inks than other materials frequently used in this application.

In the case where ink components react to the capillary storage member, the ink that is initially put into the foam is different from the ink that is removed from the foam to replenish the printhead 24. This contamination to the ink tends to result in reduced printhead life and lower print quality.

Finally, the capillary storage member of the present invention makes use of extrusion polymers that have lower manufacturing costs than foam type reservoirs. In addition, these extrusion polymers tend to be more environmentally friendly and consume less energy to manufacture than the previously used foam type storage members.