The present invention relates to ink jet printers and, more particularly, to pumping systems used to deliver ink from the ink source to the print head.
Inkjet printers are one of the most widely used print technologies, providing low cost, high speed, and high resolution printing. In order to print at high resolutions while maintaining high speed of operation, it is desired that a steady flow of ink is rapidly delivered to the print head. Various means have been employed in the art to deliver ink to the print head. Some ink jet systems, particularly the low-end models, have used disposable ink supply cartridges mounted on the print carriage, directly coupled to the print head. Other ink jet systems have used an electrically-powered pump to deliver the ink from a fixed supply tank to the print heads located on the print carriage.
U.S. Pat. Nos. 6,145,971 and 6,431,694 describe ink jet systems employing an ink pump driven by the motion of the print carriage; and, more specifically, driven by a passive inertial mass that moves in reaction to the acceleration of the print carriage. Such passively-driven ink pumps represent an important step in ink jet technology because they provide a mechanically simple pump that can be mounted directly on the print carriage. One of the shortcomings of this passively-driven ink pump seen in the prior art is the mass and, hence, the volume required to produce a pump that can achieve the pressures and flow rates required for commercial ink jet printers is too large. In order to supply enough force to generate the required pump capacity, the inertial mass as implemented in the prior art must be sufficiently large that it presents significant design limitations to the installation of the pump on the print carriage. If multiple ink pumps are required, as is necessary in a color printer, it becomes substantially difficult and impractical to fit the ink pumps on the print carriage due to their size.
In light of these shortcomings, there is a desire for a passive ink jet pump driven by an inertial mass that is smaller and lighter than those previously developed.
Exemplary embodiments of the present invention employ the inertial motion of a mass coupled to an ink jet printer's print carriage to drive a displacement-type ink pump located on the carrier. The pump delivers the ink, which is stored off the carrier, to the print heads. In accordance with the present invention, a mechanical linkage, such as a lever mechanism, is employed to couple the inertial mass to the pump's actuator, which in the exemplary embodiments includes a diaphragm and/or “displacement volume.” The mechanical advantage provided by this mechanical linkage allows a sufficiently smaller inertial mass to achieve the required pump capacity, thus enabling multiple ink supply pumps to be fitted to the print head carrier if desired.
It is a first aspect of the invention to provide a print carriage and ink supply system for a printer that includes: a print carriage adapted for lateral reciprocation along a print medium within a printer; an ink pump including an ink inlet in fluid communication with an ink source, an ink outlet in fluid communication with the print head on the print carriage, and a pump actuator for at least initiating displacement of ink through the ink pump upon actuation; and a pendulum pivotally coupled to the print carriage for pivotal movement with respect to the print carriage in reaction to acceleration of the print carriage laterally along the print medium, where the pendulum is mechanically linked to the pump actuator. In such a system the pendulum actuates the pump at least upon certain accelerations of the print carriage laterally along the print medium. In more detailed embodiment the pendulum is pivotally coupled to the print carriage at a pivot point and includes an internal mass arm extending below the pivot point and an actuator arm extending above the pivot point, where the actuator arm is mechanically linked to the pump actuator. In a further detailed embodiment the actuator arm is coupled to a piston carried on the ink pump and the piston is in contact with the pump actuator along at least a portion of the piston's reciprocation path. In yet a further detailed embodiment, the pump is a displacement type pump. In yet a further detailed embodiment, the pump is a diaphragm pump and the pump actuator includes a pump diaphragm enclosing at least a portion of a displacement volume of the diaphragm pump. In yet a further detailed embodiment, the diaphragm pump includes a pump housing containing: the displacement volume, the pump diaphragm, the pump inlet in fluid communication with the displacement volume, and the pump outlet in fluid communication with the displacement volume. In yet a further detailed embodiment, the pump housing is coupled to the print carriage, the pump housing contains the piston, and the pendulum is pivotally coupled to the pump housing. In yet a further detailed embodiment, the pump housing contains a first check valve in fluid communication with the valve inlet and a second check valve in fluid communication with the valve outlet. In yet a further detailed embodiment, the first and second check valves comprise reed valves.
