EP0902743A1 - Ink jet print head modules with common ink supply - Google Patents

Abstract

A system for supplying ink to a composite printing head (12) has a first compartment (20A) in fluid flow communication with a first set of orifices (14, 12A), and a second compartment (20B) in fluid flow communication with a second set of orifices (14, 12B). The first and second compartments (20A, 20B) are configured to allow the egress of ink to maintain the level of ink therein at a desired fill height. A reservoir (24) is also provided for supplying ink to the first and second compartments (20A, 20B).

Description

INK JET PRINT HEAD MODULES

WITH COMMON INK SUPPLY

This invention relates generally to ink jet printers. More specifically, the invention relates to a system for providing liquid ink at proper static pressure to a series

of drop-on-demand ink jet print orifices.

As is known, ink jet printing systems utilize printing heads in which ink droplets are emitted through one or more orifices and onto a target surface. In impulse type drop-on-demand printing, the emission of ink through the orifice is controlled by

creating pressure pulses within an ink chamber in the printhead. Referring to prior art

FIG. 1, a typical printhead 2 is provided with an array of orifices 3, which are individually controlled to emit ink droplets 4 that form the desired image on the target surface as the surface moves relative to the printing head. The orifices are fed ink from

individual chambers 5 within each printhead, which communicate with corresponding input ports 6. Ink is supplied via capillary action to each input port 6 from a reservoir

7 through ink supply lines 9.

It is important that the proper static pressure, typically a small negative static pressure, is achieved at each ink jet orifice to avoid orifice drooL Static pressure within the printhead is largely a function of the static fluid pressure at the printhead input port, since capillary forces within a given printhead offset any appreciable variation in

pressure head among the orifices in that printhead. Thus, the static pressure at the input

port influences the pressure at the ink jet orifices which are in immediate proximity to the input port. The optimal static pressure is determined by the physical properties of the ink, such as viscosity and surface tension, wetability and the substrate material used to construct the orifices. Ordinarily, the optimal static pressure of the ink is negative

one to three inches of water. As can be seen in FIG. 1, and as is known from hydraulic theory, the static pressure at the input port is a function of the difference in height (H)

between the input port and the reservoir ink level. More particularly, the static pressure at each orifice is a function of the difference in height between each orifice and the reservoir ink level

In commercial ink jet printing applications, it is advantageous to provide a

printing apparatus having a large printing area to permit imaging of a large image on a target surface without multiple passes of the surface past the printing head. This may be accomplished by providing a number of printheads vertically stacked or "stitched" together. Vertically stacked printhead arrangements, however, present special problems associated with the control of static pressure, and their commercial advantages have heretofore been limited by increasing costs or complexity relating to ink storage and delivery. It is not feasible to supply all printheads in a stacked arrangement from a common reservoir because uniform static pressure cannot be achieved. As seen in FIG.

1, printheads disposed above the reservoir fluid level experience negative static pressure, while those disposed below the reservoir experience positive static pressure. Moreover,

while it is feasible to provide each printhead with a separate, level-controlled reservoir

as illustrated in FIG. 2, the cost of such an arrangement is prohibitive. Additionally, the space limitations and tight spacing between printheads make it physically impractical

to install reservoirs and level-control devices in this configuration.

Prior art distribution systems are not readily adaptable to stacked printhead arrangements because of the complexity and costs associated with manufacturing and maintenance. There is thus desired an ink jet fluid distribution system which may be easily and inexpensively constructed and which provides proper and dependable control

of the static pressure of ink delivered to each printhead in a stacked arrangement.

According to the invention there is provided a system for supplying liquid to a

composite printing head having a first set of orifices at a higher elevation than a second

set of orifices, comprising:

a first compartment in fluid flow communication with the first set of orifices,

said first compartment being configured to allow the egress of liquid to maintain the level of liquid therein at a desired fill height;

a second compartment in fluid flow communication with the second set of

orifices, said second compartment being configured to allow the egress of liquid to maintain the level of liquid in the second compartment at a desired fill height; and

a reservoir for supplying liquid to the first and second compartments.

