Ink reservoir with a pressure adjusting device

Information

  • Patent Grant
  • 6533403
  • Patent Number
    6,533,403
  • Date Filed
    Thursday, January 3, 2002
    22 years ago
  • Date Issued
    Tuesday, March 18, 2003
    21 years ago
Abstract
An ink reservoir has an air bag, a housing with an ink reservoir, an elastic constraining device for constraining the air bag to prevent the seepage of ink by way of back-pressure, an active shaft movably installed in the ink reservoir, and a plugging device engaged with the active shaft for plugging a second vent of the housing. When consumption of ink in the ink reservoir causes the air bag to expand to a predetermined degree, the air bag moves the active shaft, the active shaft pulls the plugging device out of the second vent, and air enters into the ink reservoir to reduce the volume of the air bag.
Description




BACKGROUND OF INVENTION




1. Field of the Invention




The present invention relates to a pressure adjusting device, and more particularly, to a pressure adjusting device for controlling the pressure within the ink reservoir of an ink-jet print cartridge.




2. Description of the Prior Art




With the increasing in popularity of personal computers, and a correspondingly increasing demand for personal image output, ink-jet printing devices have become the most common computer output/printing devices for individuals, families, and companies. Such devices offer a price and printing quality that is attractive for users. Ink-jet printing generally relies on the controlled delivery of ink droplets from an ink-jet print cartridge ink reservoir to a print medium. Among the printing methods for delivering these ink droplets from the ink reservoir to the print head, drop-on-demand printing is a commonly used method. The drop-on-demand method typically uses thermal bubbles or piezoelectric pressure wave mechanisms. The thermal bubble type print head comprises a thin-film resistor that is heated to cause sudden vaporization of a small portion of the ink. The vapid expansion of the ink vapor forces a small droplet of ink through a print head nozzle. Although drop-on-demand printing is ideal for sending ink droplets from an ink reservoir to the print head, some mechanisms must be included to prevent ink from leaking out of the print head while the print head is inactive. This kind of controlling mechanism usually provides a slight back-pressure at the print head to prevent ink from leaking out from the print head whenever the print head is inactive. The term “back-pressure” indicates a partial vacuum within the ink reservoir. The back-pressure is defined in a positive sense so that increasing the back-pressure means that the degree of partial vacuum has increased within the ink reservoir.




Although increasing the back-pressure can prevent ink from leaking out from the print head, the back pressure must not be so high that the print head can not overcome the back-pressure to eject ink droplets. Furthermore, as ambient air pressure decreases, the necessary back pressure that prevents ink from leaking out from the print head needs to be correspondingly larger. Accordingly, back-pressure within the ink-jet print cartridge has to be regulated whenever the ambient pressure drops. Also, the pressure within the ink reservoir is subjected to what may be termed “operational effects”. This refers to the depletion of ink from the ink reservoir, which tends to increase the back-pressure within the ink reservoir. Unless the back-pressure is regulated properly, the print head will eventually fail because the back-pressure becomes too great for the print to overcome.




In the prior art, a “regulator” in the ink reservoir controls the reservoir back-pressure. The regulator is usually an elastic air bag, and the elastic air bag typically connects to the external atmosphere via a vent. When ink is consumed, for example, ambient air will enter into the elastic air bag through the vent so that the volume of the elastic air bag increases to decrease the reservoir volume, and so reduce the back-pressure to a value that is within the operational range of the print head. Another example can be found in a drop of ambient pressure. In such cases, the volume of the elastic air bag changes to increase the reservoir volume to thereby increase the back-pressure to a level that prevents ink leakage from the print head.




A major shortcoming of the prior art elastic-air-bag regulator is a limitation in a maximum volume of the elastic air bag. As ink is gradually jetted from the print head, the elastic air bag will eventually reach its maximum extent, and the reservoir volume can therefore not be adjusted further. The continuous reduction of ink volume in the reservoir causes the back-pressure to exceed the operational back-pressure range. When this occurs, the print head can no longer overcome the back-pressure to eject ink from the print head, and the remaining ink within the ink reservoir cannot be used completely and so is wasted.