In an alternate detailed embodiment of the first aspect of the present invention, the pendulum is pivotally coupled to the print carriage at a pivot point and includes an internal mass arm extending below the pivot point and an actuator arm extending above the pivot point, where the actuator arm is mechanically linked to the pump actuator, and the inertial mass arm of the pendulum is substantially longer and heavier than the actuator arm of the pendulum. In a further detailed embodiment, the inertial mass arm has a mass of approximately 2 grams to approximately 200 grams. In yet a further detailed embodiment, the ratio of pivot distance of travel between the inertial mass arm and the actuator arm is between approximately 0.5 and approximately 10 to one.
It is a second aspect of the present invention to provide a print carriage and ink supply system for a printer that includes: a print carriage adapted for lateral reciprocation along a print medium within a printer, where the print carriage includes at least one print head; an ink pump including an ink inlet in fluid communication with an ink source, an ink outlet in fluid communication with the print head, and a pump actuator for at least initiating displacement of ink through the ink pump upon actuation; and an inertial mass coupled to the print carriage for reciprocating movement with respect to the print carriage in opposing reaction to acceleration of the print carriage laterally along the print medium; where the inertial mass is indirectly linked to the pump actuator by a mechanical linkage such that the combination of the inertial mass and mechanical linkage actuates the pump at least upon certain accelerations of the print carriage laterally along the print medium. In a more detailed embodiment, the inertial mass is provided on a first arm of a pendulum pivotally coupled to the print carriage, and the pendulum is a component of the mechanical linkage. In a further detailed embodiment, the mechanical linkage includes a piston pivotally coupled to an opposing arm of the pendulum, the piston is mounted for reciprocation along a piston path on the print carriage, and the piston path includes the pump actuator. In yet a further detailed embodiment, the pump is a displacement type pump. In yet a further detailed embodiment, the pump is a diaphragm pump and the pump actuator includes a pump diaphragm enclosing at least a portion of a displacement volume of the diaphragm pump. In yet a further detailed embodiment, the diaphragm pump includes a pump housing containing: the displacement volume, the pump diaphragm, the pump inlet in fluid communication with the displacement volume, and the pump outlet in fluid communication with the displacement volume. In yet a further detailed embodiment, the pump housing is coupled to the print carriage, the pump housing contains the piston, and the pendulum is pivotally coupled to the pump housing. In yet a further detailed embodiment, the pump housing contains a first check valve in fluid communication with the valve inlet and a second check valve in fluid communication with the valve outlet. In yet a further detailed embodiment, the first and second check valves comprise reed valves.
In an alternate detailed embodiment of the second aspect of the present invention, the pendulum is pivotally coupled to the print carriage at a pivot point and includes an internal mass arm extending below the pivot point and an actuator arm extending above the pivot point, where the actuator arm is mechanically linked to the pump actuator, and the inertial mass arm of the pendulum is substantially longer and heavier than the actuator arm of the pendulum. In a further detailed embodiment, the inertial mass arm has a mass of approximately 2 grams to approximately 200 grams. In yet a further detailed embodiment, the ratio of pivot distance of travel between the inertial mass arm and the actuator arm is between approximately 0.5 and approximately 10 to one.
In another alternate detailed embodiment of the second aspect of the present invention, the inertial mass extends downwardly with respect to the print carriage and reciprocates a swinging motion. In a further detailed embodiment, the inertial mass extends below the print carriage.
In another alternate detailed embodiment of the second aspect of the present invention, the system further includes a plurality of the ink pumps for a corresponding plurality of printer inks. In a more detailed embodiment, the system further includes a corresponding plurality of the inertial mass and mechanical linkage combinations for the respective plurality of the ink pumps. Alternatively, the inertial mass is indirectly linked to each of the pump actuators by the mechanical linkage.