In a preferred embodiment of the invention, several printheads each has a set of

orifices for printing or marking a substrate. Each printhead is supplied from one of the

compartments of a multi-compartment reservoir via a separate feed line. The

compartmentalized ink reservoirs utilize a weir system which maintains a predetermined optimum static pressure within each compartment. The feed pressure to each printhead

is controlled by the relative height of the fluid column at each compartment with respect

to the height of an inlet port which is immediately proximate to the set of orifices. The

height of the fluid may be controlled by the height of the weir associated with that

compartment or the fluid level in such weir.

The present invention provides significant advantages over other ink jet fluid distribution systems. Because the weir system automatically maintains a desired level

of ink in the individual compartments, there is no need for individual level detectors for each compartment, thereby reducing parts and costs.

The present invention will now be described by way of example with reference to the accompanying drawings in which:-

FIG. 1 is an illustration of prior art printheads and ink distribution system as described above;

FIG. 2 illustrates the problems associated with independent level controls for a stacked printhead arrangement;

FIG. 3 is an illustration of a preferred embodiment of the invention; and

FIG. 4 is an illustration of a vacuum chamber feature of the present invention. Referring to FIG. 3, the fluid system embodying the present invention comprises a composite printing head 12' including a plurality-of ink embodying jet printheads 12A-

12D. Composite printing head 12 can be stationary and arranged to print an image on a target surface (not shown) which moves relative thereto. Alternatively, the printing head 12 can be movable relative to the target surface, or both the printing head 12 and the target surface can be movable relative to each other.

Although schematically illustrated as four spaced apart printheads 12A-12D, the composite printing head 12 preferably has three or four distinct internal printheads or manifolds that are integrally attached to provide an even distribution of ink as it is

ejected out of the printheads. It will be appreciated that any number of printheads can

be used to create the desired width of the area to be printed.

Preferably, each printhead 12A-12D has a set of ejection nozzles or orifices 14

which are supplied fluid by a common chamber or manifold 16 within each printhead 12A-D. The set of orifices may number twelve as illustrated, or more or less in number, it being within the skill of one knowledgeable in the art to choose the number of orifices and the pattern of those orifices. The manifolds 16 are supplied fluid through associated

inlet ports 18 and feed lines 19 attached to the printheads 12A-D. Although it is

desirable to have a separate printhead for each set of orifices, a single printhead could

have two or more sets of orifices with associated inlet ports. Also, while the sets of orifices are depicted to comprise a single row, there may be multiple rows of orifices in

a set, or other configurations, as those skilled in the art would understand.

To supply ink to the printheads 12A-12D through the feed lines 19, each printhead 12A-12D is provided with associated compartments 20A-20D which maintain a constant fluid level of ink therein using weirs 22A-22D. Each weir 22 includes an

opening, drain or other egress for permitting the flow of ink from one compartment to the next lower compartment, or in the case of the lowermost compartment 20D, back to a reservoir 24. A pump 26 provides a low- volume flow of ink from reservoir 24 to the uppermost compartment 20A via return line 27. A level detection device 28 is also

provided to ensure an adequate ink reserve is fed to reservoir 24 from a main storage container (not shown). To ensure that an adequate amount of ink is supplied to the compartments, means are provided to control the flow of fluid in the return line 27. For example, a valve or other control device can be utilized, or the pump can be configured

to pump ink at a desired constant flow rate through the supply line.

As will be understood, the ink level in each compartment 20 may be maintained

constant and therefore the static pressure at the inlet of each printhead, which is determined by the height (H) of the feed line above the ink level in its associated

compartment, is the same for each printhead. The printhead 12, and preferably the entire set of orifices for each printhead 12, are disposed above the ink level in the associated compartment 20 to provide a negative pressure in feed lines 19, which combines with the capillary forces therein to yield the proper pressure at the inlet port

18 which is in immediate proximity to the orifices 14.