Another type of prior art that is used to control the back-pressure within an ink reservoir is a bubble generator. As disclosed in U.S. Pat. No 5,526,030, which is included herein by reference, the bubble generator is set in the ink reservoir and has an orifice through which ambient air can enter the reservoir. The dimensions of the orifice, when designed appropriately, cause ink to gather in the orifice to seal off the reservoir by way of capillary effects. When the back-pressure within the ink reservoir rises to a predetermined degree, external air overcomes the liquid seal and enters into the ink reservoir as a bubble. Thus, the back-pressure within the ink reservoir decreases. Additionally, when the bubble enters into the ink reservoir, capillary effects again take over and re-establish the liquid seal to prevent bubbles from continuously entering. However, the bubble generator described above uses surface the tension of the ink and static pressure of the ink column to control bubbles entering the ink reservoir. Therefore, the primary shortcomings of the prior art described above are: 1. Different inks have different surface tensions, and so the bubble generator needs to be redesigned for various types of ink; 2. As the level of ink within the reservoir gradually drops, the static pressure of the ink column decreases, leading to the entrance of air bubbles at smaller back pressures; 3. The gap between the sphere and the orifice has to be precisely engineered to permit the entrance of air bubbles at the correct reservoir back-pressure. This increases difficulties in fabricating the reservoir of an ink-jet cartridge.




SUMMARY OF INVENTION




It is therefore a primary objective of the present invention to provide a pressure adjusting device capable of controlling the pressure within the ink reservoir of an inkjet cartridge.




Another objective of the present invention is to provide a simple and reliable pressure adjusting device.




According to claimed invention, an ink-jet cartridge comprises an ink reservoir for storing ink. The reservoir has a first vent, a second vent, and an opening. The opening is installed at a bottom end of the reservoir and is connected to the print head. An air bag is installed within the ink reservoir and connected to the first vent. The first vent enables external air to enter into the air bag, enabling the air bag to adjust internal pressure within the ink reservoir. An elastic constraining device is installed in the ink reservoir for constraining air in the air bag, and so to prevent the ink in the ink reservoir from leaking through the opening. An active shaft is movably installed in the ink reservoir. A plugging device engages with the active shaft to plug the second vent of the housing. Consumption of the ink within the ink reservoir causes the air bag to expand. When the air bag expands to a predetermined degree, the air bag moves the active shaft, the active shaft pulls the plugging device out of the second vent, and air enters into the ink reservoir through the second vent to reduce the volume of the air bag. When the air bag steps moving the active shaft, the active shaft returns to an original position and the plugging device plugs the second vent again.




It is an advantage of the present invention that the pressure adjusting device can adjust internal pressure within the ink reservoir.




It is a further advantage of the present invention that the structure is simple and reliable. Even if ambient air pressure changes, it still works normally and isn't affected by operational effects of the ink reservoir.




These and other objectives and advantages of the present invention will no doubt become obvious to those of ordinary skill in the art after having read the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.











BRIEF DESCRIPTION OF DRAWINGS





FIG. 1

is a perspective view of a present invention ink cartridge.





FIG. 2

is a cross-sectional diagram of a present invention ink reservoir along a line


2





2


of FIG.


1


.





FIG. 3

is a detailed side view of an active shaft and plugging device shown in FIG.


2


.





FIG. 4

is a detailed side view of the plugging device of

FIG. 3

when pulled out by the active shaft shown.





FIG. 5

is a diagram of an active shaft and plugging device for an alternative embodiment present invention ink jet cartridge.











DETAILED DESCRIPTION




Please refer to FIG.


1


.

FIG. 1

is a perspective view of a present invention ink reservoir


20


. The ink reservoir


20


comprises a housing


11


within which is stored ink. A top


12


of the housing


11


has a first vent


30


, and a fill opening


16


. A bottom


14


of the housing


11


has a second vent


50


and an ink-access opening


200


. Ink is poured into the ink reservoir


20


through the fill opening


16


. When the ink reservoir


20


is full, a seal cap


18


is used to seal the fill opening


16


. The ink reservoir


20


delivers ink through the ink-access opening


200


. An ink jet print head (not shown) is attached to the ink-access opening


200


, as well as circuitry (not shown) related to the ink jet print head. The circuitry controls the ink-jet print head when jetting ink to perform a printing operation.




Please refer to FIG.


2


.

FIG. 2

is a cross-sectional diagram of the ink reservoir


20


along the line


2





2


shown in FIG.