It is a third aspect of the present invention to provide a printer that includes: a printer housing; a drive assembly provided in the printer housing for driving a print medium through the printer housing; a print carriage adapted for lateral reciprocation along a print medium carried by the drive assembly within the printer housing, where the print carriage includes at least one print head; a controller for coordinating the operations of the drive assembly and print carriage with respect to each other; an ink pump provided in the printer housing, including an ink inlet in fluid communication with an ink source, an ink outlet in fluid communication with the print head, and a pump actuator for at least initiating displacement of ink through the ink pump upon actuation; and an inertial mass coupled to the print carriage for reciprocating movement with respect to the print carriage in opposing reaction to acceleration of the print carriage laterally along the print medium; where the inertial mass is indirectly linked to the pump actuator by a mechanical linkage such that the combination of the inertial mass and mechanical linkage actuates the pump at least upon certain accelerations of the print carriage laterally along the print medium.
Exemplary embodiments of the present invention employ the inertial motion of a mass coupled to an ink jet printer's print carriage to drive a displacement-type ink pump located on the carrier. The pump delivers the ink, which is stored off the carrier, to the print heads. In accordance with the present invention, a mechanical linkage, such as a lever mechanism, is employed to couple the inertial mass to the pump's actuator, which in the exemplary embodiments includes a diaphragm and/or “displacement volume.” The mechanical advantage provided by this mechanical linkage allows a sufficiently smaller inertial mass achieve the required pump capacity, thus enabling multiple ink supply pumps to be fitted to the print head carrier if desired.
As shown in
As shown by
The pump 30 includes a displacement volume housing 40 having a chamber 42 formed therein that is capped by the domed diaphragm 36, carried on a diaphragm plate 37, to provide the displacement volume 34. The chamber 42 includes an ink inlet 44 and an ink outlet 46 extending out through an outer end 48 of the displacement volume housing 40, where the outer end 48 receives a valve plate 50, which includes an inlet reed valve 52 in fluid communication with the ink inlet 44 of the chamber 42 and an outlet reed valve 54 in fluid communication with the ink outlet 46 of the chamber. An end cap 56 is attached to the valve plate 50 and includes a pump inlet 58 in fluid communication with the inlet reed valve 52 and a pump outlet 60 in fluid communication with the outlet reed valve 54.
The opposite end of the pump 30 includes a driver housing 62 containing the pump driver assembly 64, which drives the operation of the pump by activating the actuator/diaphragm 36 in reaction to lateral movement (illustrated by arrow 16) of the print carriage to which the pump 30 is attached. The driver housing 62 includes an elongated passage 66 extending perpendicular to the diaphragm 36 within which a piston or slider 38 reciprocates to continuously compress and release (i.e., activate) the diaphragm, which in turn causes ink to flow through the pump 30 as will be described in greater detail below. The pendulum 32 is pivotally coupled to the driver housing 62 below the slider 38 by a pivot pin 70, which extends through a bearing hole 71 in the pendulum 32, such that the pendulum 32 swings in the opposite direction that the print carriage 12 moves. In other words, the pendulum 32 swings on an axis extending substantially perpendicular to the direction 16 of carriage travel. The pendulum 32 includes an inertial mass arm 72 extending below the pivot pin 70 (and below the driver housing 62) and includes a follower arm 74 extending above the pivot pin and into a slot provided in the bottom of the slider 38, where it is pivotally coupled to the slider 38 by a cylindrical boss 76 on the inertial mass arm that is received within a bearing seat in the slider 38. The inertial mass arm 72 of the pendulum includes a relatively large cylindrical mass 78 provided thereon to provide most of the inertial mass for the inertial mass arm 72.
Specific dimensions and associated design data of this exemplary embodiment are provided (for illustration purposes only, and without intending to be limited thereto) as follows:
In alternate embodiments the Pendulum Mass has a mass of approximately 2 grams to approximately 200 grams; and the Pendulum/Slide Ratio is between approximately 0.5 and approximately 10 to one.