To lower gas vapor pressure and reduce dissolved air in the ink, a degassing

device is provided, such as a membrane over the reservoir or a partial vacuum above the

ink in each container. Alternatively, all of the containers 20A-20B can be placed in a

single vacuum chamber 30 as shown in FIG. 4. As illustrated, the containers 20 are

stacked within the chamber 30 and have a single port 32 for creating a low negative

pressure to reduce dissolved air in the ink. As shown, the containers 20 can also be

stacked so that the flow out of adjacent containers is in opposite directions, thereby allowing the containers to approach vertical alignment to conserve space. A control means 34 is provided to ensure that an adequate amount of liquid is supplied to the

containers 20A-20D from the reservoir 24.

Also, an adjustment mechanism can be provided to adjust the heights of the

printheads 12A-12D, and therefore the sets of orifices 14, relative to the level of the ink

in the compartments 20A-D. This type of adjustment mechanism is known in the art and

could be configured for adjustment of the printing head 12 as a unit. The adjustment mechanism could also be configured to independently adjust the height of the printheads

12A-12B, provided they are not integrally joined together.

Similarly, a moving mechanism can be provided to adjust the heights of the

compartments 20A-20D, and thus the height of the ink in each compartment, relative to

the heights of the printheads 12A-12D and their associated sets of orifices 14. If the

compartments 20 are joined together as a staggered unit, the moving mechanism can be

configured to adjust the height of the entire assembly. Alternatively, the moving

mechanism can be configured to independently adjust the height of the compartments 20. This individual adjustment can be provided by a moving mechanism such as the

device disclosed in U.S. patent application Ser. No. 08/728,866, filed October 10, 1996.

It will be appreciated that more than one return line can be used to individually

feed each container rather than supplying the top container 20A. Also, various other

devices can be utilized to control the drainage of ink from each container, such as

valves, siphons, or the like.

While the invention is depicted in schematic form, it is within the skill of those

in the art to enclose the wiers in individual cartridges or as part of a single elongated container, thereby obtaining a compact ink system for an ink jet printer. It is within the

scope of the present invention to monitor the flow of ink supplied by the pump and the

flow to each printhead so that each weir is maintained full to assure proper static

pressure at the multiplicity of printheads.

Thus, an ink jet fluid distribution system is provided which may be easily and

inexpensively constructed and which provides proper and dependable control of the

static pressure of ink delivered to each printhead in a stacked arrangement.

Claims

1. A system for supplying liquid to a composite printing head having a first set of

orifices (14) at a higher elevation than a second set of orifices (14), comprising:

a first compartment (20A) in fluid flow communication with the first set of

orifices (14), said first compartment (20A) being configured to allow the egress of liquid to maintain the level of liquid therein at a desired fill height;

a second compartment (20B) in fluid flow communication with the second set

of orifices (14), said second compartment (20B) being configured to allow the egress

of liquid to maintain the level of liquid in the second compartment (20B) at a desired fill height; and

a reservoir (24) for supplying liquid to the first and second compartments (20A,

20B).

2. A system as claimed in claim 1, wherein the desired fill height of the first

compartment (20 A) is at a lower elevation than an inlet port (18) to the first set of

orifices (14) to define an upper static height difference, and the desired fill height of the

second compartment (20B) is at a lower elevation than an inlet port (18) to the second

set of orifices (14) to define a lower static height difference, said upper and lower static

height differences creating a negative pressure acting on the liquid in the inlet port (18).

3. A system as claimed in claim 1 or 2, wherein the desired fill height of the first

compartment (20A) is lower than a lowermost orifice of the first set of orifices (14), and

the desired fill height in the second compartment (20B) is lower than a lowermost orifice of the second set of orifices (14), thereby maintaining a desired negative pressure to

each orifice in each set of orifices.

4. A system as claimed in claim 2, wherein the upper static height difference is

substantially the same as the lower static height difference so that the negative pressure

acting on the liquid in the inlet ports (18) to the first and second set of orifices (14) is

approximately the same.

5. A system as claimed in any one of the preceding claims further comprising a

single supply line (27) for supplying liquid from the reservoir (24) to the first compartment (20 A), and wherein liquid from the first compartment (20 A) is directed to flow into the second compartment (20B), and liquid from the second compartment is directed into the reservoir (24).