1


. As above, the ink reservoir


20


is used to store ink and to provide ink through the ink-access opening


200


. To prevent ink leaking from the ink-access opening


200


, the ink reservoir


20


must remain within a predetermined back-pressure range. As mentioned above, although there are several prior art mechanisms to maintain back-pressure, such mechanisms have shortcomings. Therefore, to overcome the shortcomings of these prior art mechanisms, the present invention ink reservoir


20


uses a new back-pressure controlling mechanism. The back-pressure controlling mechanism uses an air bag


32


, an elastic constraining device


34


, an active shaft


40


, and a plugging device


100


, all of which are within the ink reservoir


20


. The air bag


32


is a sealed hollow bag so as to be isolated from fluid in the ink reservoir


20


. The air bag


32


connects to the first vent


30


on the top


12


of the housing


11


by way of a ventilation pipe, and external air passes in and out of the air bag


32


through the first vent


30


via the ventilation pipe. The elastic constraining device


34


comprises a press board


36


and a spring


38


. One end of the spring


38


is fixed on a wall of the housing


11


, and the other is fixed on the press board


36


, so that the spring


38


applies pressure to the air bag


32


through the press board


36


. The active shaft


40


is fixed on the bottom of the housing


14


, and is an elastic element.




Please refer to FIG.


3


.

FIG. 3

is a detailed structural diagram of the active shaft


40


and the plugging device


100


shown in FIG.


2


. The active shaft


40


is set in the ink reservoir


20


on the bottom of the housing


14


. An adhesive


62


is used to attach the plugging device


100


to a side of the active shaft


40


so that the plugging device


100


is engaged with the active shaft


40


. The plugging device


100


is used to plug the second vent


50


to prevent external air from entering into the ink reservoir


20


through the second vent


50


. As mentioned above, the active shaft


40


is an elastic element, so the active shaft


40


elastically pushes the plugging device


100


towards the second vent


50


. In this manner, the plugging


100


contacts an upper edge of the second vent


50


and so plugs the second vent


50


. As shown in

FIG. 3

, the plugging device


100


has a spherical shape, with a radius of D


1


. The second vent


50


has a round cross section, with a radius of D


2


. D


1


is greater than D


2


. The plugging device


100


, therefore, plugs the second vent


50


so that external air cannot enter into the ink reservoir


20


through the second vent


50


when the plugging device


100


is in contact with the upper edge of the second vent


50


.




As mentioned above, the ink reservoir


20


must maintain a predetermined back-pressure to ensure that the print head works properly. The working principle of regulating back-pressure in the present invention ink reservoir


20


is described in the following. As shown in

FIG. 2

, when the ink reservoir


20


is initially filled with ink, the air bag


32


is pressed to a right wall of the ink reservoir


20


along a second direction


54


(as shown, to the right) by the press board


36


due to the spring


38


. The press board


36


does not contact the active shaft


40


at this point. When ink within the ink reservoir


20


is provided to the print head (not shown) through the ink-access opening


200


, the air bag


32


imports external air through the first vent


30


and expands. As the air bag


32


expands along a first direction


52


(as shown, to the left), the spring


38


continues to increase pressure along the second direction


54


upon the air bag


32


through the press board


36


. The volume of the ink reservoir


20


thus reduces as the air bag


32


expands, keeping the reservoir back-pressure within an adequate level such that the print head is able to continue ejecting ink from the reservoir


20


.




Please refer to FIG.


4


.

FIG. 4

is a diagram of the plugging device


100


when pulled out of the second vent


50


by the active shaft


40


shown in FIG.


2


. As mentioned above, as the ink in the ink reservoir


20


is consumed, the air bag


32


expands along a first direction


52


, and the press board


36


is simultaneously pushed by the air bag


32


towards the left of the diagram (direction


52


). When the air bag


32


expands to a predetermined degree, as shown in

FIG. 4

, the press board


36


contacts and pushes the active shaft


40


. At this time, the active shaft


40


is pushed upward because of the force upon the active shaft


40


by the press board


36


along the first direction


52


, and the active shaft


40


pulls the plugging device


100


from the top of the second vent


50


. When the plugging device


100


is pulled out of the second vent


50


by the active shaft


40


, the plugging device


100


and an arc-shaped lip


66


of the second vent


50


are no longer in contact with each other, thus form an opening through which external air can enter. At this time, external air enters into the ink reservoir


20


through the second vent


50


. With external air entering into the ink reservoir


20


, the fluid pressure within the ink reservoir


20


(i.e. the total pressure of air and ink in the ink reservoir) increases. The difference between internal and external pressure of the ink reservoir


20


thus reduces, and so back-pressure within the ink reservoir


20


reduces. The force resisting expansion of the air bag


32


on the press board


36


strengthens. Finally, the force acting on the press board


36


and resisting the expansion of the air bag


32


exceeds the expanding force of the air bag


32


along the first direction


52


, so that the press board


36


is pushed to the right (direction


54


) and disengages from the active shaft


40


. With the force that the press board


36


applies on the active shaft


40


no longer present, the active shaft


40


returns to an original position because of its elasticity and pushes the plugging device


100


towards the second vent


50


. The plugging device


100


thus once again plugs the second vent


50


. Of course, as the air bag


32


expands to a predetermined degree with the consumption of ink, the above process of opening/closing the second vent


50


happens repeatedly until the ink supply is exhausted. Therefore, a primary objective of the present invention ink reservoir


20


is for the air bag


32


to push on the active shaft


40


by way of the press board


36


due to expansion. When this happens, the active shaft


40


pulls the plugging device


100


from the second vent


50


to permit external air to flow into the ink reservoir


20


, and thus keep the back-pressure in the ink reservoir


20


within an adequate range until the ink is finally exhausted.