An equation that may be used to determine certain dimensions and values for the pump is provided as follows:
where,
Usually values of P, a, Mi, and SM are chosen first, and the equation is solved for the needed mechanical advantage k.
Additionally the following equations are utilized:
The diameter equation:
The mechanical advantage definition:
In the exemplary embodiment, when the pump 30 is coupled to an associated print head on the print carriage 12, an ink supply is coupled to the pump inlet 58 with a supply line tube and the pump outlet 60 is connected to an accumulator & vent tank by an output supply tube. The accumulator serves as a small reservoir of ink feeding a pressure regulator in the print head. The regulator serves to reduce the positive ink supply pressure to the negative (back pressure) pressure just above the print head's ejection nozzles.
Referring to
Thus, for a design pressure of 2.5 psi with a displacement of 0.032 cc's, the exemplary embodiment inertial mass pump 30 weighs only approximately 18 gms. In comparison to the inertial mass pumps of the prior art, which would have weighed approximately 40 to 50 gms for the same performance, the advantage of the present invention is clear. An additional advantage of the exemplary embodiment of the inertial mass pump 30 the pump 30 is relatively small such that multiple pumps can easily be incorporated into a printer's carriage as described and illustrated below. Additionally, the exemplary embodiment of the pump 30 requires virtually no control system. When the print carriage is in motion the pump is supplying ink, and when not in motion the pump is not supplying ink. The exemplary embodiment is also self pressure limiting in that the maximum pressure is limited to that of the acceleration of the carrier.
As shown in
Following from the above description and invention summaries, it should be apparent to those of ordinary skill in the art that, while the apparatuses and methods herein described constitute exemplary embodiments of the present invention, the inventions contained herein are not limited to these precise embodiments and that changes may be made to them without departing from the scope of the inventions as defined by the claims. For example, as will be appreciated by those of ordinary skill in the art, it is within the scope of the invention that the pump be a different type of displacement pump such as a bellows pump or a piston type pump. With such alternate pumps, the inertial mass would be coupled to the pump actuator by a mechanical linkage, such as a lever mechanism as described above, that provides a mechanical advantage. It is also within the scope of the invention that, as will be appreciated by those of ordinary skill in the art, alternate mechanical linkages providing a mechanical advantage may be utilized such as a gear system, a cam system or any other known mechanical advantage linkage. Further, with the multiple pump embodiments (such as shown and described in
It will also be appreciated by those of ordinary skill that while the exemplary embodiments described and illustrated herein have the inertial mass arm 72 extending below the pump and printer carriage, it is within the scope of the invention that the inertial mass arm extends or resides in other orientations or positions. The pendulum will operate in any orientation so long as the pivot axis is sufficiently perpendicular to the direction of carriage acceleration so as to experience the responsive movements to acceleration described herein. The exemplary embodiments have the inertial mass arm hanging below the pivot axis, but embodiments of the invention works sufficiently well with the inertial mass arm hung at angles, sideways, and even upside-down.
It will be further appreciated by those of ordinary skill that the slider 38 can also be coupled to the inertial mass arm 72 rather than to the follow arm (i.e., the slider 38 place on the same side of the pivot), by pivotally coupling the slider 38 to the inertial mass arm at a point closer to the pivot 70 than the inertial mass 78.
Additionally, it is to be understood that the invention is defined by the claims and it not intended that any limitations or elements describing the exemplary embodiments set forth herein are to be incorporated into the meanings of the claims unless such limitations or elements are explicitly listed in the claims. Likewise, it is to be understood that it is not necessary to meet any or all of the identified advantages or objects of the invention disclosed herein in order to fall within the scope of any claims, since the invention is defined by the claims and since inherent and/or unforeseen advantages of the present invention may exist even though they may not have been explicitly discussed herein.