6. A system as claimed in claim 5, wherein the first compartment (20 A) is

configured with an outlet opening (22A) adapted to allow liquid to drain therefrom to maintain said desired fill height and to direct the liquid into the second compartment

(20B), and the second compartment (20B) is configured with an outlet opening (22B)

adapted to allow liquid to drain therefrom to maintain the desired fill height and to direct

the liquid into the reservoir (24).

7. A system as claimed in claim 6, wherein the flow of liquid out of the first

compartment (20A) is directed in an opposite direction to the flow of liquid out of the

second compartment (20B), thereby allowing a generally vertical staking arrangement of the first compartment (20A), second compartment (20B), and reservoir (24).

8. A system as claimed in any one of the preceding claims further comprising

control means configured to ensure that an adequate amount of liquid is supplied to the compartments (20A - 20D) from the reservoir (24).

9. A system as claimed in any one of the preceding claims further comprising a

pump (26) for delivering the liquid from the reservoir (24) to the first compartment (20A).

10. A system as claimed in any one of the preceding claims wherein the first and

second compartments (20A, 20B) are configured to hold substantially the same volume of liquid.

11. A system as claimed in any one of the preceding claims further comprising a

device for creating a partial vacuum above the liquid in each compartment to lower the gas vapour pressure in said first and second compartments.

12. A system as claimed in any one of the preceding claims further comprising an adjustment mechanism for adjusting the height of the first and second compartments (20A, 20B) to further control the elevation of liquid therein.

13. A system for supplying ink to a composite printing head (12) having an upper printhead (12A) at a higher elevation than a lower printhead (12B), the upper and lower printheads (12A, 12B) each having an inlet port (18) in fluid flow communication with

a set of orifices (14), comprising:

an upper compartment (20A) in fluid flow communication with the upper

printhead (12A) for supplying ink thereto, said upper compartment (20A) having an

outlet opening (22A) at a desired height that is lower than the height of the upper set of

orifices, thereby defining an upper static height difference between the upper printhead

inlet port and the level of ink maintained in the upper compartment (20A) to create a

back pressure acting on the ink in the inlet port;

a lower compartment (20B) in fluid flow communication with the lower

printhead (12B) for supplying ink thereto, said lower compartment (20B) being positioned at a lower elevation than the upper, compartment (20A) and adapted to

receive an overflow of ink draining from the outlet opening (22A) of the upper

compartment (20A), said lower compartment (20B) having an outlet opening (22B) at

a height lower than the lower printhead inlet port (18) to define a lower static height difference the same as the upper static height difference, whereby back pressure acting

on the ink in the upper printhead orifice is substantially the same as back pressure acting on the ink in the lower printhead orifice;

a reservoir (24) for supplying ink to the upper compartment;

a supply line (27) for supplying ink from the reservoir to the upper compartment; and

a pump (26) for delivering the ink from the reservoir to the upper compartment.

14. A system for supplying liquid to a composite printing head (12) having an upper

set of orifices (12A, 14) at a higher elevation than a lower set of orifices (12B, 14), the upper set of orifices having an upper inlet port (18, 12 A) associated therewith, and the

lower set of orifices having a lower inlet port (18, 12B) associated therewith,

comprising:

means (22A-22D) for draiiiing liquid from individual compartments (20A - 20D)

to maintain the hquid in said compartments at desired levels relative to the heights of

the corresponding upper and lower inlet ports, thereby creating a desired back pressure

on said inlet ports; and

means (24, 26) for supplying liquid to said compartments (20A - 20D).

15. A system for supplying ink to a composite ink jet printhead (12) formed of at least two vertically disposed component printheads (12A - 12D), comprising:

an ink compartment (20 A - 20D) for each of said component printheads (12A - 12D) for communicating ink thereto, each compartment disposed at a predetermined

height, relative to its corresponding printhead, to maintain a desired static pressure;

each of said ink compartments (20A - 20D) including a weir (22A - 22D) to

maintain a desired quantity of ink therein and to permit excess ink to spill from said compartment;

said compartments (20A - 20D) being positioned, relative to each other, to cause

the ink to spill from one compartment to be received in the next lower compartment;

a reservoir (24) for receiving ink spillage from a lowest one of said ink

compartments; and

a pump (26) for pumping ink from said reservoir (24) to an uppermost one (20A)

of said ink compartments.