As shown in

FIG. 3

, the housing


11


forms a lip


66


around the top of the second vent


50


. A surface of the lip


66


and a surface of the plugging device


100


meet at a special angle. This special angle enables the plugging device


100


to plug and unplug from the second vent


50


more easily. Also, as mentioned above, an adhesive


62


is used to attach the plugging device


100


to the active shaft


40


, so that when the active shaft


40


is pushed upward by the press board


36


, the plugging device


100


moves upward with the active shaft


40


to unplug the second vent


50


. The active shaft


40


and the plugging device


100


are made of metal. The adhesive can be a solder


62


that fixes the plugging device


100


onto the active shaft


40


. Regardless of whether the present invention utilizes solder or another standard adhesive, of key importance is that the air bag


32


moves the active shaft


40


when the air bag


32


expands to a predetermined degree because of ink consumption, or rising external air pressure. The plugging device


100


is pulled from the second vent


50


by the active shaft


40


, enabling external air to enter into the ink reservoir


20


.




Please refer to FIG.


5


.

FIG. 5

is a diagram of an active shaft


130


and a plugging device


140


of an alternate present invention ink reservoir


20


. In this embodiment, the active shaft


130


comprises a device hole


142


, and an end of the plugging device


140


is set in the device hole


142


, so that the plugging device


140


is fixed on the active shaft


130


. Furthermore, the plugging device


140


comprises an arc-shaped surface


144


, with a radius of curvature of D


3


. As mentioned above, the second vent


50


is a round hole, and its radius is D


2


. The radius of curvature D


3


of the arc-shaped surface


144


is larger than the radius D


2


of the round hole, so the plugging device


140


is capable of plugging the second vent


50


by way of the arc-shaped surface


144


. Similarly, the surface of the lip


66


and the arc-shaped surface


144


of the plugging device


140


meet at a special angle that permits the plugging device


140


to engage and disengage with the second vent


50


more easily.




The active shaft


130


and the plugging device


140


together form a complete structure to pull the plugging device


140


from the second vent


50


when the active shaft


130


is pushed upward.




In the comparison with the prior art, such as the bubble generator disclosed in U.S. Pat. No. 5,526,030, the present invention utilizes a mechanical controlling mechanism to control a vent to accept external air to maintain back-pressure in an ink reservoir. The controlling mechanism of the prior art, however, utilizes surface tension and static pressure of the ink column. The prior art structure is thus more complicated than that of the present invention, which increases the difficulty of producing the ink cartridge. Additionally, as noted before, when different types of ink are used, the surface tension of the ink may vary, and so the controlling mechanism needs to be redesigned. The present invention design, however, works independently of the type of ink used. The back-pressure controlling mechanism of the present invention ink reservoir


20


pushes on the active shaft


40


by way of the press board


36


due to expansion of the air bag


32


. This causes the active shaft


40


to pull the plugging device


100


from the second vent


50


, permitting external air to enter into the ink reservoir


20


. The back-pressure controlling mechanism of the present invention ink reservoir


20


continues working normally until the ink is exhausted, and does not need to be redesigned for each type of ink. The structure of the back-pressure regulating mechanism of the present invention ink reservoir is simple and easy to produce, manufacture, and assemble.




Those skilled in the art will readily observe that numerous modifications and alterations of the device may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.



Claims
  • 1. An ink reservoir comprising:a housing with an ink reservoir for storing ink, the housing having a first vent, a second vent, and an opening, the opening installed at a bottom end of the housing and connected to the ink reservoir; an air bag installed in the ink reservoir and connected to the first vent, the first vent enabling external air to enter into the air bag, the air bag adjusting internal pressure within the ink reservoir; an elastic constraining device installed in the ink reservoir for constraining air in the air bag to prevent the ink in the ink reservoir from leaking through the opening; a plugging device for plugging the second vent of the housing; and an active shaft movably installed in the ink reservoir and connected to the plugging device for pulling the plugging device out of the second vent of the housing; wherein comsumption of the ink in the ink reservoir causes the air bag to expand, and when the air bag expands to a predetermined degree, the air bag moves the active shaft, the active shaft pulls the plugging device out of the second vent, and air enters into the ink reservoir through the second vent to reduce the volume of the air bag, and when the air bag stops moving the active shaft, the active shaft returns to an original position and the plugging device plugs the second vent.
  • 2. The ink reservoir of claim 1 wherein the plugging device is fixed on the active shaft.
  • 3. The ink reservoir of claim 2 wherein the active shaft comprises a device hole, and an end of the plugging device is set in the device hole so that the plugging device is fixed on the active shaft.
  • 4. The ink reservoir of claim 1 wherein the active shaft is an elastic element, and when the air bag expands to the predetermined degree, the air bag pushes the elastic element so that the elastic element pulls the plugging device out of the second vent, and when the air bag contracts, the elastic element returns to an original form and pushes the plugging device to the second vent to plug the second vent.
  • 5. The ink reservoir of claim 1 wherein the plugging device has a spherical shape, the second vent is a round hole, and a radius of the plugging device is larger than a radius of the second vent so that the plugging device plugs the second vent.
  • 6. The ink reservoir of claim 1 wherein the plugging device comprises an arc-shaped surface, the second vent is a round hole, and a radius of curvature of the arc-shaped surface is larger than a radius of the round hole so that the plugging device plugs the round hole.
  • 7. The ink reservoir of claim 1 wherein the active shaft and the plugging device together form a monolithic structure.
  • 8. The ink reservoir of claim 1 wherein an adhesive is used to adhere the plugging device to the active shaft.
  • 9. The ink reservoir of claim 1 wherein the active shaft and the plugging device are made of metal, and the plugging device is welded onto the active shaft.
  • 10. An ink reservoir comprising:a housing with an ink reservoir for storing ink, the housing having a first vent and a second vent; a print head installed at a bottom end of the housing and connected to the ink reservoir; an air bag installed in the ink reservoir and connected to the first vent, the first vent enabling external air to enter into the air bag, the air bag adjusting internal pressure within the ink reservoir; an elastic constraining device installed in the ink reservoir for constraining air in the air bag to prevent the ink in the ink reservoir from leaking through the print head; a plugging device for plugging the second vent of the housing; and an active shaft movably installed in the ink reservoir and connected to the plugging device for pulling the plugging device out of the second vent of the housing; wherein consumption of the ink in the ink reservoir causes the air bag to expand, and when the air bag expands to a predetermined degree, the air bag moves the active shaft, the active shaft pulls the plugging device out of the second vent, and air enters into the ink reservoir through the second vent to reduce the volume of the air bag, and when the air bag stops moving the active shaft, the active shaft returns to an original position and the plugging device plugs the second vent.
  • 11. The ink reservoir of claim 10 wherein the plugging device is fixed on the active shaft.
  • 12. The ink reservoir of claim 11 wherein the active shaft comprises a device hole, and an end of the plugging device is set in the device hole so that the plugging device is fixed on the active shaft.
  • 13. The ink reservoir of claim 10 wherein the active shaft is an elastic element, and when the air bag expands to the predetermined degree, the air bag pushes the elastic element so that the elastic element pulls the plugging device out of the second vent, and when the air bag contracts, the elastic element returns to an original form and pushes the plugging device to the second vent to plug the second vent.
  • 14. The ink reservoir of claim 10 wherein the plugging device has a spherical shape, the second vent is a round hole, and a radius of the plugging device is larger than a radius of the second vent so that the plugging device plugs the second vent.
  • 15. The ink reservoir of claim 10 wherein the plugging device comprises an arc-shaped surface, the second vent is a round hole, and a radius of curvature of the arc-shaped surface is larger than a radius of the round hole so that the plugging device plugs the round hole.
  • 16. The ink reservoir of claim 10 wherein the active shaft and the plugging device together form a monolithic structure.
  • 17. The ink reservoir of claim 10 wherein an adhesive is used to adhere the plugging device to the active shaft.
  • 18. The ink reservoir of claim 10 wherein the active shaft and the plugging device are made of metal, and the plugging device is welded onto the active shaft.
Priority Claims (1)
Number Date Country Kind
90100380 A Jan 2001 TW
US Referenced Citations (5)
Number Name Date Kind
5453772 Aono et al. Sep 1995 A
6186620 Hsieh et al. Feb 2001 B1
6203146 Pawlowksi, Jr. et al. Mar 2001 B1
6213598 Hou et al. Apr 2001 B1
20020047883 Hou et al. Apr 2002 A1